TWM268560U - Foul odors separating device and refrigerator - Google Patents
Foul odors separating device and refrigerator Download PDFInfo
- Publication number
- TWM268560U TWM268560U TW093211047U TW93211047U TWM268560U TW M268560 U TWM268560 U TW M268560U TW 093211047 U TW093211047 U TW 093211047U TW 93211047 U TW93211047 U TW 93211047U TW M268560 U TWM268560 U TW M268560U
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- ozone
- deodorizing device
- cold air
- refrigerator
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Classifications
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25D—REFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
- F25D17/00—Arrangements for circulating cooling fluids; Arrangements for circulating gas, e.g. air, within refrigerated spaces
- F25D17/04—Arrangements for circulating cooling fluids; Arrangements for circulating gas, e.g. air, within refrigerated spaces for circulating air, e.g. by convection
- F25D17/042—Air treating means within refrigerated spaces
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25D—REFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
- F25D23/00—General constructional features
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25D—REFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
- F25D21/00—Defrosting; Preventing frosting; Removing condensed or defrost water
- F25D21/04—Preventing the formation of frost or condensate
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25D—REFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
- F25D2317/00—Details or arrangements for circulating cooling fluids; Details or arrangements for circulating gas, e.g. air, within refrigerated spaces, not provided for in other groups of this subclass
- F25D2317/04—Treating air flowing to refrigeration compartments
- F25D2317/041—Treating air flowing to refrigeration compartments by purification
- F25D2317/0415—Treating air flowing to refrigeration compartments by purification by deodorizing
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25D—REFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
- F25D2317/00—Details or arrangements for circulating cooling fluids; Details or arrangements for circulating gas, e.g. air, within refrigerated spaces, not provided for in other groups of this subclass
- F25D2317/04—Treating air flowing to refrigeration compartments
- F25D2317/041—Treating air flowing to refrigeration compartments by purification
- F25D2317/0416—Treating air flowing to refrigeration compartments by purification using an ozone generator
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25D—REFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
- F25D2317/00—Details or arrangements for circulating cooling fluids; Details or arrangements for circulating gas, e.g. air, within refrigerated spaces, not provided for in other groups of this subclass
- F25D2317/06—Details or arrangements for circulating cooling fluids; Details or arrangements for circulating gas, e.g. air, within refrigerated spaces, not provided for in other groups of this subclass with forced air circulation
- F25D2317/066—Details or arrangements for circulating cooling fluids; Details or arrangements for circulating gas, e.g. air, within refrigerated spaces, not provided for in other groups of this subclass with forced air circulation characterised by the air supply
- F25D2317/0665—Details or arrangements for circulating cooling fluids; Details or arrangements for circulating gas, e.g. air, within refrigerated spaces, not provided for in other groups of this subclass with forced air circulation characterised by the air supply from the top
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25D—REFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
- F25D2317/00—Details or arrangements for circulating cooling fluids; Details or arrangements for circulating gas, e.g. air, within refrigerated spaces, not provided for in other groups of this subclass
- F25D2317/06—Details or arrangements for circulating cooling fluids; Details or arrangements for circulating gas, e.g. air, within refrigerated spaces, not provided for in other groups of this subclass with forced air circulation
- F25D2317/067—Details or arrangements for circulating cooling fluids; Details or arrangements for circulating gas, e.g. air, within refrigerated spaces, not provided for in other groups of this subclass with forced air circulation characterised by air ducts
Landscapes
- Engineering & Computer Science (AREA)
- Chemical & Material Sciences (AREA)
- Combustion & Propulsion (AREA)
- Physics & Mathematics (AREA)
- Mechanical Engineering (AREA)
- Thermal Sciences (AREA)
- General Engineering & Computer Science (AREA)
- Cold Air Circulating Systems And Constructional Details In Refrigerators (AREA)
- Disinfection, Sterilisation Or Deodorisation Of Air (AREA)
- Oxygen, Ozone, And Oxides In General (AREA)
- Devices That Are Associated With Refrigeration Equipment (AREA)
Description
M268560 八、新型說明: 【新型所屬之技術領域】 本創作係有關一脫臭裝置,其係配置於冰箱内之冷氣循 環路徑内,藉由產生及分解臭氧,而進行冰箱内脫臭;本 創作又有關一種具備該脫臭裝置之冰箱。 【先前技術】 有關冰箱’已有-種配置有脫臭裝置’藉由將臭氧產生 後予以分解所生成之活性氧,將冰箱内之臭氣成分或細菌. 等氧化分解,而達成脫臭或殺菌作用者。為了產生臭氧, 有必要以增壓變壓器誘發4k〜5以左右之高電壓並予施加 於沿面放電形電極,而產生電晕放電令空氣中之惰性氣體 電離。 【新型内容】 [創作之解決課題] 然而’根據習用之構成,增髮變壓器與放㈣電極一起 配置於冰箱内,其係直接暴露於循環冰箱内之冷氣或冰箱 門開閉時流入冰箱内之外界氣體。因此,導因於冰箱内之 冷氣與外界氣體之溫度差’增壓變壓器有結露產生之情 形。 本創作係有鑑上述情事開發而 ^ 烕者’其目的係在提供一 種可防止增壓變壓器中產生姓命 脫臭裝置之冰箱。 H臭裝置,以及備有該 [課題之解決手段] 申請專利範圍第丨項之脫臭 衣置,其係配置於冰箱内之 M268560 冷氣的循環路徑内,利用臭氧 在於: 進行冰箱内之脫臭;其特徵 % 在以遮斷上述冷氣流 <乃忐構成的弟一室内配置有 壓變壓器; ~ i β & 在以使上述冷氣可流通之方式構成的第二室内,配置有 電連接於上述增壓„器的二次側之臭氧產生用電極,以 及將由該臭氧產生用電極產生 王97六虱分解之臭氧分解機 構0 若採如是之構成,增麼變壓器藉由配置於第一室内而自 循環冰箱内之冷氣被遮斷,只有臭氧產生用電極在第二室 内暴:於循環冷氣中。此外,在冰箱門開閉時,也不會直 接暴露於流人冰箱内之外界氣體中。是以,可盡量缓和增 壓變壓器周邊的溫度變化,而防止結露之發生。 θ 其並傷有以遮覆臭氧產生用電極周圍之方式構成的遮覆 構造者。若採用此—構成’就臭氧產生用電極也是,例 如’可防止冰箱門開閉時流入冰箱内之外界氣體等直接與 其接觸’可抑制溫度急劇之上昇。 此一場合中,如申請專利範圍第2項料,較佳的是, 自X遮覆構k ’ 3臭氧空氣流出之部位,設有供抑制其流 量之節流構造者。亦即,-般而t,放電用電極之放電開 始電壓,具有因經時變化而上昇之特性。因此,施加於臭 氧產生用電極之電壓,也宜預見放電開始電壓之上昇而預 先設定成較高。 如此1始使用之初期階段,臭氧之產生濃度據信會較 66405-930810 M268560 问疋以,藉由設置供抑制臭氧含有空氣之流出量的節流 構造防止含高濃度臭氧之空氣與臭氧分解機構直接接觸, 而抑制臭氧分解機構之劣化等等。 在以上之場合中,如申請專利範圍第3項所述,較佳的 是該臭氧產生用電極與臭氧分解機構之間,備有用以擴散 古大氧空氣之臭氧擴散機構者。若採用此一構成,與申請 專利範圍第6項相@,可防止含高濃度之臭氧的空氣與臭 氧分解機構直接接觸。又,在與申請專利範圍第2項之構 成併用的場合,可更為提高上述之效果。 申請專利範圍第4項脫臭裝置,其係配置於冰箱内之冷 氣的循環路徑内,利用臭氧進行冰箱内之脫臭;其特徵在 於: 此脫臭裝置備有: 變壓器室,配置有增壓變壓器; 屯極室’與該k壓态室相隔開地構成,配置有與上述增 壓變壓裔二次側電連接的臭氧產生用電極;及 冷氣流通室,具有與該電極室連通之連通口,以可使上 式構成,且配置有分解介以上述連通 述循環冷氣流通 口供給之臭氧的臭氧分解機構 具體5之,在蜒壓器室内所配置之增壓變壓器,與申請 專利範圍第1項相同’係與循環於冰箱内之冷氣遮斷: 又,冰箱内之循環冷氣係流通至冷氣流通室内,臭氧係自 電極室㈣連通口供給。是以,電極室内之臭氧產生^ 極也不會與冰箱内之循環冷氣或門開閉時流入冰箱内之= 66405-930810 M268560 界氣體直接接觸1而’臭氧產生用電極之溫度變化 抑制。 蚁 此一場合,如+請專利範圍第5項所述,較佳的是該臭 氧分解機構,係對應於連通口之部位配置者。具體今之, 在冷氣流通室於電極室中所產生的臭氧介以連通口供 給的附近’該臭氧係與含臭氧之空氣混合。因&,若對應 於連通口之部位酉己置臭氧分解機才冓,可有效率地進行臭^ 又,如申請專利範圍第6項所述,較佳的是該臭氧產生 用黾極其產生放電之放電面其内面之非放電面此二面, 均係位於電極室内者。藉由此—構成’當放電面與非放電 面位於不同環境狀態下時,兩者之溫度梯度會增大,以2 加諸臭氧產生用電極之熱應力增大。因此,藉由將二者均 位於第二室内,可減小兩者間之溫度梯度,而減輕加諸臭 氧產生用電極之熱應力。 另,如申請專利範圍第7項所述,較佳的是,該電極室 内所產生之臭氧,係藉其本身之重量落下至冷氣流通室側 者。若採用此一構成,利用臭氧較空氣為重之性質,臭氧 可谷易地供給至冷氣流通室内。 此一場合中,如申請專利範圍第8項所述,較佳的是該 臭氧產生用電極,係相對臭氧落下至冷氣流通室側之方 向,配置成與其平行朝向者。若採用此一構成,臭氧產生 用電極,可妨害產生之臭氧朝向冷氣流通室側之流動,可 將臭氧圓滑地供給。 M268560 又以上之場合中,如申請專利範圍第9項所述,較佳 白勺是'今女—片十 ^六乳產生用電極之放電面,係配置成縱向者。若採 用此一構成’可防止塵埃等積滯於臭氧產生用電極。 另外’如申請專利範圍第10項所述,較佳的是,該増 變壓哭夕 I . 的 < 一次側端子,係配置成朝向下方者。若採用此— 成例如可防止水分傳經供電線等侵入增壓電壓器之一 次側。 者如申睛專利範圍第11項所述,較佳的是,該循琴: 冷軋之流入口部份處,配置有異物侵入防止用格柵者。若 採用 itb — 士、 -τ 霉成’可防範食品等異物侵入流出而降低脫臭效 率於未然。 ' > 味Y專利範圍第12項之冰箱,其特徵在於具備申請專利 咏第1或4項之脫臭裝置。因此,可防止增壓變壓器 矣士露算笑太 、、σ 、寻,使得冰箱内之脫臭效果持續維持於安定狀態。 、人二’如申請專利範圍第13項所述,車交佳的*,在該循環 ~礼之回歸路徑側,配置脫臭裝置者。㈣考 夕曰 循衣冷氣至該時為止循環過冰箱内,因而含有 =之臭氣成分’是以’若採用此—構成,可使脫臭 率地進行。 、又’如巾請專利範圍第14項所述,較佳的是,由共通 冷卻器所產生 # /、 H ,係循環至冷藏室及蔬菜室;脫臭裝 側上述循環冷氣自上述冷藏室側流入上述蔬菜室 為死ηβ份者。11由㈣此—構成,可有效率地使用略 ’’、、空間之部份,可盡量抑制冰箱内食品貯存容積之減 66405-930810 M268560 少。 上此%合中,如申請專利範圍第15項所述,較佳的是, 該^臭裝置中之循環冷氣流入口位置處的近處之冷藏室底 板邛伤’設有水分侵入防止用凹部者。若採用此一構成, σ入口之水分,係可由其近處之凹部所捕捉,可防止 水分對於脫臭裝置之侵入。 ^ 如申巧專利範圍第16項所述,較佳的是該脫臭裝置M268560 8. Description of the new type: [Technical field to which the new type belongs] This creation relates to a deodorizing device, which is arranged in the cold air circulation path in the refrigerator to deodorize the refrigerator by generating and decomposing ozone; this creation It also relates to a refrigerator provided with the deodorizing device. [Prior art] Related refrigerators, "existing-equipped with a deodorizing device", decomposes the odorous components or bacteria in the refrigerator by oxidizing and decomposing the active oxygen generated by decomposing ozone and decomposing them to achieve deodorization or Sterilizers. In order to generate ozone, it is necessary to induce a high voltage of about 4k to 5 by a booster transformer and apply it to a creeping electrode, and a corona discharge is generated to ionize the inert gas in the air. [New content] [Solutions for creation] However, according to the conventional structure, the additional transformer is placed in the refrigerator together with the discharge electrode, which is directly exposed to the cold air in the circulating refrigerator or flows into the outer and outer boundaries of the refrigerator when the door is opened and closed. gas. Therefore, dew condensation may occur due to the difference in temperature between the cold air in the refrigerator and the outside air. This creation was developed in light of the above circumstances, and its purpose is to provide a refrigerator that can prevent the generation of a deodorizing device in the booster transformer. H-odor device and deodorizing clothes with item No. 丨 of the patent application scope, which are arranged in the circulation path of M268560 air-conditioning in the refrigerator, and use ozone to: deodorize the refrigerator ; Characteristics% A voltage transformer is arranged in the first room constructed to block the cold air flow <Naaru; ~ i β & In the second room constructed so that the cold air can flow, is electrically connected to The ozone generating electrode on the secondary side of the above-mentioned booster and the ozone decomposition mechanism for decomposing the sixty-nine lice from the ozone generating electrode. If it is constructed as described above, the transformer is arranged in the first room. The cold air in the self-circulating refrigerator is blocked, and only the ozone-generating electrode is exposed in the second room: in the circulating cold air. In addition, when the refrigerator door is opened and closed, it will not be directly exposed to the gas flowing inside and outside the refrigerator. Therefore, it is possible to reduce the temperature change around the booster transformer as much as possible to prevent the occurrence of dew condensation. Θ It also hurts the covering structure formed by covering the surroundings of the ozone generating electrode. If this is adopted, the electrode for ozone generation is also used, for example, 'the gas can be prevented from directly contacting the inside and outside of the refrigerator when the refrigerator door is opened and closed', and the rapid temperature rise can be suppressed. In this case, if the scope of patent application is the second The item is preferably provided with a throttling structure for suppressing the flow rate from the portion where the X covering structure k ′ 3 ozone air flows out. That is, generally, t, the discharge start voltage of the discharge electrode, It has the characteristic of rising due to the change with time. Therefore, the voltage applied to the ozone-generating electrode should also be set to a higher value in anticipation of the increase in the discharge start voltage. It is believed that the concentration of ozone generated during the initial stage of use Compared with 66405-930810 M268560, it is suggested that by setting a throttling structure for suppressing the outflow of ozone-containing air, the air containing high concentration of ozone is prevented from directly contacting the ozone decomposition mechanism, and the degradation of the ozone decomposition mechanism is suppressed. In the above cases, as described in item 3 of the scope of patent application, it is preferable that the ozone generating electrode and the ozone decomposing mechanism be used for diffusion. Those who use the ozone diffusion mechanism of ancient oxygen air. If this structure is adopted, it is in line with item 6 of the scope of patent application, which can prevent the air containing high concentration of ozone from directly contacting the ozone decomposition mechanism. When the two items are used together, the above effect can be further enhanced. The fourth item of the patent application scope is a deodorizing device, which is arranged in the circulation path of the cold air in the refrigerator and uses ozone to deodorize the refrigerator; its characteristics The deodorizing device is provided with: a transformer room configured with a boosting transformer; a pole electrode room is configured to be separated from the k-pressure state room, and is configured to generate ozone that is electrically connected to the secondary side of the boosting transformer; An electrode; and a cold air flow passage chamber having a communication port communicating with the electrode chamber so as to be constituted by the above formula, and configured with an ozone decomposition mechanism that decomposes ozone supplied through the above-mentioned circulating cold air flow passage. The booster transformer configured in the serpentine compressor is the same as the first item in the scope of the patent application, which is to block the cold air circulating in the refrigerator: In addition, the circulating cold air in the refrigerator is circulated to Gas flow chamber, (iv) an ozone-based communication port from the electrode chamber is supplied. Therefore, the ozone generating electrode in the electrode chamber will not directly contact the circulating cold air in the refrigerator or the door flowing into the refrigerator when it is opened or closed = 66405-930810 M268560 Boundary gas directly contacts 1 and the temperature change of the ‘ozone generating electrode’ is suppressed. In this case, as described in item 5 of the patent scope, it is preferable that the ozone decomposition mechanism is arranged at a position corresponding to the communication port. Specifically, in the vicinity of the supply of ozone generated by the cold air flow passage in the electrode chamber through the communication port ', the ozone is mixed with ozone-containing air. Because &, if the part corresponding to the communication port is equipped with an ozone decomposer, the odor can be efficiently performed. Also, as described in item 6 of the scope of the patent application, it is preferable that the ozone generating agent be extremely generated. Both the discharge side of the discharge and the non-discharge side of the inner side are located in the electrode chamber. By this means-when the discharge surface and the non-discharge surface are located in different environmental conditions, the temperature gradient of the two will increase, and the thermal stress of the electrode for ozone generation by 2 will increase. Therefore, by placing both of them in the second chamber, the temperature gradient between the two can be reduced, and the thermal stress of the electrode for ozone generation can be reduced. In addition, as described in item 7 of the scope of patent application, it is preferable that the ozone generated in the electrode chamber is dropped to the side of the cold air flow passage by its own weight. With this configuration, ozone can be easily supplied into the cold air flow passage chamber by utilizing the property that ozone is heavier than air. In this case, as described in item 8 of the scope of the patent application, it is preferred that the electrode for ozone generation be arranged in a direction parallel to the direction in which the ozone drops to the side of the cold air flow passage chamber. According to this configuration, the ozone generating electrode can prevent the generated ozone from flowing toward the cold air flow passage side, and can smoothly supply the ozone. M268560 In the above cases, as described in item 9 of the scope of the patent application, the preferred surface is the current discharge surface of the electrode for producing milk, which is arranged vertically. With this configuration, it is possible to prevent dust and the like from accumulating on the ozone generating electrode. In addition, as described in item 10 of the scope of patent application, it is preferable that the < primary terminal of the 増 transformer transformer I. Is arranged to face downward. If this is adopted, it is possible to prevent, for example, moisture from entering the primary side of the booster voltage through the power supply line or the like. As described in item 11 of the patent scope of Shenyan, it is preferable that the Xunqin: a cold rolled rolling flow inlet portion is provided with a foreign object intrusion prevention grille. If itb is used, it can prevent foreign matter such as food from flowing out and reduce the deodorization efficiency. '> The refrigerator of Wei Y patent scope is characterized in that it has a deodorizing device for patent application No. 1 or 4. Therefore, it is possible to prevent the booster transformer Shi Shilu from laughing too much, and make the deodorizing effect in the refrigerator continuously maintain a stable state. "People two" As described in the scope of the patent application No. 13, the car is very good *, and the deodorization device is installed on the return path side of the cycle ~ Li. Examination Xi Yu said that the air-conditioner circulates through the refrigerator until this time, so the odor component containing = is composed of 'if this is adopted, the deodorization rate can be performed. As described in item 14 of the patent scope, it is preferable that the common cooler # /, H is circulated to the refrigerating room and the vegetable room; the circulating cold air on the deodorizing side is from the refrigerating room Those who flowed into the vegetable room sideways were dead ηβ servings. 11 is composed of this-it can be used efficiently, and the space part can be used efficiently, and the reduction of the food storage volume in the refrigerator can be suppressed as much as possible 66405-930810 M268560. In the above %%, as described in item 15 of the scope of the patent application, it is preferable that the bottom of the refrigerating compartment near the entrance of the circulating cold air flow in the odor device is provided with a recess for preventing moisture intrusion. By. With this configuration, the moisture at the σ inlet can be captured by the recess in the vicinity, which can prevent the moisture from entering the deodorizing device. ^ As described in item 16 of Shenqiao's patent scope, the deodorizing device is preferred
系配置於冷藏室内之循環冷氣吸人部者。亦即,循環冷氣 二=部係位於循環冷氣之回歸路徑的末端,因此,到達該 邛伤之循環冷氣係含最大量之臭氧成分,&而,採用此一 構成’可使脫臭效率進一步提高。 申明專利範圍第17項之冰箱,其特徵在於:此冰箱具 有二配置於以遮斷冰箱内循環冷氣方式而設的變壓器室之 立曰[、交壓S、冑連接於該增壓變壓器的二次側且配置於上 述變壓室外部之臭氧產生用電極、以及分解由該臭氧產生It is a person who circulates cold air in the refrigerating room. That is, the circulating cold air two = the department is located at the end of the return path of the circulating cold air. Therefore, the circulating cold air that reaches the sting contains the maximum amount of ozone components, and the use of this structure can make the deodorization efficiency further. improve. The refrigerator claiming the scope of patent No. 17 is characterized in that the refrigerator has two transformers arranged in a transformer room which is arranged to block the circulation of cold air in the refrigerator. [, AC voltage S, 胄 connected to the booster transformer An ozone-generating electrode disposed on the secondary side and outside the transformer chamber, and decomposing the ozone-generating electrode
“極所產生的臭氧之臭氧分解機構;相對藉由令冷藏室 内之循環冷氣流通而進行脫臭之脫臭裝置,僅使循環冷氣 之一部份可流通者。 若採用此一構成,增壓變壓器係藉由配置於變壓器室 ::冰箱内循環之冷氣被遮斷’而只有臭氧產生用電極 ,壓器室之外部暴露於循環冷氣中。又,在冰箱之門開 守s壓麦壓為不會暴露於流入冰箱内之外界氣體。 此’可盡量缓和增壓變壓器周邊之溫度變化,防止結露 產生。 66405-930810 10 M268560 人 ▲入脫臭裝置之循環冷氣係與配置於變壓器室外部 之六1產生用電極所產纟的臭氧一起通過臭氧分解機構, 因此,右令循環冷氣全部流入脫臭裝置,因流過臭氧分解 $構,之阻力,冷氣之循環停滯,而有冷氣性能降低之 、疋以,藉由只使循環冷氣之一部份流通至脫臭梦 可在防止冷卻性能降低下進行脫臭。 “置, 另外’若在脫臭裝置中有過多之循環冷氣通時時,會有 °i^六氧刀解機構中之臭氧分解反應速度的界限之可能. ^ ’於此-場合下’不只臭氧分解無法終了,招致脫臭效 :::降低’ $時’臭氧有在冰箱内過量流出之虞。於此一 场合下’也可藉由只令循環冷氣的一部份流通至脫臭裝 置,進行調整而適切地維持脫臭效率。 此-場合中,如申請專利範圍第18項所述,較佳的是, :對脫臭裝置之循環冷氣的每(小時之流通量,係設定為 ▽藏室容積之4倍以上者。若採用此__構成,彳因應冰箱 之容積適切地設定對於脫臭裝置之循環冷氣的流通量,因 此,可良好地確保脫臭裝置中之脫臭效率。 又’如巾請㈣範圍第19項所述,較佳的是,該相對脫 4置之循環冷氣的流通量,係、形成為可變化者。若採用 ^構成’即使是冰箱内所貯存之食品㈣量變化之場 3 猎由因應此一變化辦姑非丄 >人扣占& 曰減對於脫臭裝置之循環冷氣的流 通量,可適切地維持脫臭裝置中脫臭效率。 、此-場合中,如中請專利範圍第2。項所述,車交佳的是該 脫以置中’備有供流通循環冷氣之專用風扇$。若採因 66405-930810 M268560 此一構成,與冷卻運轉之狀態獨立,可藉由專用之風扇對 於脫臭裝置流通以循環冷氣進行脫臭。 , 又,如申請專利範圍第21項所述,較佳的是,流通至脫 臭裝置之循環冷氣,與流通至除此之外的部份之循環冷 氣/、比率係可麦化者。亦即,即使冰箱内之循環冷氣的 流量為一定之場合,藉由變化流通至脫臭裝置的量與流通 至以外部份的量之比率,可相對地變化流通至脫臭裝置之 循環冷氣的量。"The ozone decomposition mechanism of ozone produced by the pole; compared with the deodorizing device that allows the circulating cold air flow in the refrigerating chamber to pass through, only a part of the circulating cold air can be circulated. If this structure is used, the pressure is increased The transformer is arranged in the transformer room: the cold air circulating in the refrigerator is blocked, and only the ozone generating electrode is exposed to the outside of the compressor room. It will not be exposed to gas flowing inside and outside the refrigerator. This can minimize the temperature change around the booster transformer to prevent condensation. 66405-930810 10 M268560 people ▲ The circulating cold air entering the deodorizing device is connected with the outside cooler of the transformer room. The ozone generated by the electrodes used in the June 1 pass through the ozone decomposition mechanism. Therefore, all the circulating cold air flows into the deodorizing device. Due to the resistance of the ozone decomposition structure, the circulation of the cold air stagnates, and the cooling performance is reduced. Therefore, by circulating only a part of the circulating cold air to the deodorizing dream, deodorization can be performed while preventing the cooling performance from being lowered. When there is too much circulating cold air in the device, there may be a limit of the ozone decomposition reaction speed in the ° i ^ hexaoxygen knife decomposition mechanism. ^ 'In this-occasions', not only the ozone decomposition cannot end, causing deodorization effect ::: Reduce '$ 时' ozone may cause excessive outflow in the refrigerator. In this case, it is also possible to appropriately maintain the deodorizing efficiency by circulating only a part of the circulating cold air to the deodorizing device and adjusting it. In this case, as described in item 18 of the scope of the patent application, it is preferable that: (the circulation volume per hour of the circulating cold air of the deodorizing device is set to be more than 4 times the volume of the storage room.) With this __ configuration, the circulation cold air flow rate of the deodorizing device is appropriately set according to the volume of the refrigerator, so the deodorizing efficiency in the deodorizing device can be well ensured. Also, if you want to use the towel, please refer to item 19 in the scope. As mentioned, it is preferable that the circulation flow of the relatively depleted circulating air-conditioner be changed and formed. If ^ is used to constitute a field where even the quantity of food stored in the refrigerator changes 3 This change can be used to reduce the circulation of cold air to the deodorizing device, which can appropriately maintain the deodorizing efficiency in the deodorizing device. In this case, the scope of the patent should As described in item 2. The best thing for the car is that it is equipped with a special fan for circulating air-conditioning. If it uses 66405-930810 M268560, this structure is independent of the cooling operation. Dedicated fan for circulating deodorizing equipment to circulate cold Deodorization. Also, as described in item 21 of the scope of the patent application, it is preferable that the circulating cold air flowing to the deodorizing device and the circulating cold air flowing to the other parts have a ratio of kemai. That is, even if the circulating cold air flow in the refrigerator is constant, the ratio of the amount of circulating cold air to the deodorizing device and the amount of circulating cold air can be changed relatively. The amount of circulating air-conditioning.
又,如申请專利範圍第22項所述,較佳的是,設有用以 增加循環冷氣風量之開關者。若採用此—構成,在使用二 進行強力脫臭之場合,I!由操作上述開關,可藉脫臭裝置 流通多量之循環冷氣提高脫臭率率。As described in item 22 of the scope of patent application, it is preferable to provide a switch for increasing the amount of circulating cold air. If this structure is adopted, in the case of using two to perform strong deodorization, I! By operating the above-mentioned switch, a large amount of circulating cold air can be passed through the deodorization device to increase the deodorization rate.
另外’如申請專利範圍第23項所述,藉由脫臭裝置之 續運轉,而可調整脫臭效率者。亦即,若使脫臭裝置中 臭氣的產生量為ϋ冷藏室之容積不同,則自、氧之 度會相對地變化。是以,在冷藏室之容積小的場合,夢 =脫臭裝置之運轉時間而降低運轉率(例如,丨分料 整使脫臭效率成為適切。相對^至之容積進行' 再者,”請專利範圍第24項所述,較佳的是,㈣ =之運轉㈣,係因應_該脫臭裝置之循環冷㈣ 者。例如’相對脫臭裝置之循環冷氣的流通 效率會適切地提高。反之,在循環冷氣話’脱 Κ⑽通量減少之 66405-930810 -12- M268560 合’藉由縮短脫臭裝置之運轉時間,可防止臭氧停滯於脫 臭裝置内。 【實施方式】 以下’茲將本創作第1實施例,佐以圖1及圖2說明之, 於表示冰箱之縱斷側視圖之圖2中,冰箱本體1係呈前面開 口之矩形箱狀,外箱2内係配設有内箱3,外箱2與内箱3之 間係充填有發泡胺基甲酸酯等之絕熱材料,基於此而形成- 該冰箱本體1。又,内箱3之内面上固定有水平之合成樹脂 製分隔板(冷藏室底板)5。此一分隔板5係在冰箱本體丨内之 上部形成冷藏室6,該冷藏室6之前端部轉動自如地安裝有 R門7 〇 分隔板5之上面形成有複數個突部(圖未示),複數之突 部上搭載有冷藏盒8。此低溫冷藏盒8係成上面及前面均開 口之容器,,低溫冷藏盒8之下面與上面間形成有冷氣通 路9又,付號1 〇係指開閉低溫冷藏盒8前面之蓋。 又,分隔板5之一部份係經開口,於該開口部處嵌合有 脫臭裝置u,。脫臭裝置"之下方側固定有支持板1〇〇, 供支持脫臭裝置Η。又,分隔板5與支持板1〇〇之間,形成 有冷氣通路1 〇 1。 内相3内,在分隔板5之下方,固定有絕熱分隔板12。此 -絕熱分隔板嶋合成樹脂製之盒内,收納發泡苯乙烯 而成,絕熱分隔板12與分隔板5之間形成有蔬菜室13。此 -蔬菜室U係介以配置於分隔板5之脫臭裝置⑽至冷藏 66405-930810 M268560 室6内(作為冷藏宕& 至6之一部份發揮機能)’蔬菜室13之前端 部安裝有可前後方向滑動vni4。 疏采室1 3内收纟内古I人 —扣, 、、有下盖1 5。此一下益1 5係成上面開口之 ^下風15上搭載有上盒16。此一上盒16係占據下盒 、 中不包括剷端部之部份,形成上面開口之容器 狀此上凰1 6之上面開閉自如地安裝有蓋丨7,蓋丨7與分 隔板5之間形成有冷氣通路丨8。 絕緣分隔板12之下方形成有冷凍室19。此一冷凍室19與· 上方之‘菜至1 3及冷藏室6係熱隔絕,又,冷凍室19之前 端邛,安I有可在前後方向滑動之上門2〇及下門2 1,冷凍 室19内收納有上下二段之冷凍盒22及23。 冰箱本體1之下端部形成有機械室24,機械室以内配設 有冷康循環之壓縮機25。此—壓縮機25係以壓㈣馬達% 為驅動源之在復式,壓縮機馬達2 $係介以驅動電路電連接 於主控裝置(均未圖示)。主控裝置係以微電腦為主體而構 成’其係配没於冰箱本體1内。 疏菜室13之後部形成有R冷氣生成室,R蒸發器33係收 納於R冷氣生成室36内。此一 R冷氣生成室36具有圓筒狀 之冷氣吐出口 37及格子狀之冷氣吸入口 38,冷氣吐出口 37 係插入上盒16内。 冷藏室6内固定有略L字形之導管罩39。此一導管罩39係 以合成樹脂為材料形成,其中形成有開口於冷藏室6内之 複數個冷氣吐出孔40。此一導管罩3 9係與内箱3之後板協 同構成L字通路狀之冷氣導管41,該冷氣導管4丨之上端部 66405-930810 -14- M268560 係開口於冷藏室6内,下端部係連通於冷氣生成室3 6内。 氣生成室36内’收納有R風扇馬達42,R風扇馬達42 係"以圖未示之驅動電路電連接於主控裝置。此一尺風扇 馬達42之轉軸上,連結有R風扇43,在R風扇43迴轉時, 、氣係以下述路控循環。又,符號44係由:R風扇馬達42及 尺風扇43所構成之尺風扇裝置。此一R風扇裝置44係相當於 冷藏室用送風機,與R蒸發器33協同,構成相當於冷藏室 用冷卻裝置之R冷卻裝置45。 - 1 有^關冷藏室6、蔬菜室13中之冷氣的循環路徑> 空氣之一部份係自R冷氣生成室36内通過冷氣吐出口 ”吐 出至盒16内,並通過蓋17前端部所形戊冷氣流通孔私放出 至,氣通路18内。而後,沿著下盒15之前面朝下方流動,再 沿著下盒15之下面朝後方流動,並通過冷氣吸入口 38回送到 R冷氣生成室36内。此時,R蒸發器33係基於將空氣冷卻而 冷風化,冷卻蔬菜室丨3内。 空氣之殘餘部份係自R冷氣生成室36内,通過冷氣導管41 之複數個冷氣吐出孔4〇及上端部吐出至冷藏室6内,而流入 低溫冷藏盒8下方之冷氣通路9内。而後,再通過嵌合於分隔 板5之脫臭裝置11及冷氣通路1〇1流入蔬菜室13内,並唑由冷 氣通路18内朝前方流動。此後,再沿下盒丨5之前面朝下方^ 動,再沿下盒15之下面朝後方流動,並通過冷氣吸入口 38 = 到冷氣生成室36内。此時,基於R蒸發器33之將空氣冷卻而 冷風化,將冷藏室6内及蔬菜室丨3内冷卻。亦即,脫臭裝置 11係配置於循環冷風之回歸路徑側。 冷凍室19之後部形成有F冷氣生成室47,F冷氣生成室π之 上端部及下端部處設有冷氣吐出口 48及冷氣吸入口的。此一 F冷氣生成室47内,收納有F蒸發器34及?風扇馬達5〇,F風 M268560 扇馬達50係介以圖未示之驅動電路電連接於主控裝置。 F風扇馬達5〇之韓紐卜 Λ. 1_ 時,冷氣係以下述路4/: 扇51 ’F風扇51迴轉 α ^ 攻峪仏循%。又,符號52係由尸風扇馬達50 冷滚室Ϊ1所η構/之㈣扇裝置。此一㈣扇裝置52係相當於 、人卻梦w达虫與F瘵發器34協同,構成相當於冷凍室用 冷部裝置之F冷卻裝置53。 $ <有關冷凍室19中之冷氣的循環路徑> 室19内系自生成至47内通過冷氣吐出口 48吐出至冷床 =二,冷氣吸入口 48回到#氣生成室-内。此 冷卻:、洛為34之將空氣冷卻而冷風化,將冷凍室19内 形的構成之斜視圖。脫臭裝置11具有成矩 :目各54户::用1盒54,此盒54之圖1中下方側係成開放狀。 方便;月Γ 樹脂可為透明或非透明,本實施例中,為 万便5兄明汁,係採透明者。 盒54之内部,藉由分 相當於右上—角之二=及56自圖1中近側的側面觀之 L 角之σ|Μ刀的分隔,形成有變壓器室(第一 58,:厂變壓器室57之内部,配置有小型之增壓變壓哭 5二變壓器58’係由圖未示之-次側端子4 一一人側端子58a、58b係貫穿分ρ辟ψ石"厂 /、 部。又,各U由加桃二牙刀隔壁56硌出至變壓器室57之外 (第二室)59。 °之艾摩為至57以外的空間,係形成電極室 二次側端子58a、58b上,電逵桩古VL而私+ 用電極60。臭氧產味用^連接“面放笔形之臭氧產生 及分別與二次==60係由矩形薄板狀之陶莞板咖 H ^ 4出於陶究板60a之表面^ 11 / 放電面)配置(放電電極 广i中左 之内部模製成形(感應電極)。又,放電電::,在陶働a 陶瓷被覆以抑制调#姑+ 放^電極之表面係經施以 抑制源於放電之經時劣化。此二金屬電極上若經 66405-930810 16 M268560 施加由增壓變壓器58所增壓之交流4·5 kv左右的高電壓,則 兩金屬電極會介以陶瓷板60a放電。 又’盒54之圖1中左側的面上,形成有矩形開口狀之流入 口 54a ’供取入含冰箱内臭氣之空氣,又,盒54下方側之開 放的部份之流出口 54b中,以塞住該流出5朴之方式配置有觸 媒(臭氣分解機構)61。 。觸媒61例如係在以氧化錳為基底之陶瓷製蜂巢體(成形 。口)或將金屬蜂巢體形成為矩形板狀而成之芯材上,固定 禅61盥自、,構成藉由將其形成為蜂巢體狀,可大幅確保觸_ 觸桩Γι =氧成臭虱成分之接面積,可提高分解效率。又,在 中4方脫臭之空氣係、朝圖1中下方側流出。又,圖面 中=便計,蜂巢體構造係表示成四角形。 為上方:5構:二脫臭裝置11 ’於圖2中’係以吸入口 54a 板5。 " ’、,以朝向冷藏室ό側之狀態配置於分隔 之《脫臭裝置作用。亦電化學上,係作為所謂 高電壓時,產生電暈放電 =產生用電極⑼上經施加 性氣體電離成為電漿狀態。于:氣中所含之ΑΓ(氬)等之惰In addition, as described in item 23 of the scope of patent application, the deodorization efficiency can be adjusted by the continuous operation of the deodorization device. That is, if the amount of odor generated in the deodorizing device is set to be different from the volume of the refrigerating compartment, the degree of self and oxygen will be relatively changed. Therefore, when the volume of the refrigerating compartment is small, dream = the operating time of the deodorizing device to reduce the operating rate (for example, 丨 split the material to make the deodorization efficiency appropriate. Relative to the volume of ^ to carry out 'moreover, "Please, As described in item 24 of the scope of the patent, it is preferable that 之 = the operation 系 is in accordance with the circulation cold of the deodorizing device. For example, 'the circulating cooling air circulation efficiency of the deodorizing device will be appropriately improved. Otherwise, In the circulation of cold air, 66405-930810 -12- M268560 of the reduction of the de-K⑽ flux is reduced. By shortening the operating time of the deodorizing device, it is possible to prevent the stagnation of ozone in the deodorizing device. The first embodiment is created and explained with reference to FIG. 1 and FIG. 2. In FIG. 2 showing a longitudinal side view of the refrigerator, the refrigerator body 1 has a rectangular box shape with an open front, and the outer box 2 is provided with an inner portion. Box 3, outer box 2 and inner box 3 are filled with thermal insulation materials such as foamed urethane, and are formed based on this-the refrigerator body 1. Also, the inner surface of inner box 3 is fixed with a horizontal composition Resin partition (refrigerator compartment floor) 5. This one partition 5 A refrigerator compartment 6 is formed on the upper and inner portions of the refrigerator body. The front end of the refrigerator compartment 6 is rotatably installed with an R door 70. A plurality of protrusions (not shown) are formed on the partition plate 5. The plurality of protrusions are not shown in the figure. The refrigerator box 8 is mounted on it. The low-temperature refrigerator box 8 is a container which is open on the front and the front. The front cover. Also, a part of the partition plate 5 is passed through an opening, and a deodorizing device u is fitted at the opening portion. A support plate 100 is fixed to the lower side of the deodorizing device for support. The deodorizing device Η. Also, a cold air passage 100 is formed between the partition plate 5 and the support plate 100. In the internal phase 3, a heat-insulating partition plate 12 is fixed below the partition plate 5. This -The heat insulation partition board 嶋 is made of synthetic resin and contains expanded styrene. A vegetable compartment 13 is formed between the heat insulation partition board 12 and the partition board 5. This vegetable compartment U is arranged in the center. The deodorizing device of the partition 5 is stored in the refrigerated 66405-930810 M268560 room 6 (played as part of refrigerated & to 6) Yes) The front end of the 'vegetable room 13' is equipped with a sliding vni4 which can be moved forward and backward. The picking room 1 3 is closed inside and there is an ancient person — a buckle,, and a lower cover 15. ^ The upper box 16 is mounted on the downwind 15. This upper box 16 occupies a part of the lower box, excluding the end of the shovel, and forms a container with an upper opening. The upper 16 can be opened and closed with a lid. 7. A cold air path is formed between the cover 丨 7 and the partition plate 5. A freezing compartment 19 is formed below the insulating partition plate 12. This freezer compartment 19 is connected to the top of the dish 13 and the refrigerating compartment 6 The system is thermally insulated, and the front of the freezer compartment 19 is slanted. The upper door 20 and the lower door 21 can be slid in the front-rear direction. The freezer compartment 19 contains two upper and lower freezer boxes 22 and 23. A mechanical chamber 24 is formed at the lower end portion of the refrigerator body 1, and a compressor 25 for a cold-kill cycle is arranged inside the mechanical chamber. This—Compressor 25 is a duplex type that uses a pressure motor% as the driving source. The compressor motor 2 $ is electrically connected to the main control device through a drive circuit (both are not shown). The main control device is composed of a microcomputer as its main body, and it is arranged in the refrigerator body 1. An R cold air generating chamber is formed at the rear of the vegetable growing room 13, and an R evaporator 33 is housed in the R cold air generating chamber 36. This R cold air generating chamber 36 has a cylindrical cold air outlet 37 and a grid-shaped cold air inlet 38. The cold air outlet 37 is inserted into the upper case 16. A slightly L-shaped duct cover 39 is fixed in the refrigerator compartment 6. This duct cover 39 is formed of a synthetic resin as a material, and a plurality of cold air discharge holes 40 are formed in the refrigerating compartment 6. This duct cover 3 9 cooperates with the rear plate of the inner box 3 to form an L-shaped air-conditioning duct 41. The upper end of the duct 4 丨 66405-930810 -14- M268560 is opened in the refrigerating compartment 6 and the lower end is It communicates with the cold air generation chamber 36. An R fan motor 42 is housed in the gas generating chamber 36. The R fan motor 42 is electrically connected to the main control device by a driving circuit (not shown). An R fan 43 is connected to the shaft of this one-foot fan motor 42. When the R fan 43 rotates, the air system is controlled by the following road control cycle. Reference numeral 44 denotes a ruler fan device including an R fan motor 42 and a ruler fan 43. This R fan device 44 is equivalent to a refrigerating room fan, and cooperates with the R evaporator 33 to constitute an R cooling device 45 equivalent to a refrigerating room cooling device. -1 The cooling air circulation path in the refrigerating compartment 6, the vegetable compartment 13 > Part of the air is discharged from the R cold air generation chamber 36 through the cold air outlet "into the box 16, and through the front end of the cover 17 The shaped cold air flow through hole is released to the inside of the air passage 18. Then, it flows downwards along the front of the lower box 15, and then flows backwards under the lower box 15, and returns to the R cold air through the cold air inlet 38. The inside of the generating chamber 36. At this time, the R evaporator 33 is based on cooling and weathering the air to cool the inside of the vegetable chamber 丨 3. The remaining part of the air is from the inside of the R cold-air generating chamber 36 and passes through the cold-air duct 41 The discharge hole 40 and the upper end are discharged into the refrigerating compartment 6 and flow into the cold air passage 9 below the low-temperature refrigerated box 8. Then, they flow in through the deodorizing device 11 fitted into the partition plate 5 and the cold air passage 101. In the vegetable compartment 13, the azole is moved forward from the inside of the cold air passage 18. After that, it moves downwards along the front of the lower box 5 and then flows backwards under the lower box 15, and passes through the cold air inlet 38 = to The cold air generation chamber 36. At this time, based on the R evaporator 33 The air is cooled and cold-weathered, and the inside of the refrigerating compartment 6 and the vegetable compartment 丨 3 are cooled. That is, the deodorizing device 11 is arranged on the return path side of the circulating cold air. An F cold air generation chamber 47, F is formed at the rear of the freezing compartment The upper and lower ends of the cold air generating chamber π are provided with a cold air outlet 48 and a cold air inlet. The F cold air generating chamber 47 contains an F evaporator 34 and a? Fan motor 50, and an F wind M268560 fan motor. The 50 series is electrically connected to the main control device through a driving circuit not shown in the figure. When the F fan motor 50 is Hanubu Λ. 1_, the air-conditioning system is as follows 4 /: fan 51 'F fan 51 turns α ^ attack The cycle number is%. In addition, the symbol 52 is a fan device constructed by the dead fan motor 50 and the cold rolling chamber Ϊ1. This fan device 52 is equivalent to a person who dreams of a worm and cooperates with the F hair generator 34. It constitutes the F cooling device 53 which is equivalent to the cold section device for the freezing compartment. $ ≪ The circulation path of the cold air in the freezing compartment 19 > The inside of the room 19 is generated from 47 to 47 through the cold air outlet 48 to the cooling bed = Second, the cold air inlet 48 returns to the # 气 生产 室-. This cooling :, Luo is 34 to cool and cool the air Perspective view of the internal shape of the freezer compartment 19. The deodorizing device 11 has a rectangular shape: each 54 households :: 1 box 54, the lower side of this box 54 is open in Figure 1. Convenient; month The Γ resin can be transparent or non-transparent. In this embodiment, it is Manji 5 broth, which is transparent. The inside of the box 54 is equivalent to the upper right-the two corners = and 56. The side view of the L angle σ | M knife divides to form a transformer room (the first 58: the inside of the factory transformer room 57 is equipped with a small step-up transformer transformer 58). Shown-Secondary side terminals 4-One-side terminals 58a, 58b are penetrating through the branch " factory. In addition, each U is pulled out of the transformer chamber 57 (second chamber) 59 from the next wall 56. The Aimo is a space other than 57, and the electrode chamber is formed on the secondary side terminals 58a and 58b. Ozone production uses ^ to connect "noodle-shaped pen-shaped ozone generation and secondary and secondary == 60 is made of rectangular thin plate-shaped Taowan plate coffee H ^ 4 is from the surface of ceramic plate 60a ^ 11 / discharge surface) configuration ( The inner part of the discharge electrode can be molded into the left (induction electrode). Also, the discharge power :: The ceramic surface is covered with a ceramic to suppress the tone. When the two metal electrodes are applied with a high voltage of about 4.5 kV by the booster transformer 58 via 66405-930810 16 M268560, the two metal electrodes will be discharged through the ceramic plate 60a. 54. On the left side of FIG. 1, a rectangular opening-shaped inlet 54a 'is formed to take in the air containing the odor in the refrigerator, and the outlet 54b of the open part on the lower side of the box 54 is plugged. A catalyst (odor decomposition mechanism) 61 is arranged in a manner to hold the outflow 5. The catalyst 61 is, for example, a ceramic honeycomb body (shaped. Mouth) made of manganese oxide as a base, or a metal honeycomb body is formed into a rectangular plate shape. On the formed core material, the Zen 61 was fixed, so that it was formed into a bee. The shape of the body can greatly ensure the contact area of the contact _ contact pile Γι = the composition of the oxygen to stink components, which can improve the decomposition efficiency. In addition, the deodorized air system in the middle 4 flows out to the lower side in Fig. 1. Also, the drawing Middle = convenience, the honeycomb structure is shown as a quadrangle. For the top: 5 structure: two deodorizing device 11 'in Figure 2' is a suction port 54a plate 5. " ', to the side of the refrigerator compartment The state is arranged in a separate deodorizing device. It is also electrochemically used as a so-called high voltage to generate a corona discharge = ionization of the applied electrode ⑼ into a plasma state. In: ΑΓ (argon) and other inertia
Ar — Ar+ + e 根據(i)式之電離所發生 ^ 〇) 徐拚 之电子,右與氧原子〇 衝揎,將會發生活性氧〇。 02 〇2 — 〇+〇 根據(2)式所產生之活性 '**(2) 氧〇,。 ”氧結合,而生成臭 〇2 + 0-> 〇, 66405-930810 M268560 使上述(1)〜(3)之過程所生成之臭氧〇3,係藉由冷氣在冰 箱内循環而與自流入口 54a流入之含臭氣空氣混合。若觸 媒61之表面吸附有臭氧〇3及臭氣成分時,〇3會分解而產 生活性氧。活性氧0具有極強之氧化力之故,會將臭氣成 分氧化分解。依此一方式脫臭之空氣,係自流出口 5仆流 出。 以上之脫臭作用,係在上述冷藏室6之冷氣的循環路徑 内進行。亦即,在吸入口 54a中,除了沿冷氣通路9循環之 冷氣外,還有含臭氣空氣流入,而自流出口 54b,經脫臭 之空氣係流出至蔬菜室13内之冷氣通路1〇1。 此一場合下,增壓變壓器54由於係配置於變壓器室57之 内,因此係自循環冰箱内之冷氣被遮斷,只有產生臭氧之 臭氧產生用電極60配置於電極室59内,而暴露循環冷氣 中。 如上所述,根據本實施例,由於係將增壓變壓器5 8配置 於變壓器室57,因此不會有增壓變壓器58直接暴露於在冷 氣内循環之冷氣,或是在冰箱之R門7開閉時,直接暴露於 /”L入冰相内之外界氣體之情事。是以,可盡量緩和增壓變 壓器58周邊之過度變化,防止結露之發生,而可使增壓變 壓器5 8之壽命增長,提高信賴性。 另外,由於臭氧產生用電極6〇之放電面與其内面之非放 電面之兩面,均係位於電極室59内,因此可使兩面間之溫 度梯度減小,而減輕加諸臭氧產生用電極6〇之熱應力。故 而,也可彡』長六、氧產生用電極60之寿命。再者,由於係將 66405-930810 -18- M268560 臭氧產士用電極60配置於循環冷氣之流入側,將觸媒㈣ 置於循環冷氣之流出側’因&,可將臭氧之產生及利用其 分解之脫臭作用’沿著循環冷氣之流動有效率地進行。 又’根據本實施例,由於由共通之冷卻裝置她所產生 之冷氣係循環至冷藏室6及蔬菜室13,且該循環冷氣自冷 藏室6側流入蔬菜室13側之境界部份配置有脫臭裝置u : 因此’可有效地使用稍為死角空間之部份,可盡量避免冰 箱内容積之減少。X,依此一方式,藉由將脫臭裝置⑴己 置於循環冷氣之回歸路徑側,冷氣可將至此為止循環於冰 箱内之含有更多量臭氧成分的空氣(回送空氣)更有效率地 脫臭。 圖3及圖4中所示的是本創作的第2實施例,就與幻實施 例相同之部份係標示以相同之符號,至於其說明則在此省 略,以下僅就不同之部份說明之。第2實施例中,只有脫 臭裝置11之配置與第i實施例不同。亦即,第i實施例之分 隔板5係以分隔板5A取代,該分隔板5八上,配置有脫臭裝 置11之位置,設有複數個冷氣通口(圖中只示一個)62。 脫六、裝置11A係配置於形成有蔬菜室13的冷氣吸入口 38 之壁面上。於表示其正面之圖4中,脫臭裝置uA係在冷氣 吐出口 3 7的下方且位於兩個冷氣吸入口 3 8之間,係以吸入 口 54a朝向蔬菜室13内之狀態配置。又,於圖3中,脫臭裝 置11A之盒體54A的形狀,係與脫臭裝置丨丨之盒體54有若 干之不同。亦即,第1實施例中之流出口 54b係經封閉,而 代替的是,在盒體54A之背面側形成與R冷氣生成室36連 66405-930810 19- M268560 通之流出口 54c。又,吸入口 54a上配置有過濾器。 · 根據以上構成之第2實施例,由於係將脫臭裝置11 a配置 》 於形成有蔬菜室1 3内之冷氣吸入口 3 8的部份,因此,在循 壞冷氣之回歸路徑的末端,可將含有與第丨實施例相較更 多之臭氣成分的空氣之脫臭,更有效率地進行。又,觸媒 6 1係配置於臭氧產生用電極60之下方側。亦即,由於臭氧 較空氣為重,會自然移動至下方側,因此,若採用此一構 成,在臭氧產生用電極60附近生成之臭氧係自然朝觸媒Μ 方向移動。因此,可將臭氧之分解及伴隨該分解之臭氣成 _ 分的氧化分解,更有效率地進行。χ,臭氧產生用電極 6〇,其放電面係配置成縱向(重直方向)之故,可防止塵埃 等積滯之臭氧產生用電極。 圖5係本創作之第3實施例,在此只就與第2實施例不同 之邛伤σ兒明。第3實施例,如第2實施例般之配置脫臭裝置 11Α之場合,係以遮覆構造63將配置於電極室59内之臭氧 產生用電極60的周圍遮覆。亦即,遮覆構造〇例如係以樹 月曰寺形成為底面側開口之矩形箱狀,配置成自上方將臭氧修 產生用電極60遮覆。又,增壓變壓器58之二次側端子 5 8b係貝穿被覆構造63之上面。又,其他之構造在 此省略其圖示。 根據上述方式構成之第3實施例,藉由將臭氧產生用電 和之周圍以遮覆構造6 3遮覆,可防止在冰箱之v門14開 閉之%合,流入冰箱内之外界氣體直接與臭氧產生用電極 6〇接觸。是以’就臭氧產生用電極60,也可防止其與外界 66405-930810 -20- M268560 氣體接觸所導致之急劇的溫度上昇,故而,可進一步降低 熱應力,更增長臭氧產生用電極6〇之壽命。 圖6中所示的是本創作之第4實施例,只就其與第3實施 例之不同點說明t。第4實施例中,,在第3實施例之遮覆構 造63中開放的底面側,配置有矩形板狀之節流構造以。節 流構造64上設有例如三個圓形開口部64a,含有在臭氧產 生用電極60附近產生之臭氧的空氣,係、自節流構祕之開 口部64a流出,並朝向下方之觸媒61前進。 · 具體言之’一般而言,臭氧產生用電極60之放電開始電 昼,係因經時變化而有上昇之特性。因此,對於施加於臭 氧產生用電極60之電壓,也被期望能預見放電開始電壓之 上昇而預先設定地較高。如此,在開始使用之初期階段, 可預見的是臭氧之產生濃度會變得較高。 是以’根據如上構成之第4實施例,纟臭氧之空氣係自 開口部w相對外部徐徐地流出,因此可防止含高濃度臭 氧之卫氣直接與觸媒接觸,可抑制觸媒61之劣化等等。 圖7中所示的是本創作第5實施例,只就其與第*實施例 不同之部份說明之。第5實施例令,底面側配置有節流構 遮覆構造63與觸媒61之間,大致平行地配置有擴散 板(臭氧擴散機構)65。 “艮據如上構成之第5實施例,自節流構造以之開口部_ ^反Γ臭氧空氣,係暫時由遮覆板65遮斷,在以朝向擴 =周邊方向移動的方式擴散後’係朝觸媒Μ降下。 ^ ’藉由擴散板65也可防止含高濃度臭氧之空氣直接與 66405-930810 M268560 觸觸’故而可進-步提高觸媒61之劣化抑制效果。 例二:1中/T是在本創作第6實施例,其與請施 0 刀僅私圮以相同之符號而省略其說明,以下口 2同之部份說明之。第7實施例中之脫臭裝置66,其盒 之構造係與脫臭裝置u之盒體“有所不同,只是與第 1實施例大致相㈣配置於冷藏室6與蔬菜室13 =界部 份0 ° 首先4就脫臭裝置66之構成佐以圖9〜圖u說明之。大 矩形之箱狀盒體67,係由形成於水平方向之分隔壁砧 :Dj為‘上下—層。其下層部(冷氣流通室)仍備有朝冷藏 至6之鈾面開口的吸入口 67Da。 上層部67U中,藉由垂直方向之分隔壁仍、7〇,在圖 中右上之—角部份形成有變壓器室71,又,變壓器室71以 外之部份係電極室72。變壓器室71中配置有增壓變壓器 58〜壓4壓器58之二次側端子58a '娜,係'貫穿分隔壁 69露出於電極室72,其二次側端子5心、5肋上,電連接有 臭氧產生用電極60A。臭氧產生用電極6〇A係配置成以放 電面成垂直方向(縱向)。 分隔壁70係以使臭氧產生用電極60A附近所生成之臭氧 朝向下層部67D之路徑狹窄化的方式,在圖1〇中向左方延 伸又刀隔壁68之圖丨〇右下一角處,形成有連通於下層 部67D之連通口 68a。又,上層部67U之圖10中的右上角 處,形成有小的吸氣孔67Ua以使上層部67U内部之空氣流 動0 66405-930810 -22- M268560 圖1丨中,係將脫臭裝置66及冷藏室6與蔬菜室13之境界 J伤的斷面擴大表示。下層部67d之圖"中的右下部份, 係朝下方作右干之突出,其底面部份係形成開放。又,以 封塞其開放部份之方式,配置有與第^實施例觸媒&大致 相同構成之觸媒73。亦即,觸媒73係對應於連通口 68a之 部位配置於其正下方。 又H變愿器58之_次側端子58c (圖U中只表示一 個)’係配置於自增塵變壓器58之盒體的圖i i中右端部份 朝向下方纟-次側端子58c上,連接有自脫臭裝置66之 外部拉繞之供電線74。 以上之方式所構成之脫臭裝置66,如圖8及圖n所示, =裝入形成冷藏室6與蔬菜室13之境界部份的分隔板(冷 藏至底板)75。取代第}實施例之分隔板$的分隔板乃,係 自冷藏室6之近側(圖8中左側)延伸至深側之途中部位,具 有在俯角方向形成傾斜之傾斜部75a。自該傾斜部達於 脫六哀置66之π及入口 67Da的正前之部位,形成有凹部 75b。 自凹部75b更向冰箱之深側方向,形成有脫臭裝置66安 哀用之瓜0孔,此一嵌合孔中嵌合有脫臭裝置66中之下層 部6.7 8D的流出口 67Db。 其-人,级就第6實施例之作用說明之。冷藏室6及蔬菜室 13中之冷氣的循環路徑係與第1實施例相同,脫臭裝置66 ^電化學㈣也相同。亦即,沿冷藏室6内之冷氣通路9循 環之冷氣’若導入至脫臭裝置66之吸入口 67Da,會流通過 66405-930810 -23- M268560 觸媒73及流出口 67Db流出至蔬菜室1 3。 脫臭裝置66之上層部67U處,電極室72之臭氧產生用電 極60A附近,臭氧產生。如上所述,冷氣若流通至下層部 67D,介以吸氣孔69冰箱内空氣只有少量流入電極室72。 如此,產生之臭氧會繞入分隔壁流至深側’並介以連通 口 6 8 a落下至下層部6 7 D。如此,臭氧與含臭氧之冰箱内空 氣係在連通口 68a之附近混合,藉由觸媒73而進行臭氧之 分解及臭氧成分之氧化分解。經脫臭之空氣係自流出67D 流至蔬菜室13。 如上所述,根據第6實施例,增壓變壓器58係配置於盒 體67之上層部67U中所形成的變壓器室71内,臭氧產生用 電極60A係配置於電極室72A内,在電極室72所產生之臭 氧係介以連通口 68a供給至下層部67D,與流通於該下層部 67D之含臭氣空氣混合,並藉由觸媒73分解成臭氧及臭氣 成分。Ar — Ar + + e The ionization according to the formula (i) ^ 〇) Xu Pinzhi's electron, the right and oxygen atom 揎 rush, active oxygen 〇 will occur. 02 〇2 — 〇 + 〇 Activity '** (2) oxygen 〇, according to formula (2). "O2 is combined with oxygen to generate odors. 〇2 + 0- > 〇, 66405-930810 M268560 The ozone generated in the above processes (1) to (3) is 〇3, which is circulated in the refrigerator through the cold air and flows into the free inlet. The odorous air flowing in 54a is mixed. If ozone and odor components are adsorbed on the surface of the catalyst 61, 〇3 will decompose to generate active oxygen. Therefore, the active oxygen 0 has a strong oxidizing power, which will cause odor The gas component is oxidatively decomposed. The deodorized air in this way is discharged from the outflow port 5. The above deodorizing effect is performed in the circulation path of the cold air in the refrigerating compartment 6 above. That is, in the suction port 54a, In addition to the cold air circulating along the cold air passage 9, there is also odor-containing air flowing in, and from the outflow port 54b, the deodorized air flows out to the cold air passage 101 in the vegetable room 13. In this case, the booster transformer Because 54 is arranged in the transformer room 57, the cold air in the self-circulating refrigerator is blocked, and only the ozone-generating electrode 60 that generates ozone is placed in the electrode room 59, and the circulating cold air is exposed. As described above, according to In this embodiment, since The step-up transformer 58 is arranged in the transformer room 57, so there is no step-up transformer 58 directly exposed to the cold air circulating in the cold air, or when the R door 7 of the refrigerator is opened and closed, it is directly exposed to / ”L into the ice phase. Things of the Outer Gas. Therefore, excessive changes in the periphery of the booster transformer 58 can be mitigated as much as possible to prevent the occurrence of dew condensation, so that the life of the booster transformer 58 can be increased and reliability can be improved. In addition, since both the discharge surface of the ozone-generating electrode 60 and the inner non-discharge surface are located in the electrode chamber 59, the temperature gradient between the two surfaces can be reduced, and the ozone-generating electrode 6 can be reduced. Thermal stress. Therefore, the lifetime of the oxygen-generating electrode 60 can be increased. Furthermore, because the 66405-930810 -18- M268560 ozone obstetrician electrode 60 is arranged on the inflow side of the circulating cold air, and the catalyst ㈣ is placed on the outflow side of the circulating cold air, it is possible to generate and use ozone. The decomposition and deodorization effect 'is performed efficiently along the flow of circulating cold air. Also according to this embodiment, since the cold air generated by the common cooling device is circulated to the refrigerating compartment 6 and the vegetable compartment 13, and the circulating cold air flows from the refrigerating compartment 6 side to the vegetable compartment 13 side, a decoupling portion is disposed. Odor device u: Therefore, 'the slightly dead space part can be effectively used, and the reduction of the refrigerator internal volume can be avoided as much as possible. X, in this way, by placing the deodorizing device on the return path side of the circulating cold air, the cold air can circulate the air (return air) containing more ozone components in the refrigerator so far more efficiently Deodorization. Figures 3 and 4 show the second embodiment of this creation. The same parts as the magical embodiment are marked with the same symbols, and the description is omitted here. Only the different parts will be described below. Of it. In the second embodiment, only the arrangement of the deodorizing device 11 is different from that in the i-th embodiment. That is, the partition plate 5 of the i-th embodiment is replaced by a partition plate 5A. The partition plate 5 is provided with a position for a deodorizing device 11 and is provided with a plurality of cold air vents (only one is shown in the figure). ) 62. The device 11A is disposed on the wall surface of the cold air inlet 38 in which the vegetable compartment 13 is formed. In FIG. 4 showing the front side thereof, the deodorizing device uA is arranged below the cold air outlet 37 and between the two cold air inlets 38, and is arranged with the inlet 54a facing the vegetable compartment 13. In addition, in Fig. 3, the shape of the box body 54A of the deodorizing device 11A is different from that of the box body 54 of the deodorizing device. That is, the outflow port 54b in the first embodiment is closed. Instead, an outflow port 54c communicating with the R cold air generation chamber 36 is formed on the back side of the box body 54A 66405-930810 19-M268560. A filter is arranged in the suction port 54a. · According to the second embodiment of the above configuration, the deodorizing device 11 a is disposed at the portion where the cold air intake opening 38 in the vegetable compartment 13 is formed. Therefore, at the end of the return path following bad cold air, Deodorization of air containing more odorous components than in the first embodiment can be performed more efficiently. The catalyst 61 is arranged below the ozone-generating electrode 60. That is, since ozone is heavier than air and naturally moves to the lower side, if this configuration is adopted, the ozone generated near the ozone generating electrode 60 naturally moves in the direction of the catalyst M. Therefore, the decomposition of ozone and the oxidative decomposition of odor components accompanying the decomposition can be performed more efficiently. χ, the ozone-generating electrode 60. The discharge surface is arranged in the vertical direction (orthogonal direction), which can prevent the ozone-generating electrode from accumulating dust and the like. Fig. 5 shows the third embodiment of the present invention, and only the difference σ is different from the second embodiment. In the third embodiment, when the deodorizing device 11A is disposed like the second embodiment, the surroundings of the ozone-generating electrode 60 disposed in the electrode chamber 59 are covered with a covering structure 63. That is, the covering structure 0 is, for example, a rectangular box-like shape with a bottom surface side opening formed by a tree and a temple, and is arranged to cover the ozone repairing electrode 60 from above. The secondary-side terminal 58b of the step-up transformer 58 is the upper surface of the shell structure 63. The other structures are not shown here. According to the third embodiment configured as described above, by covering the ozone generating electricity and the surrounding with a covering structure 6 3, it is possible to prevent the% opening and closing of the v door 14 of the refrigerator to be combined, and the gas flowing into the inside and outside of the refrigerator directly contacts The ozone-generating electrode 60 is in contact. Therefore, the electrode 60 for ozone generation can also prevent the rapid temperature rise caused by the gas contact with the outside 66405-930810 -20-M268560. Therefore, the thermal stress can be further reduced, and the electrode for ozone generation can be further increased. life. Fig. 6 shows a fourth embodiment of the present invention, and t will be described only with respect to differences from the third embodiment. In the fourth embodiment, a rectangular plate-shaped throttling structure is arranged on the open bottom surface side of the covering structure 63 of the third embodiment. The throttle structure 64 is provided with, for example, three circular openings 64 a, and air containing ozone generated near the ozone-generating electrode 60 flows out from the opening 64 a of the throttle structure and faces the catalyst 61 below. go ahead. · To be specific, in general, the discharge start time of the ozone-generating electrode 60 has a characteristic that it increases with time. Therefore, it is expected that the voltage applied to the ozone-generating electrode 60 is set to be high in anticipation of an increase in the discharge start voltage. In this way, in the initial stage of use, it is foreseeable that the ozone production concentration will become higher. According to the fourth embodiment configured as above, the air of ozone is slowly flowing out from the opening w relative to the outside, so that the protective gas containing a high concentration of ozone can be prevented from directly contacting the catalyst, and the deterioration of the catalyst 61 can be suppressed. and many more. Fig. 7 shows a fifth embodiment of the present invention, and only a portion different from the * embodiment is described. In the fifth embodiment, a diffuser plate (ozone diffusion mechanism) 65 is arranged approximately in parallel between the throttle cover structure 63 and the catalyst 61 on the bottom surface side. "According to the fifth embodiment configured as described above, the opening portion of the self-throttling structure _ ^ Γ ozone air is temporarily blocked by the cover plate 65, and diffuses in a manner that moves in the direction of expansion = periphery. It is lowered toward the catalyst M. ^ 'The diffusion plate 65 can also be used to prevent air with a high concentration of ozone from directly contacting 66405-930810 M268560'. Therefore, the degradation suppression effect of the catalyst 61 can be further improved. Example 2: 1 / T is the sixth embodiment of this creation, which is the same as the application of the knife, and the description is omitted. The same part as the following is described. The deodorizing device 66 in the seventh embodiment, The structure of the box is different from that of the box of the deodorizing device u, except that it is roughly arranged in the refrigerating compartment 6 and the vegetable compartment 13 as in the first embodiment. The configuration will be described with reference to FIGS. 9 to u. The large rectangular box-shaped box body 67 is formed by a partition wall anvil formed in the horizontal direction: Dj is ‘upper-lower-layer. The lower part (cold air flow chamber) is still equipped with a suction port 67Da which opens to the uranium surface refrigerated to 6. In the upper part 67U, the transformer chamber 71 is formed in the upper right corner of the figure by a vertical partition wall 70, and the electrode chamber 72 is formed in a part other than the transformer chamber 71. The transformer room 71 is provided with a secondary side terminal 58a of the booster transformer 58 to the voltage transformer 58 through the partition wall 69 and exposed to the electrode chamber 72. The secondary side terminals 5 cores and 5 ribs are electrically connected. An ozone-generating electrode 60A is connected. The ozone generating electrode 60A is arranged so that the discharge surface is vertical (vertical). The partition wall 70 is formed so as to narrow the path of the ozone generated near the ozone generating electrode 60A toward the lower layer portion 67D. The partition wall 70 extends to the left in FIG. There is a communication port 68a that communicates with the lower portion 67D. In the upper right part of the upper part 67U, a small suction hole 67Ua is formed at the upper right corner in FIG. 10 to allow the air in the upper part 67U to flow. 0 66405-930810 -22- M268560 In Figure 1, the deodorizing device 66 is used. And the cross section of the boundary between injury in the refrigerator compartment 6 and the vegetable compartment 13 is enlarged. The lower right part in the picture of the lower layer part 67d is a right stem protruding downward, and the bottom part is formed to be open. A catalyst 73 having substantially the same structure as the catalyst & That is, the catalyst 73 is disposed at a position corresponding to the communication port 68a directly below it. The H secondary transformer 58 _ secondary terminal 58c (only one is shown in Figure U) 'is arranged on the box of the self-aerosolizing transformer 58 with the right end part facing downwards. The secondary terminal 58c is connected. There is a power supply wire 74 drawn from the outside of the self-deodorizing device 66. As shown in FIG. 8 and FIG. N, the deodorizing device 66 constituted as described above is installed in a partition plate (cold to bottom plate) 75 forming a boundary portion between the refrigerator compartment 6 and the vegetable compartment 13. The partition plate, which replaces the partition plate $ of the second embodiment, is an intermediate portion extending from the near side (left side in FIG. 8) to the deep side of the refrigerating compartment 6, and has an inclined portion 75a which is inclined in the depression direction. A recessed portion 75b is formed from the inclined portion at a position immediately before the π of the detachment 66 and the entrance 67Da. From the recessed portion 75b further toward the deep side of the refrigerator, a 0-hole melon for the deodorizing device 66 is formed. This fitting hole is fitted with an outlet 67Db of the lower-layer portion 6.78D of the deodorizing device 66. Its -person, level explains the function of the sixth embodiment. The circulation path of the cold air in the refrigerating compartment 6 and the vegetable compartment 13 is the same as that in the first embodiment, and the deodorizing device 66 is also the same. That is, if the cold air circulated along the cold air passage 9 in the refrigerating compartment 6 is introduced into the suction port 67Da of the deodorizing device 66, it will flow through the 66405-930810 -23-M268560 catalyst 73 and the outlet 67Db to the vegetable compartment 1 3. In the upper layer portion 67U of the deodorizing device 66, ozone is generated near the ozone generating electrode 60A of the electrode chamber 72. As described above, if the cold air flows to the lower portion 67D, only a small amount of the air in the refrigerator flows into the electrode chamber 72 through the suction holes 69. In this way, the generated ozone flows around the partition wall to the deep side 'and falls to the lower layer portion 6 7 D through the communication port 6 8 a. In this way, ozone is mixed with the air in the refrigerator containing ozone in the vicinity of the communication port 68a, and the decomposition of ozone and the oxidative decomposition of ozone components are performed by the catalyst 73. The deodorized air flows from the outflow 67D to the vegetable compartment 13. As described above, according to the sixth embodiment, the booster transformer 58 is disposed in the transformer chamber 71 formed in the upper portion 67U of the box body 67, and the ozone generating electrode 60A is disposed in the electrode chamber 72A. The generated ozone is supplied to the lower portion 67D through the communication port 68a, and is mixed with the odorous air flowing through the lower portion 67D, and is decomposed into ozone and odor components by the catalyst 73.
因此,與第1實施例等相同,可抑制增壓變壓器5 8之溫 接觸,而抑制溫度變化。又 通口 68a之部位配置,因此 解0 度變化,而且,也可防止冰箱内之循環冷氣或厌門7開閉 時,流入冰箱内之外界氣體也直接與臭氧產生用電極6〇a 觸媒73係對應於臭氧供給連 可有效地作臭氧及臭氣之分 係 增Therefore, similar to the first embodiment and the like, it is possible to suppress the temperature contact of the booster transformer 58 and suppress the temperature change. The position of the port 68a is arranged so that it can be changed by 0 degrees, and it can also prevent the circulating cold air in the refrigerator or the exhaust door 7 from opening and closing, and the external gas flowing into the refrigerator also directly contacts the ozone generating electrode 60a catalyst 73 Corresponding to the ozone supply chain, it can effectively increase the ozone and odor.
者,根據第6實施例’增壓變壓器58之_次側端子58C =配置’因此,可防止水分傳經供電線74等而侵入 “壓㈣之-次側。此外,脫Μ㈣ 66405-930810 -24- M268560 的流入口 67Da所位置處附近,分隔板乃之前半部75a形成 有凹部75b,因此,自分隔板75朝向流入口 67D之水分,會 υυ 由凹部75b所捕捉,而防止水分侵入脫臭裝置 圖12係本創作之第7實施例,只就與第6實施例不同之部 分說明。在第7實施例令’在脫臭裝置66之流入口 67Da, 設有用以防止異物侵入之格柵76。藉由此一構成,可防止 食品等進入流入口 67Da,可防範脫臭效率降低於未然。According to the sixth embodiment, 'the secondary terminal 58C of the booster transformer 58 = configuration' Therefore, it is possible to prevent moisture from passing through the power supply line 74 and the like to enter the "secondary-secondary side. In addition, the de-matter 66405-930810 -24 -Near the position where the inflow port 67Da of M268560 is located, the partition plate is formed with a recessed portion 75b in the front half 75a. Therefore, the moisture from the partition plate 75 toward the inflow port 67D will be captured by the recessed portion 75b to prevent moisture from entering and removing. Fig. 12 is a seventh embodiment of the present invention, and only the parts different from the sixth embodiment will be described. In the seventh embodiment, "the inlet of the deodorizing device 66 at 67 Da is provided with a grid for preventing foreign matter from entering." Grid 76. With this structure, food and the like can be prevented from entering the inlet 67 Da, and deodorization efficiency can be prevented from being lowered.
圖13〜圖17係本創作之第8實施例。第8實施例中之脫臭 哀置77的構’係與第6或第7實施例中之脫臭裝置66的構 造有若干之不同。脫臭裝置77係與第i實施例等相同。配 置於冷臧室6與蔬菜室π之間的冷氣循環路徑内,但如圖 13及圖14所不,代替分隔板5之分隔板78,係構成脫臭裝 置77之-部份。脫臭裝置77之盒體79上只形成有變壓器室 80及電極室81,在盒體79組裝於分隔板78之狀態下,由兩 者間所形成之空間構成冷氣流通室8 2。13 to 17 are the eighth embodiment of the present invention. The structure of the deodorizing device 77 in the eighth embodiment is slightly different from the structure of the deodorizing device 66 in the sixth or seventh embodiment. The deodorizing device 77 is the same as the i-th embodiment and the like. It is arranged in the cold air circulation path between the cold compartment 6 and the vegetable compartment π, but as shown in Figs. 13 and 14, the partition plate 78 instead of the partition plate 5 constitutes a part of the deodorizing device 77. Only the transformer chamber 80 and the electrode chamber 81 are formed on the box body 79 of the deodorizing device 77. When the box body 79 is assembled on the partition plate 78, the space formed by the two constitutes a cold air flow passage 82.
圖13係脫臭裝置77之分解透視圖,圖14⑷係冰箱之脫臭 裝置77配置部分的縱斷面圖,⑻係⑷之要部的擴大圖。 盒體79之左側近處部份所形成之變壓器請中,增壓變壓 器58之配置方向’係與第6實施例之配置方向相諸度, 相對冰箱之往深處的方向,係配置於橫向。貫通變壓器室 8〇之分隔壁83的增壓變壓器58的二次側端子58am, ^替臭氧產生用電極60A ’接續有臭氧產生用電極料。 位於臭氧產生用電極84下方處之盒體79部分,其有朝電 極室81之深處方向稍作傾斜之傾斜部79a (圖14⑻參照), 66405-930810 -25 - M268560 在臭氧產生用電極84之附近所產生的臭氧係導至電極室8i 之後方側。又,電極室81後方側之盒體79部分,設有複數 個臭氧流出孔79b,令臭氧落下至下方之冷氣流通室82。 盒體79之上部,安裝有被覆變壓器室8〇及電極室^之上 蓋85。又,盒體79之前面部,形成有朝下方側延伸之通氣 部(格栅)86,在盒體79組裝於分隔板7δ之場合,可防止異 物侵入冷氣流通室82。 其次,茲就分隔板78側之構成說明之。安裝有盒體乃之 分隔板78的部分,形成有凹部狀之安裝凹部87。安裝凹部 87之兩側,設有將冰箱内之循環冷氣不介由脫臭裝置π而 自冷藏室6直接流入蔬菜室π之流通口 88,88。安裝凹部 87中,在盒體79之通氣部86位處之部位的近處,形成有可 在使用者誤將水等灑入冰箱内時,防止水等侵入脫臭裝置 77内部之除水孔89。 又,在安裝凹部87内,在通氣部86所位處部位之後方 側’也設有朝後方側傾斜之傾斜部90,以防止異物或水等 侵入。安裝凹部87之最後部,配置有臭氧分解觸媒乃,其 係如同於第6實施例,蜂巢狀之通氣方向係朝上下方向。 臭氧分解觸媒73之外周部,捲繞有軟帶(海綿,圖未 示),壓入盒體79之配置部份,其配置部份之下面側,形 成有格子狀之防護柵91。由於臭氧分解觸媒73之芯材非常 脆弱,因此,例如在製造過程外,作業者若不小心自盒體 79之下方側碰觸到臭氧分解觸媒73 ,會有裂開或缺損之 虞。是此,在盒體79之下方側設置防護栅91,而防止臭氧 66405-930810 -26- M268560 分解觸媒73之破損。 · 又,女裝有盒體79之安裝凹部87的後方側周緣部,以包 -圍安裝狀態盒體79周圍三方之方式形成有肋條92。此一肋 條92也是用以抑制水自周邊侵入脫臭裝置”。又,圖丨4係 表不除去臭氧產生電極84之狀態。 另外,就增壓變壓器58之二側側端子58a、5扑上所接續 之臭氧產生用電極84的構成,茲佐以圖15說明之。圖15(〇 係臭氧產生用電極84之構造的模式性縱斷面圖(陶瓷基板 之厚度尺寸較實際為誇張),圖15(b)係臭氧產生用電極料· 之平面圖。臭氧產生用電極84,基本上係與第1實施例等 中之六、氧產生用電極6 〇等相同,為沿面放電形,由配置於 陶瓷基板93内部之感應電極94,及配置於陶瓷基板%表面 (放電面)附近之放電電極95所構成,在放電電極95之形狀 上具有特徵。 圖15(c)係圖15(b)中放電電極95的形狀之擴大圖。放電 電極95於其複數個部位備有朝圖i5(c)上下方向突起形狀之鲁 犬起4 95a。藉由設置此種形狀之突起部95a,電場會集中 於違部分’因此可發揮降低臭氧產生用電極84中放電起始 電壓之作用。 其次’兹就第8實施例之作用,佐以圖16及丨7說明之。 當在冷藏室6及蔬菜室13内有冰箱内冷氣循環時,其大部 分(例如約95%)係如上所述介以形成於上述分隔板78之流 通口 88或除水孔89,而自冷藏室6側直接流入蔬菜室13 側。又,循環冷氣之約5%係被調整成經由脫臭裝置77。 66405-930810 -27- M268560 具體3而言,循環冷藏室6及蔬菜室13之冷氣的總風量若為 4〇 m/H,會有約2 mVH程度流入脫臭裝置π。如此,若 ^藏室6與蔬菜室13之合計容積為35〇升時,每小時約有其 容積6倍之風量的冷氣流通過脫臭裝置77。Fig. 13 is an exploded perspective view of a deodorizing device 77, Fig. 14 is a longitudinal sectional view of a configuration portion of the deodorizing device 77 of a refrigerator, and an enlarged view of a main portion of the refrigerator. For the transformer formed near the left part of the box body 79, please refer to the arrangement direction of the booster transformer 58 to the arrangement direction of the sixth embodiment. It is arranged in the transverse direction relative to the deeper direction of the refrigerator. . The secondary-side terminal 58am of the booster transformer 58 penetrating the partition wall 83 of the transformer room 80 is connected to the ozone-generating electrode material 60A 'in place of the ozone-generating electrode material. The portion of the case 79 located below the ozone-generating electrode 84 has an inclined portion 79a slightly inclined toward the depth of the electrode chamber 81 (refer to Fig. 14), 66405-930810 -25-M268560 At the ozone-generating electrode 84 The ozone generated in the vicinity is guided to the rear side of the electrode chamber 8i. In addition, a plurality of ozone outflow holes 79b are provided in a portion of the case body 79 on the rear side of the electrode chamber 81 to allow ozone to fall to the cold air flow passage chamber 82 below. The upper part of the box body 79 is provided with a cover 85 for covering the transformer chamber 80 and the electrode chamber ^. In addition, a ventilation portion (grid) 86 extending downward is formed on the front surface of the box body 79. When the box body 79 is assembled on the partition plate 7δ, foreign matter can be prevented from entering the cold air flow passage chamber 82. Next, the configuration of the partition plate 78 side will be described. The box body is a portion where the partition plate 78 is mounted, and a recessed mounting recess 87 is formed. On both sides of the mounting recess 87, there are circulation ports 88, 88 for directly circulating the cool air in the refrigerator from the refrigerator compartment 6 to the vegetable compartment π without passing through the deodorizing device π. In the mounting recess 87, a dewatering hole is formed near the 86th position of the ventilation portion of the box body 79 to prevent water or the like from entering the deodorizing device 77 when the user accidentally spills water or the like into the refrigerator. 89. In addition, in the mounting recess 87, an inclined portion 90 which is inclined toward the rear side is provided behind the position where the vent portion 86 is located to prevent foreign matter, water, and the like from entering. The rearmost part of the mounting recess 87 is provided with an ozone decomposition catalyst, as in the sixth embodiment, and the honeycomb-shaped ventilation direction is upward and downward. A soft band (sponge, not shown) is wound around the outer periphery of the ozone decomposition catalyst 73, and the arrangement portion of the box body 79 is pressed into the lower side of the arrangement portion to form a grid-like protective grid 91. Since the core material of the ozone decomposition catalyst 73 is very fragile, for example, outside the manufacturing process, if the operator accidentally touches the ozone decomposition catalyst 73 from the lower side of the case 79, it may be cracked or damaged. In this case, a protective grille 91 is provided below the box body 79 to prevent damage of the ozone 66405-930810 -26-M268560 decomposition catalyst 73. Also, in the women's clothing, the peripheral edge portion on the rear side of the mounting recess 87 of the box body 79 is formed with ribs 92 in a three-way manner around the box body 79 in a package-mounted state. This rib 92 is also used to prevent water from entering the deodorizing device from the surroundings. Moreover, Fig. 4 shows the state of the ozone generating electrode 84. In addition, the two side terminals 58a and 5 of the booster transformer 58 are flapped on. The structure of the subsequent ozone-generating electrode 84 is described below with reference to FIG. 15 (FIG. 15 is a schematic longitudinal sectional view of the structure of the 0-type ozone-generating electrode 84 (the thickness of the ceramic substrate is exaggerated compared to the actual size), Fig. 15 (b) is a plan view of an electrode material for ozone generation. The electrode 84 for ozone generation is basically the same as the sixth one in the first embodiment and the electrode 6 for oxygen generation. The induction electrode 94 inside the ceramic substrate 93 and the discharge electrode 95 arranged near the% surface (discharge surface) of the ceramic substrate are characterized by the shape of the discharge electrode 95. Fig. 15 (c) is a figure 15 (b) An enlarged view of the shape of the intermediate discharge electrode 95. The discharge electrode 95 is provided with a plurality of protrusions 4 95a protruding in a vertical direction in FIG. I5 (c). By providing protrusions 95a of this shape, an electric field will occur. Focus on the offending 'so it can play down The effect of the discharge initiation voltage in the ozone generating electrode 84. Next, the operation of the eighth embodiment will be described with reference to Figs. 16 and 7. When there is a cold air circulation in the refrigerator in the refrigerator compartment 6 and the vegetable compartment 13, Most of them (for example, about 95%) are formed as described above through the circulation opening 88 or the water removal hole 89 of the partition plate 78, and flow directly from the refrigerating compartment 6 side into the vegetable compartment 13 side. Moreover, circulating cold air About 5% is adjusted to pass through the deodorizing device 77. 66405-930810 -27- M268560 Specifically, if the total cooling air volume of the circulating refrigerating compartment 6 and the vegetable compartment 13 is 40 m / H, there will be about 2 mVH flows into the deodorizing device π. In this way, if the total volume of the storage room 6 and the vegetable room 13 is 350 liters, a cold air flow having an air volume of about 6 times its volume passes through the deodorizing device 77 per hour.
若脫臭裝置77之增壓變壓器58被通電,冷氣產生用電極 84附近所生之臭氧較空氣為重之故,因其本身之重量,产 電極室81之傾斜部%朝後方側移動,並介以臭氧流出孔 携落下至下方之冷氣流通室82。彳以通氣部%,流入脫 臭裝置77之冷氣流通部82的循環冷氣,係以與自下方落下 之臭氧混合的狀態朝向臭氧分解觸媒73。又,包含於循環 冷氣的臭氣成分等,與上述各實施例相同,係由分解之臭 氧的活性氧氧化分解。 六 曰此處’纟圖16中,表示通過脫臭裝置77之循環冷氣的風 置變化時,以氨為指標氣體之脫臭試驗的結果。每丨小時 通過脫臭裝置77之風量,相對冷藏室6及蔬菜室13之容積 為4倍以上時,氨之殘存率成為1〇%以下係在分鐘以 内。 又,於圖17中所示的是,與圖16相同,通過脫臭裝置77 之循環冷風的風量變化時之官能試驗結果。試驗係將速食 咖哩200 g在開放狀態下收納於冷藏室6内,在經24小時後 予以取出,自該時起,再經過5小時後,嗅涓彳冷藏室6内之 臭氣,將臭氣等級分為3階段(食品殘臭,丨為幾乎無感 覺’ 2為輕微感覺,3為顯有感覺)評估。由此結果可知, 每1小時之通過風量,若相對冷藏室6及蔬菜室13之容積為 66405-930810 -28- M268560 4倍以上時’脫臭效果顯著。 如上所述,根據第8實施例,係將脫臭裝置77之電極室 8 1中所產生之臭氧,依其本身重量落下至冷氣流通室u 側,因此,可將臭氧容易地供給至冷氣流通室82。又,由 於臭氧產生用電極80係配置成相對臭氧在冷氣流通室。側 落下之方向平行之朝向,因&,臭氧產生用電極可在不 妨礙產生之臭氧朝冷氣流通室82側之流動下,將臭氧順利 地供給。 ' 再者,根據此第8實施例,相對脫臭裝置77,由於只使 循環冷氣之-部份可流通’因此可在不使冷氣過度循環, 於防止冰箱之冷卻性能的降低下進行脫臭。又,超過脫臭 裝置77中之臭氧分解觸媒73的臭氧分解反應速度之風量的 ,氣’流通至脫臭裝置77也可予防止,可謀求將脫臭效率 调整維持成適切。If the booster transformer 58 of the deodorizing device 77 is energized, the ozone generated near the air-conditioning electrode 84 is heavier than air. Because of its own weight, the inclined portion% of the electrode production chamber 81 moves to the rear side, and intervenes. A cold air flow passage chamber 82 is carried down by the ozone outflow hole. (2) The circulating cold air flowing into the cold air flow passing portion 82 of the deodorizing device 77 at the ventilation portion% is directed toward the ozone decomposition catalyst 73 in a state of being mixed with ozone falling from below. The odor components and the like contained in the circulating air-conditioner are oxidatively decomposed by the active oxygen which decomposes the odorous oxygen in the same manner as in the above embodiments. Sixth, here, FIG. 16 shows the results of a deodorization test using ammonia as an index gas when the air condition of the circulating cold air passing through the deodorizing device 77 is changed. When the volume of air passing through the deodorizing device 77 every four hours is more than four times the volume of the refrigerating compartment 6 and the vegetable compartment 13, the residual ammonia rate is 10% or less within the minute. FIG. 17 shows the results of the functional test when the air volume of the circulating cold air passing through the deodorizing device 77 is the same as that shown in FIG. 16. In the test, 200 g of instant curry was stored in the refrigerator 6 in an open state, and it was taken out after 24 hours. After that, after 5 hours, the odor in the refrigerator 6 was sniffed. The odor level is divided into 3 stages (food residual odor, 丨 means almost no sensation, 2 means slight sensation, 3 means sensation). From this result, it can be seen that if the volume of the passing air per hour is 4 times or more than the volume of the refrigerating compartment 6 and the vegetable compartment 13, 66405-930810 -28-M268560, the deodorizing effect is significant. As described above, according to the eighth embodiment, the ozone generated in the electrode chamber 81 of the deodorizing device 77 is dropped to the cold air flow passage u side according to its own weight. Therefore, the ozone can be easily supplied to the cold air flow passage u. Room 82. The ozone generating electrode 80 is arranged in a cold air flow passage with respect to ozone. Since the side-down direction is parallel, the ozone generating electrode can smoothly supply ozone without preventing the generated ozone from flowing toward the cold air flow passage 82 side. 'Furthermore, according to this eighth embodiment, since only a part of the circulating cooling air is allowed to circulate relative to the deodorizing device 77, it is possible to perform deodorization without excessively circulating the cooling air and preventing the cooling performance of the refrigerator from being reduced. . Furthermore, the flow rate of the gas that exceeds the ozone decomposition reaction speed of the ozone decomposition catalyst 73 in the deodorizing device 77 can be prevented from flowing to the deodorizing device 77, and the deodorizing efficiency can be adjusted and maintained appropriately.
相對脫臭裝置77之循環冷氣的每小時流通量係設 成冷藏室6及蔬菜室13之容積的4倍以上(6倍),因此,因 冷職室6及蔬菜室13之容積,相對脫臭裝置77之循環冷 P通量可適切設定,可良好地確保脫臭裝置77之脫臭 率。 f 一 π刊及王用電極84重複 敌電以致放電電極95之表面雄籍条& " t ^ Λ § 、虱虱化物等而有不易放電 之伐向的場合,藉由設置突 始雷严… 置大起咖而在實質上使放電開 得放h '貝之電屋降低部分成為餘裕度,使 件玫電機能可長期維持。 66405-930810 -29- M268560 圖18係本創作第9實施例,在此只就與第8實施例不同之 部分說明。第9實施例中,脫臭裝置77之循環冷氣流出 側,亦即盒體79之防護栅91下方側’配置有脫臭裝置77專 用之風扇96。此一風扇96係可與供循環冷氣之r風扇4· 動作藉由使用者之操作(例如藉由在冰箱之R門7嗖置 開關)作ΟΝ/OFF之切換或風量之增減。 °又 根據如此構成之第9實施例,藉由設置脫臭裝置π專用 之風扇96’可在無關冷藏室6之冷卻運轉狀態下,調整流 =於脫臭裝置77之冷氣的風量’因此’例如在冰箱内食品 置少而使用者認為不必|隹 勹+义要進仃脫臭時,可關掉風扇96,而 在冰箱内之食品量增多,以致使用者認為有必要脫臭時, 可令風扇96動作而在脫臭裝置77進行脫臭。又,藉由風扇 %可使流通於脫臭裝置77之風量作增減,因此,也可調整 使用者運轉脫臭裝置77時之脫臭效率。 當無須脫臭時,若中止風扇96同時也停止對於增壓 反壓為58之通電時,可降低消耗電力,同時也使臭氧 觸媒73之壽命長期化。 圖㈣本創作第10實施例,只就其與第8實施例不同之 部分說明。此第10實施例中,脫臭裝置-之通氣部86部 分,安裝有相對循環冷新之户 令孔之",L入方向可作轉動之遮斷器 97,藉而構脫臭裝置77八。遮斷器Μ之轉動,例如可藉在 脫臭裝置77A之近側部分之使用者可操作的位置預設桿體 等之操作件(圖未示),由使用者操作該操作件而進行。 圖19係通氣部86部分之正視圖,⑷係、表示將遮斷㈣相 66405-930810 -30- M268560 對循%冷氣之流入方向設成大致垂直而將通氣部86部分封 · 鎖之狀態,(b)係表示將遮斷器97相對循環冷氣之流入方向 -設成大致平行而將通氣部86部分開放之狀態。 根據如此構成之第10實施例,例如,即使冰箱内之循環 冷氣的風量一定之場合,藉由轉動遮斷器97即可變化流通 於脫六袭置77之冷氣風量及介以流通口 直接流通至蔬菜 至1 3側之冷氣風量的比率,可調整脫臭效率。 圖20係本創作第1丨實施例,只就其與第8實施例不同之 部为忒明。在第11實施例中,在設於分隔板78之流通口鲁 88,88處,設有與第10實施例中設於脫臭裝置77a之遮斷 器97具有相同作用的遮斷器98。 圖20係安裝有脫臭裝置77的狀態之88分隔板78的平面 圖,(a)係表示將遮斷器98相對循環冷氣之流入方向設成大 致垂直而將流通口 88部分封鎖之狀態,(…係表示將遮斷器 98相對循環冷氣之流入方向設成大致平行而將流通口以部 分開放之狀態。 根據如此構成之第1丨實施例,與第丨〇實施例相同,例 如,即使冰箱内之循環冷氣的風量一定之場合,藉由轉動 遮斷器98即可變化流通於脫臭裝置77之冷氣風量及介以流 通口 88直接流通至蔬菜室13側之冷氣風量的比率,可調=The hourly circulation volume of the circulating cool air relative to the deodorizing device 77 is set to be 4 times or more (6 times) the volume of the refrigerating compartment 6 and the vegetable compartment 13. Therefore, the volume of the cold room 6 and the vegetable compartment 13 is relatively depleted. The circulating cold P flux of the deodorizing device 77 can be appropriately set, which can ensure the deodorizing rate of the deodorizing device 77 well. f When the π issue and the king electrode 84 repeat the enemy electricity, so that the surface of the discharge electrode 95 has a male stripe & " t ^ Λ §, lice lice, etc., and it is difficult to discharge the direction, by setting a sudden start lightning Strictly… Set up a large coffee and actually make the discharge turn on. The lower part of the electric house is reduced to a margin, so that the piece of motor can be maintained for a long time. 66405-930810 -29- M268560 Fig. 18 is the ninth embodiment of the present invention, and only the part different from the eighth embodiment will be described here. In the ninth embodiment, the circulating cold air flow out side of the deodorizing device 77, that is, the lower side of the protective grille 91 of the box body 79 is provided with a fan 96 dedicated to the deodorizing device 77. This fan 96 can be used with the r fan 4 for circulating air-conditioning. The operation (for example, by setting a switch on the R door 7 of the refrigerator) can be used to switch ON / OFF or increase or decrease the air volume. ° According to the ninth embodiment configured as described above, by setting a fan 96 'dedicated to the deodorizing device π, it is possible to adjust the flow rate = the air volume of the cold air in the deodorizing device 77 in the cooling operation state of the refrigerating compartment 6 so " For example, when there is less food in the refrigerator and the user does not think it is necessary to deodorize, you can turn off the fan 96, and when the amount of food in the refrigerator increases, so that the user thinks it is necessary to deodorize, The fan 96 is operated to deodorize the deodorizing device 77. In addition, since the amount of air flowing through the deodorizing device 77 can be increased or decreased by the fan%, the deodorizing efficiency when the user operates the deodorizing device 77 can also be adjusted. When deodorization is not required, if the fan 96 is stopped and the energization to the boost pressure and back pressure is 58, the power consumption can be reduced, and the life of the ozone catalyst 73 can be prolonged. The tenth embodiment of the present invention is illustrated only in terms of differences from the eighth embodiment. In this tenth embodiment, the deodorizing device-the ventilation part 86 is provided with a relatively circulating cold new household order hole ", a shutter 97 that can be rotated in the inlet direction, thereby constructing a deodorizing device 77 Eight. The rotation of the interrupter M can be performed by operating an operating member (not shown), for example, by presetting an operating member (not shown) such as a lever body at a position that can be operated by a user near the deodorizing device 77A. Fig. 19 is a front view of the 86 part of the ventilation part. It is a state showing that the blocking phase 66405-930810 -30- M268560 is set to be approximately perpendicular to the inflow direction of the% cold air, and the ventilation part 86 is closed and locked. (B) shows a state in which the interrupter 97 is set to be approximately parallel to the inflow direction of the circulating cold air, and the vent portion 86 is partially opened. According to the tenth embodiment thus constituted, for example, even when the amount of circulating cold air in the refrigerator is constant, the amount of the cold air flowing through the deviating device 77 can be changed by turning the interrupter 97 and directly flowing through the circulation port. The ratio of cold air volume from vegetable to 13 sides can adjust deodorization efficiency. Fig. 20 shows the first embodiment of the present invention, and only the difference from the eighth embodiment is clear. In the eleventh embodiment, a breaker 98 having the same function as the breaker 97 provided in the deodorizing device 77a in the flow passages 88 and 88 provided in the partition plate 78 is provided. . FIG. 20 is a plan view of the 88 partition plate 78 in a state where the deodorizing device 77 is installed, and (a) shows a state in which the interrupter 98 is set to be approximately vertical with respect to the inflow direction of the circulating cold air, and the circulation port 88 is partially blocked. (... indicates a state in which the inflow direction of the interrupter 98 with respect to the circulating cold air is set to be substantially parallel and the circulation port is partially opened. According to the first embodiment thus constructed, it is the same as the first embodiment, for example, even if When the amount of circulating cold air in the refrigerator is constant, the ratio of the amount of cold air flowing through the deodorizing device 77 and the amount of cold air flowing directly to the vegetable compartment 13 through the circulation port 88 can be changed by turning the shutter 98. Tune =
脫臭效率。 I 圖21係本創作之第12實施例。冰箱係依製品之不同而在 冰箱内容積(冷藏室6及蔬菜室13之容積)上有各種不同。因 此,對於此種冰箱内容積不同之冰箱應用相同之脫臭裝置 66405-930810 -31 - M268560 77 %,在冰箱内容積小的冰箱内,臭氧濃度會增高。例 如,即使在臭氧分解觸媒73上發生某種異常以致臭氧無法 作通常般之分解時,為確保安全性,也有必要將臭氧濃度 抑制於0 · 1 ppm以下之必要。Deodorizing efficiency. I FIG. 21 is the twelfth embodiment of this creation. There are various variations in the refrigerator internal volume (the volume of the refrigerator compartment 6 and the vegetable compartment 13) depending on the product. Therefore, the same deodorizing device 66405-930810 -31-M268560 is applied to refrigerators with different refrigerator contents, and the ozone concentration will increase in refrigerators with small refrigerator contents. For example, even if an abnormality occurs in the ozone decomposition catalyst 73 so that ozone cannot be decomposed normally, it is necessary to keep the ozone concentration below 0 · 1 ppm in order to ensure safety.
疋以,此處係因應各冰箱之冰箱内容積將脫臭裝置77作 斷續運轉,調整脫臭效率。例如,如圖2 i所示,重複在1 刀’里k』下將脫臭裝置77作36秒運轉後,作24秒之運轉 伶止(此场合之運轉率為60%)此種運轉模式。如此,藉_ 由將脫臭裝置77斷續運轉,而可相對冷藏室之室内容㈣ 由脫臭裝置7所產生之臭氧的脫臭效率調整成適切。是 以可將脫臭裝置77相對冰箱内容積不同之複數種冰箱共 通地適當應用。 本創作*限上述及圖Φ中所記載之實施例,其可作以下 般之變形或擴張。 在第1實施例中,係可將臭氧產生用電極60之放電面配 置成縱向。藉由此-構成’肖第2實施例相同,可防止塵 埃之積滯。 在第3/施例之構成中,可設置第5實施例之擴散板65。 六氧擴政機構不限於擴散板65 ,只要是有臭氧擴散作 用者即可,不問其形狀。 第5實施例中,凹部75b因應必要設置即可。 :第6貫%例中,觸媒73不一定非得設於對應連通口㈣ =部位不可。又,增壓變壓器58之一次側端子58c也不一 定要朝向下方配置。 66405-930810 -32- M268560 脫臭裝置之配置部位不限於圖㈣示者,也可適當地變* 更貫施。 _ 二於弟9實施例中,風扇可配置於脫臭裝置77之通氣部% 前面你J。 又’也可例如在間7設置用卩增加循環冷氣風量之開 ^ ’藉由此一構成,例如使用者期待進行強力脫臭之場 合,藉由操作上述開關,可藉脫臭裝置77流通多量之循環 冷氣’提高脫臭效率。 _ 可使脫臭裝置77之運轉時間,因應相對該脫臭裝置”之鲁 循環冷氣的流通量而變化。例如,在相對脫臭裝置π之循 環冷氣的&通量增加之場合,# 一起肖長脫臭袭置77之運 轉時間,可使脫臭效率適切地提高。反之,若循環冷氣之 流通量減少之場合,藉由縮短脫臭裝置77之運轉時間,可 防止脫臭裝置77内臭氧之停滯。 [創作之效果] 本創作係如上所說明,可發揮以下之效果。 根據申請專利範圍第1項之脫臭裝置,增壓變壓器藉由鲁 配置於第一室而自循環冰箱内之冷氣被遮斷,只有臭氧產 生用電極在第二室内暴露於循環冷氣中。此外,在冰箱門 開閉%,也不會直接暴露於流入冰箱内之外界氣體中。是 以,可盡量緩和增壓變壓器周邊的溫度變化,而防止結露 之發生,謀求壽命之延長。 、、σ路 其並備有以遮覆臭氧產生用電極周圍之方式構成的遮覆 構造者,因此,就臭氧產生用電極也是,例如,可防止冰 66405-930810 -33- M268560 箱門開閉日寺流入冰箱内之外界氣體等直接與其接觸,可抑 制溫度急劇之__L昇。 根據申請專利範圍第2項之脫臭裝置,自該遮覆構造, 含臭軋空氣流出之部位,設有供抑制其流量之節流構造 者口此可防止3同/辰度臭氧之空氣與臭氧分解機構直 接接觸,而抑制臭氧分解機構之劣化等等。 根據申請專利範圍第3項之脫臭裝置,該臭氧產生用電 極與臭氧分解機構之間,備有用以擴散含臭氧空氣之臭氧 擴散,構者’因此’與中請專利範圍第2項相@,可防止 含高濃度之臭氧的空氣與臭氧分解機構直接接觸。 根據申請專利範圍第4項脫臭裝置,在變壓器室内所配 置之增壓變壓器’肖中請專利項相同,係與循環 於冰箱内之冷氣遮斷冰箱内之循環冷氣係流通至A 氣流通室^臭氧係自電極室介於連通口供給。是以,: 極至内之臭乳產生用電極也不會與冰箱内之循環冷氣 開閉時流人冰箱内之外界氣體直接接觸,&而,臭氧 用電極之溫度變化可獲抑制。 根據申請專利範圍第5項 構,係對應於連通口之心=“置,该臭氧分解機 行臭氧之分解。 ·置者,因此,可有效率地進 根據申請專利範圍第6項 極,其產生放電之放電面其 位於電極室内者,可減小兩 臭氧產生用電極之熱應力, 之脫臭裝置,氧產生用電 内面之非放電面此二面,均係 者間之溫度梯度,而減輕加諸 可延長壽命。 66405-930810 '34- M268560 根據申請專利範圍第7 生之臭氧,係藉其本身之二下t:極室内所產 ,,里洛下至冷氣流通室側者,因 氣流通室内。 重…臭乳可容易地供給至冷 根據申請專利範圍第8項之脫臭裝置,該臭氧產生用電 … …下至冷氣流通室側之方向,配置成盥豆 平行朝向者。因此,自、汽 六虱產生用龟極,可妨害產生之臭氧 朝向冷氣流通室側之流動,可將臭氧圓滑地供給。 :::請專利範圍第9項之脫臭裝置,該臭氧產生用電 極之放笔面,係配置成縱 於臭氧產生用電極。 τ防止塵埃等積滞 根據申請專利範圍第_之脫臭袭置,該增壓變壓 一次側端子,係w ^ τ I ° 置成朝向下方者°因此,例如可防止水 刀專!供電線等侵入增壓電壓器之一次側。 根據申請專利範圍第u項之脫臭裝置,該循環冷氣之流 =口部份處,配置有異物侵人防止㈣柵者。因此,可防 耗食品等異物侵人流出而降低脫臭效率於未然。 根據申請專利範圍第 乾圍第12項之冰相,其具備中請專利範圍 ::物之脫臭裝置。因此,可防止增㈣麼器中之結露 寻等,使得冰箱内之脫臭效果持續維持於安定狀態。 根據申請專利範圍第13項之冰箱’該循環冷氣:回歸路 么則’配置脫臭裝置者。是以,可使脫臭有效率地進行。 根據申請專利範圍第14項之冰箱,由共通之冷卻器所產 生之冷氣,係猶環至冷藏室及蔬菜室;脫臭裝置係配置於 66405-930810 -35- M268560 域循環冷氣自上述冷藏室側流入上述蔬菜室側之境界部-伤者因此’可有效率地使用略為死角空間之部份,可盡. 置抑制冰箱内食品貯存容積之減少。 根據申請專利範圍第15項之冰箱,該脫臭裝置中之循環 冷氣流入口位置處的近處之冷藏室底板部份,設有水分侵 入防止用凹部者。因此’朝向流入口之水分,係可由其近 處之凹部所捕捉,可防止水分對於脫臭裝置之侵入。 根據申請專利範圍第16項之冰箱,該脫臭裝置係配置於 冷藏室内之循環冷氣吸入部者。因此,藉此使脫臭裝置位# 於循環冷氣之回歸路徑的末端,可使脫臭效率進一步提 高。 根據申請專利範圍第17項之冰箱,增壓變壓器係藉由配 置於變壓器室内而自冰箱内循環之冷氣被遮斷,而只有臭 氧產生用電極在變壓器室之外部暴露於循環冷氣中。又,' 在冰箱之門開閉時,增壓變壓器不會暴露於流入冰箱内之 外界氣體。因此,可盡量緩和增壓變壓器周邊之溫度變 化’防止結露之產生,可延長壽命。 籲 又,對於令冷藏室内之循環冷氣流通而進行脫臭之脫臭 裝置,由於只令循環冷氣的一部份流通至脫臭裝置,因此 可在防止冷卻性能降低下進行脫臭。又,也可謀求進行調 整而適切地維持脫臭效率。 根據申請專利範圍第1 8項之冰箱,相對脫臭裝置之/盾广 4氣的母1小日^之流通置’係設定為冷藏室容積之*彳立、 者。因此,可因應冰箱之容積適切地設定對於脫自、 六、展置之 66405-9308J0 -36- M268560 L:冷氣的流通量,故而可良好地確保脫臭裝置中之脫臭 環冷氣圍第19項之冰箱,該相對脫臭裝置之循 仅~礼的流通量,係 係形成為可變化者。因此,即#县、a # 内所貯存之食品等的量變…… 卩使疋冰相 減對於脫臭裝置之〆“肖由因應此-變化增 裝置中脫臭效率。…的流通量,可適切地維持脫臭 «中請專·圍第2G項之冰箱,該脫臭裝置中,備有 獨:通循被冷氣之專用風扇者。因此,與冷卻運轉之狀態 行脫臭可精由專用之風扇對於脫臭裝置流通以循環冷氣進 如申請專利範圍第21項之冰箱,流通至脫臭裳置之 循環冷氣’與流通至除此之外的部份之循環冷氣,其比率 係可變化者。因此,即使冰箱内之循環冷氣的流量為—定 之^合’ 變化流通至脫臭裝置的量與流通至以外部份 的量之比率’可相對地變化流通至脫臭裝置之循環冷氣的 量0 根據申請專利範圍第22項之冰箱’其中設有用以增加循 環冷氣風量之開關者。因此,在使用者進行強力脫臭之場 合,藉由操作上述開關,可藉脫臭裝置流通多量之循環冷 氣提南脫臭率率。 根據申請專利範圍第23項之冰箱,藉由脫臭裝置之斷續 運轉,而可調整脫臭效率者。因此,可相對冷藏室之容積 將脫臭率率適切調整。 66405-930810 -37- M268560 根據申明專利範圍第24項之冰箱,該脫臭裝置之運轉時 間係因應相對該脫臭裝置之循環冷氣的流通量而變化 者。因此,例如相對脫臭裝置之循環冷氣的流通量增加之 場合,若一併增長脫臭裝置之運轉時間的話,脫臭效率會 適切地提高。反之,在循環冷氣之流通量減少之場合,藉 由縮短脫臭裝置之運轉時間,可防止臭氧停滞於脫臭裳置 内0 【圖式簡單說明】 圖1係本創作之第丨實施例,表示脫臭裝置的構成之斜 圖。 圖2係冰箱之縱斷側視圖。 圖3係表示本創作第2實施例的與圖2相當之圖。 圖4係脫臭裝置之正視圖。 圖5係本創作之第3實施例,表示脫臭裝置的部份構成之 斜視圖。 圖6係本創作之第4實施例,表示遮覆構造的構成之斜視 圖。 ’、 圖7係本創作之第5實施例,係在圖6之構成中附加擴散 板的構成之斜視圖。 圖8係表示本創作第6實施例的與圖2相當之圖。 圖9係與圖1相當之圖。 圖1 〇係脫臭裝置之平面圖。 圖Π係以脫臭裝置為中心的一部份之擴大縱斷側視圖。 圖12係本創作第7實施例的與圖9相當之圖。 66405-930810 M268560 圖13係本創作之第8實施例,係脫臭裝置之分解 圖。 优 圖Η⑷係冰箱的要部之縱斷側視圖,⑻係⑷的 擴大圖。 ㈣⑼系臭氧產生用電極的構造之模式性縱斷側視圖, (b)係臭氧產生用電極之平面圖,⑷係、(b)中放電電 狀之擴大圖。 ^ 圖16係通過脫臭裝置之循環冷氣的風量變化之場合,以 氨作為指標氣體的脫臭試驗之結果圖。 圖17係通過脫臭裝置之循環冷氣的風量變化之場合,— 月&測試之結果圖。 一 圖18係表示本創作第9實施例的與圖l4(b)相當之圖。 、圖19係表示本創作第丨。實施例的部份之正視:二係部 份封死之狀態圖,(b)係部份開放之狀態圖。 圖20係表示本創作第11實施例之安裝脫臭裝置狀態的分 隔板之平面圖,⑷係流通口部份封鎖狀態之圖 通口部份開放狀態之圖。 ’、机 圖2i係本創作之第12實施例,表示脫臭狀繼續運 運轉模式圖。 ^ 【主要元件符號說明】 5、5A分隔板(冷藏室底板)、6冷藏室、^、1丨續臭裝 置、38冷氣吸入口、57變壓器室(第—室)、以增壓變壓 器、58c—二欠側端子、他、娜二次側端子、μ電極室(第 二室)、60臭氧產生用電極、61觸媒(臭氧分解機構〇被 66405-930810 -39- M268560 覆構造、罐構造、65擴散板(臭氧擴散機構)、“脫臭 裝置、㈣下層部(冷氣流通室卜咖連通口 I變壓哭That is, here, the deodorizing device 77 is intermittently operated in accordance with the refrigerator internal volume of each refrigerator to adjust the deodorizing efficiency. For example, as shown in Fig. 2i, the operation mode of the deodorizing device 77 is repeatedly operated for 36 seconds under 1 knife 'li k', and the operation is performed for 24 seconds (the operating rate in this case is 60%). . In this way, by intermittently operating the deodorizing device 77, it is possible to adjust the deodorizing efficiency of the ozone generated by the deodorizing device 7 to an appropriate level relative to the contents of the refrigerator compartment. It is suitable to apply the deodorizing device 77 to a plurality of refrigerators having different contents of refrigerators in common. This creation is limited to the embodiments described above and shown in Figure Φ, which can be modified or expanded as follows. In the first embodiment, the discharge surface of the ozone generating electrode 60 can be arranged in the vertical direction. By the same configuration as in the second embodiment, the accumulation of dust can be prevented. In the structure of the third embodiment, a diffusion plate 65 of the fifth embodiment may be provided. The hexaoxygen expansion mechanism is not limited to the diffusion plate 65, as long as it has an ozone diffusion effect, regardless of its shape. In the fifth embodiment, the recessed portion 75b may be provided as necessary. : In the 6th percentile example, the catalyst 73 does not necessarily have to be provided at the corresponding communication port ㈣ = part is impossible. The primary-side terminal 58c of the step-up transformer 58 is not necessarily arranged downward. 66405-930810 -32- M268560 The location of the deodorizing device is not limited to those shown in the figure, but it can be changed as appropriate * for more consistent application. _ In the second embodiment, the fan may be disposed in front of the ventilation portion of the deodorizing device 77%. It is also possible to increase the amount of circulating cold air for example by installing 卩 in room 7. With this configuration, for example, when the user expects a strong deodorization, by operating the switch, a large amount can be circulated by the deodorizing device 77. The circulating air-conditioning 'improves deodorization efficiency. _ The operating time of the deodorizing device 77 can be changed in accordance with the circulation volume of the circulating cooling air in the deodorizing device. For example, when the & flux of the circulating cooling air in the deodorizing device π increases, # 同Xiao Chang's operating time of the deodorizing device 77 can appropriately improve the deodorizing efficiency. Conversely, if the circulating cold air flow is reduced, by shortening the operating time of the deodorizing device 77, the inside of the deodorizing device 77 can be prevented. The stagnation of ozone. [Effect of creation] This creation is as described above, and can exert the following effects. According to the deodorizing device of the first patent application scope, the booster transformer is arranged in the first room and is in a self-circulating refrigerator. The cold air is blocked, and only the ozone-generating electrode is exposed to the circulating cold air in the second room. In addition, when the refrigerator door is opened and closed, it will not be directly exposed to the gas flowing into the inside and outside of the refrigerator. Therefore, it can be as slow as possible. The temperature change around the transformer prevents the occurrence of dew condensation and seeks to extend the life. The σ, σ, and σ are equipped with a covering structure that covers the surroundings of the electrodes for ozone generation. Therefore, the electrode for ozone generation is also used, for example, it can prevent ice 66405-930810 -33- M268560 from opening and closing of the door of the box and entering the outer and outer gas of the refrigerator, etc., and it can suppress the sharp __L rise of temperature. The deodorizing device in the scope of the patent application No. 2 is provided with a throttling structure for suppressing the flow of the odorous rolling air from the covering structure. This can prevent the air and ozone of 3 ozone. The decomposing mechanism is in direct contact to suppress the degradation of the ozone decomposing mechanism, etc. According to the deodorizing device of the third scope of the application for a patent, the ozone generating electrode and the ozone decomposing mechanism are provided for diffusing ozone containing ozone-containing air, The structurer 'is therefore in line with item 2 of the Chinese patent scope, which can prevent the air containing high concentration of ozone from directly contacting the ozone decomposing mechanism. According to the item 4 of the scope of the patent application, the deodorizing device is added in the transformer room. The voltage transformer 'Xiao Zhong's patented item is the same as the cold air circulating in the refrigerator to block the circulating cold air in the refrigerator from flowing to the A air flow chamber ^ The ozone is from the electrode chamber It is supplied at the communication port. Therefore, the electrode for the stinky milk generation inside will not come into direct contact with the outside gas flowing into the refrigerator when the circulating cold air in the refrigerator is opened and closed, and the temperature change of the ozone electrode can be obtained. Suppression. According to the 5th structure of the scope of the patent application, it corresponds to the heart of the communication port = "set, this ozone decomposition machine performs ozone decomposition. · The installer can efficiently enter the electrode according to item 6 of the scope of the patent application, and the discharge surface where the discharge is generated is located in the electrode chamber, which can reduce the thermal stress of the two ozone generating electrodes, the deodorizing device, and the oxygen The two sides of the non-discharge surface that generate the inner side of the electricity are the temperature gradients between them, and lightening can extend the life. 66405-930810 '34-M268560 According to the 7th ozone of the scope of the patent application, it is based on two of its own t: produced in the polar room, and from the bottom of the lilo to the side of the cold airflow passage, because the airflow passes through the room. Heavy ... Stinky milk can be easily supplied to the cold. According to the deodorizing device of claim 8 of the patent application, the electricity for ozone generation ... is arranged to the side of the cold air flow passage side, and the toilet beans are arranged in parallel. Therefore, the tortoise poles for the production of hexapods can prevent the generated ozone from flowing toward the side of the cold air flow passage, and can smoothly supply the ozone. ::: Please use the deodorizing device of item 9 of the patent scope. The writing surface of the ozone generating electrode is arranged to be vertical to the ozone generating electrode. τ Prevent accumulation of dust, etc. According to the deodorization of the scope of the patent application, the booster transformer primary terminal is w ^ τ I ° is set to face downward ° Therefore, for example, waterjet can be prevented! Power supply lines and the like penetrate into the primary side of the booster. According to the deodorizing device in the scope of application for patent item u, the circulating cold air flow = mouth part is equipped with foreign objects to prevent people from invading the grille. Therefore, it is possible to prevent foreign matter such as foodstuffs from invading the human body and reduce the deodorization efficiency. According to the ice phase of the dry patent No. 12 in the scope of the patent application, it has the deodorization device of the patent scope ::. Therefore, it is possible to prevent dew condensation and the like in the booster, so that the deodorizing effect in the refrigerator can be maintained in a stable state. According to refrigerator No. 13 of the scope of the patent application, the circulating air conditioner: return circuit is equipped with a deodorizing device. Therefore, deodorization can be performed efficiently. According to item 14 of the scope of the patent application, the cold air generated by the common cooler is still connected to the refrigerating room and the vegetable room. The deodorizing device is configured at 66405-930810 -35- M268560. The side that flows into the boundary part of the vegetable room side-the injured person can therefore use the part of the dead space effectively, which can be used as much as possible to suppress the reduction of the food storage volume in the refrigerator. According to the refrigerator in the scope of the patent application No. 15, the bottom portion of the refrigerating compartment near the circulating cold airflow inlet in the deodorizing device is provided with a recess for preventing moisture from entering. Therefore, the moisture directed toward the inflow port can be captured by the recesses near it, preventing the moisture from entering the deodorizing device. According to the refrigerator in item 16 of the scope of the patent application, the deodorizing device is a circulating cold air intake section arranged in a refrigerating room. Therefore, by setting the deodorizing device # at the end of the return path of the circulating cold air, the deodorizing efficiency can be further improved. According to the refrigerator in item 17 of the scope of the patent application, the booster transformer is shielded from circulating cold air by being placed in the transformer room, and only the ozone-generating electrode is exposed to the circulating cool air outside the transformer room. Also, when the door of the refrigerator is opened and closed, the booster transformer will not be exposed to the outside air flowing into the refrigerator. Therefore, the temperature change around the booster transformer can be mitigated as much as possible 'to prevent the occurrence of dew condensation and the life can be extended. It is appealed that the deodorizing device that allows the circulating cold air flow in the refrigerating chamber to pass through the deodorizing device allows only a part of the circulating cold air to flow to the deodorizing device, so that the deodorizing device can be deodorized without reducing the cooling performance. It is also possible to adjust to appropriately maintain the deodorizing efficiency. According to the refrigerator in item 18 of the scope of the applied patent, the relative circulation of the deodorizing device / Dong Guang 4 gas of the mother 1 small day ^ is set to the height of the refrigerating compartment. Therefore, according to the volume of the refrigerator, it can be appropriately set. For the free air circulation of 66405-9308J0 -36- M268560 L: the cooling air flow rate, the deodorizing ring in the deodorizing device can be ensured. The refrigerator of this item, the circulation of the relative deodorizing device is only ~, the circulation volume is formed as a changeable person. Therefore, the amount of food stored in # 县, a #, etc. is changed ... 卩 Subtract the ice from the ice. For the deodorization device, "Xiao You responds to this change-increasing the deodorization efficiency in the device .... Appropriately maintain deodorization «Chinese-special-designed 2G refrigerators. This deodorization device is equipped with a unique: a dedicated fan that passes through the air-conditioning. Therefore, deodorization can be performed in the state of cooling operation. The ratio of the circulating cooling air flowing through the deodorizing device to the refrigerator such as item 21 of the patent application scope, the circulating cooling air circulating to the deodorizing rack, and the circulating cooling air circulating to other parts can be changed. Therefore, even if the flow rate of the circulating cold air in the refrigerator is-fixed, the ratio of the amount of circulating cold air to the deodorizing device to the amount of circulating to the outside part can be changed relatively. Quantity 0 The refrigerator according to item 22 of the scope of the patent application is provided with a switch to increase the amount of circulating cold air. Therefore, when the user performs a strong deodorization, by operating the switch, a large amount of the deodorization device can be circulated. The deodorization rate of the circulating cold air is raised to the south. According to the refrigerator in item 23 of the patent application scope, the deodorization efficiency can be adjusted by the intermittent operation of the deodorization device. Therefore, the deodorization rate can be compared with the volume of the refrigerator Appropriate adjustments. 66405-930810 -37- M268560 According to the refrigerator in the scope of the declared patent, the operating time of the deodorizing device is changed according to the circulating cold air flow of the deodorizing device. Therefore, for example, relative deodorization When the circulating cold air flow of the device is increased, if the operating time of the deodorizing device is increased, the deodorizing efficiency will be appropriately increased. On the contrary, when the circulating cold air flow is reduced, the deodorizing device is shortened. Operating time can prevent ozone from stagnation in the deodorizing clothes. [Brief description of the drawing] Fig. 1 is a perspective view showing the structure of a deodorizing device according to the first embodiment of the present invention. Fig. 2 is a vertical side view of the refrigerator Fig. 3 is a view corresponding to Fig. 2 showing the second embodiment of the present invention. Fig. 4 is a front view of the deodorizing device. Fig. 5 is a third embodiment of the present invention, showing a partial deflection of the deodorizing device. Fig. 6 is a perspective view of the fourth embodiment of the present invention, showing the structure of the covering structure. ', Fig. 7 is a perspective view of the fifth embodiment of the present invention, and is a perspective view of the structure of the diffuser plate added to the structure of Fig. 6. Fig. 8 is a diagram corresponding to Fig. 2 showing a sixth embodiment of the present invention. Fig. 9 is a diagram corresponding to Fig. 1. Fig. 10 is a plan view of a deodorizing device. Fig. Π is a center of the deodorizing device. A partly enlarged longitudinal section side view. Fig. 12 is a view equivalent to Fig. 9 of the seventh embodiment of this creation. 66405-930810 M268560 Fig. 13 is an exploded view of the eighth embodiment of this creation. The excellent picture is a longitudinal sectional side view of the main part of the refrigerator, and is an enlarged view of a ⑷. A schematic longitudinal sectional side view of the structure of the ozone generating electrode, (b) a plan view of the ozone generating electrode, , (B) An enlarged view of the electrical discharge state. ^ Fig. 16 is a graph showing the results of a deodorization test using ammonia as an index gas when the air volume of the circulating cold air passing through the deodorizing device changes. Fig. 17 is a graph showing the results of the monthly & test when the air volume of the circulating cold air passing through the deodorizing device changes. Fig. 18 is a view corresponding to Fig. 14 (b) showing the ninth embodiment of the present invention. Figure 19 shows the first part of this creation. The front view of the part of the embodiment: the state diagram of the second part partially sealed, and (b) the state diagram of the part opened. Fig. 20 is a plan view of a partition plate showing a state where a deodorizing device is installed in the eleventh embodiment of the present invention, and is a diagram showing a state where a circulation port is partially blocked; a state where a port is opened. Figure 2i is a twelfth embodiment of the present invention, showing the operation mode of the deodorizing continuous operation. ^ [Description of main component symbols] 5, 5A partition plate (frozen room bottom plate), 6 refrigerated room, ^, 1 丨 continuous odor device, 38 cold air intake, 57 transformer room (first room), booster transformer, 58c—Secondary under terminal, other secondary terminal, μ electrode chamber (second chamber), 60 ozone generating electrode, 61 catalyst (ozone decomposing mechanism. Covered by 66405-930810 -39- M268560, can Structure, 65 diffuser plate (ozone diffusion mechanism), "deodorizing device, lower part of the lower part (cold air flow chamber, coffee outlet I, pressure change)
室、72電極室、73觸媒(臭氧分解機構)、75分隔板(冷藏I 底板)、75b凹部、76格栅、77、77A脱& 至 7A脫臭裝置、79b臭象Chamber, 72 electrode chamber, 73 catalyst (ozonolysis mechanism), 75 partition plate (refrigeration I bottom plate), 75b recess, 76 grille, 77, 77A de & to 7A deodorizer, 79b odor
出孔(連通口)、80變壓器室、81带把 /;,L 兒極室、8 2冷氣Outlet (connecting port), 80 transformer room, 81 with handle /, L child pole room, 8 2 air conditioner
84臭氧產生用電極、96風扇(專用風屬)。P84 ozone generating electrode, 96 fan (special wind type). P
66405-930810 40-66405-930810 40-
Claims (1)
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP2000080034 | 2000-03-22 | ||
JP2000262831A JP2001336871A (en) | 2000-03-22 | 2000-08-31 | Deodorizer and refrigerator |
Publications (1)
Publication Number | Publication Date |
---|---|
TWM268560U true TWM268560U (en) | 2005-06-21 |
Family
ID=26588053
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
TW093211047U TWM268560U (en) | 2000-03-22 | 2000-09-27 | Foul odors separating device and refrigerator |
Country Status (6)
Country | Link |
---|---|
JP (1) | JP2001336871A (en) |
KR (1) | KR100406093B1 (en) |
CN (1) | CN100398952C (en) |
ID (1) | ID29689A (en) |
SG (1) | SG88815A1 (en) |
TW (1) | TWM268560U (en) |
Families Citing this family (9)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JP4458779B2 (en) * | 2003-07-10 | 2010-04-28 | 株式会社東芝 | refrigerator |
JP5359174B2 (en) * | 2007-10-31 | 2013-12-04 | パナソニック株式会社 | refrigerator |
JP5248275B2 (en) * | 2008-11-18 | 2013-07-31 | 株式会社東芝 | refrigerator |
CN102197860B (en) * | 2010-03-24 | 2014-06-04 | 海信(北京)电器有限公司 | Deodorization device and refrigerator provided with same |
CN103423945A (en) * | 2013-09-05 | 2013-12-04 | 合肥美的电冰箱有限公司 | Refrigerator |
CO7280072U1 (en) * | 2014-11-20 | 2015-05-29 | Brenes Marta Patricia Patiño | Ozonation device for refrigerators and refrigerators |
JP6449389B2 (en) * | 2017-08-08 | 2019-01-09 | 東芝ライフスタイル株式会社 | refrigerator |
JP7198109B2 (en) * | 2019-02-14 | 2022-12-28 | シャープ株式会社 | refrigerator |
CN113915831B (en) * | 2021-06-28 | 2023-07-07 | 海信冰箱有限公司 | Refrigerator and refrigerator purification control method |
Family Cites Families (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPH01172201A (en) * | 1987-12-10 | 1989-07-07 | Asahi Glass Co Ltd | Ozone generator |
JPH01164702A (en) * | 1987-12-21 | 1989-06-28 | Mitsubishi Electric Corp | Ozonizer for refrigerator |
CN88205179U (en) * | 1988-04-28 | 1988-12-14 | 张勤 | Electronic freash-keeping and smell-removing device for ice box |
CN2111760U (en) * | 1991-10-28 | 1992-08-05 | 李华 | Miniature ice cabinet, freezer deodorising and fresh-keeping device |
CN2187950Y (en) * | 1993-02-10 | 1995-01-25 | 成都蓉高新技术研究院化机电研究所 | Catalitic cleaning type ozone disinfection and deodorisation device |
-
2000
- 2000-08-31 JP JP2000262831A patent/JP2001336871A/en active Pending
- 2000-09-27 TW TW093211047U patent/TWM268560U/en not_active IP Right Cessation
- 2000-10-12 CN CNB001317717A patent/CN100398952C/en not_active Expired - Fee Related
-
2001
- 2001-03-16 SG SG200101641A patent/SG88815A1/en unknown
- 2001-03-21 ID IDP20010237D patent/ID29689A/en unknown
- 2001-03-21 KR KR10-2001-0014483A patent/KR100406093B1/en not_active IP Right Cessation
Also Published As
Publication number | Publication date |
---|---|
ID29689A (en) | 2001-09-27 |
CN100398952C (en) | 2008-07-02 |
KR20010092701A (en) | 2001-10-26 |
SG88815A1 (en) | 2002-05-21 |
CN1314573A (en) | 2001-09-26 |
KR100406093B1 (en) | 2003-11-15 |
JP2001336871A (en) | 2001-12-07 |
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MK4K | Expiration of patent term of a granted utility model |