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JPS634895Y2 - - Google Patents

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Publication number
JPS634895Y2
JPS634895Y2 JP1983008785U JP878583U JPS634895Y2 JP S634895 Y2 JPS634895 Y2 JP S634895Y2 JP 1983008785 U JP1983008785 U JP 1983008785U JP 878583 U JP878583 U JP 878583U JP S634895 Y2 JPS634895 Y2 JP S634895Y2
Authority
JP
Japan
Prior art keywords
heat exchanger
room
ventilation path
ventilation passage
solenoid valve
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired
Application number
JP1983008785U
Other languages
Japanese (ja)
Other versions
JPS59115226U (en
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed filed Critical
Priority to JP878583U priority Critical patent/JPS59115226U/en
Publication of JPS59115226U publication Critical patent/JPS59115226U/en
Application granted granted Critical
Publication of JPS634895Y2 publication Critical patent/JPS634895Y2/ja
Granted legal-status Critical Current

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  • Air-Conditioning Room Units, And Self-Contained Units In General (AREA)

Description

【考案の詳細な説明】 この考案は空気調和装置の室内機の改良に関す
るものである。
[Detailed Description of the Invention] This invention relates to an improvement of an indoor unit of an air conditioner.

従来の空気調和装置の室内機は、外筐内に単独
の通風路を設け、この通風路に熱交換器を内設
し、通風路に送風する送風機を設けて構成され、
暖房時には熱交換器を加熱して送風機の吐出を室
内下方に向け、また、冷房時には熱交換器を冷却
して送風機の吐出を室内上方に向けることによつ
て冷暖房は行なわれていたが、特に暖房時におい
ては室内温度分布が第1図に示すように、天井に
近い程温度は高く、床に近い程温度は低くなり、
頭部が暑く足部が冷たいといつた不快感があり、
また、居住空間以外を加熱することから熱損失が
多くなる欠点があつた。
A conventional indoor unit of an air conditioner is configured by providing a single ventilation passage inside the outer casing, installing a heat exchanger inside this ventilation passage, and installing a blower to blow air into the ventilation passage.
Heating and cooling was performed by heating a heat exchanger and directing the blower's discharge downwards indoors during heating, and by cooling the heat exchanger and directing the blower discharge upwards indoors during cooling. During heating, the temperature distribution in the room is as shown in Figure 1, the closer to the ceiling the higher the temperature, and the closer to the floor the lower the temperature.
There is a feeling of discomfort when the head is hot and the feet are cold.
Another drawback is that heat loss increases because areas other than the living space are heated.

この考案は上記欠点に鑑みなされたもので、暖
房時における室内温度分布が良好な空気調和装置
の室内機を提供することを目的とするものであ
る。
This invention was made in view of the above-mentioned drawbacks, and the purpose is to provide an indoor unit of an air conditioner that provides a good indoor temperature distribution during heating.

以下、この考案の一実施例を第2図および第3
図に従つて説明すると、図において1は空気調和
装置で、室内に設置される室内機2と室外に設置
される室外機3とから形成されている。室内機2
は、外筐4内の上部に第1通風路5と下部に第2
通風路6を設け、これら第1通風路および第2通
風路内には第1熱交換器7と第2熱交換器8が別
個に設けられ、上記第1通風路5と上記第2通風
路6にはそれぞれ横流フアンで形成した送風機9
が、羽根10、電動機(図示せず)、羽根ケーシ
ング12を有して設けられ、それぞれの通風路
5,6の吐出部にはその吐出方向を変更すること
が可能な風向板13,14が設けられ、第1通風
路5の吐出口5aは外筐4前面の上端部に、第2
通風路6の吐出口5bは外筐4前面の下端部に設
けられ、4a,4bは第1,第2通風路5,6の
吸気口であり、上記第1熱交換器7と上記第2熱
交換器8は絞り抵抗15と並設された電磁弁16
とを介してて接続されている。室外機3は上記第
1熱交換器7と接続される冷媒加熱器17、圧縮
機18、室外熱交換器19、絞り抵抗部20とを
直列に設け上記第2熱交換器8に接続して冷凍サ
イクルを形成するとともに、上記室外熱交換器1
9と絞り抵抗部20をバイパスするバイパス回路
21を電磁弁22を介して接続し、冷媒加熱器1
7部分にはこれを加熱するバーナ23が設けら
れ、室外熱交換器19部分にはこれに送風する室
外フアン24が設けられている。25は室内の上
部に設置される温度検知素子で、制御回路26を
介してバーナ23および電磁弁16を制御する。
An example of this invention is shown below in Figures 2 and 3.
To explain according to the drawings, 1 in the drawings is an air conditioner, which is composed of an indoor unit 2 installed indoors and an outdoor unit 3 installed outdoors. Indoor unit 2
There is a first ventilation passage 5 in the upper part of the outer casing 4 and a second ventilation passage in the lower part.
A ventilation passage 6 is provided, and a first heat exchanger 7 and a second heat exchanger 8 are separately provided in the first ventilation passage and the second ventilation passage. 6 each has a blower 9 formed by a cross-flow fan.
is provided with a blade 10, an electric motor (not shown), and a blade casing 12, and the discharge portion of each ventilation passage 5, 6 is provided with a wind direction plate 13, 14 that can change the discharge direction. The discharge port 5a of the first ventilation path 5 is provided at the upper end of the front surface of the outer casing 4, and the second
The outlet 5b of the ventilation passage 6 is provided at the lower end of the front surface of the outer casing 4, and 4a and 4b are intake ports of the first and second ventilation passages 5 and 6, and the first heat exchanger 7 and the second The heat exchanger 8 includes a solenoid valve 16 installed in parallel with a throttle resistor 15.
It is connected through. The outdoor unit 3 includes a refrigerant heater 17, a compressor 18, an outdoor heat exchanger 19, and a throttle resistor 20 connected to the first heat exchanger 7 in series, and is connected to the second heat exchanger 8. In addition to forming a refrigeration cycle, the outdoor heat exchanger 1
9 and a bypass circuit 21 that bypasses the throttle resistance section 20 are connected via a solenoid valve 22, and the refrigerant heater 1
A burner 23 is provided at the 7th section to heat this, and an outdoor fan 24 is provided at the outdoor heat exchanger 19 section to blow air thereto. Reference numeral 25 denotes a temperature sensing element installed in the upper part of the room, which controls the burner 23 and the solenoid valve 16 via a control circuit 26.

上記のように構成されたものにおいてその動作
を説明すると、まず、暖房時において暖房初期の
ように室内温度が低く加熱暖房(以下、加熱暖房
という)する場合には、これを温度検知素子25
で検知し電磁弁16をONして開放し、バーナ2
3を燃焼させ、かつ電磁弁22もONして開放す
る。また、風向板13,14を吐出方向が下方に
なるように移動させる。これにより冷媒は破線で
示すように冷媒加熱器17で加熱され蒸発して高
温高圧ガス冷媒となり圧縮機18に吸入、吐出さ
れ、バイパス回路21を通つて第2熱交換器8、
さらに電磁弁16を通つて第1熱交換器7に至り
冷媒加熱器17に戻る。このとき、第1および第
2熱交換器7,8を加熱し、送風機9,9を運転
することで熱交換され室内は加熱暖房されるが、
このときの室内温度分布は従来と同様に第1図の
ようになるが、室内上部の温度が所定温度まで上
昇すると、これを温度検知素子25が検知し、暖
房された室上部の熱を利用して室下部を暖房する
ようにした熱利用運転(以下、熱利用運転とい
う)に切り換わる。すなわち、室内上部の温度が
所定温度になると、温度検知素子25によつて電
磁弁16はOFFされ閉塞し、バーナ23の燃焼
は止め、かつ風向板14側のみそのままで、風向
板14を移動させ室上方に吐出されるように移動
させる。これにより冷媒は一点鎖線で示すように
流れ、絞り抵抗15が介在されるため第2熱交換
器8が凝縮器として作用し、第1熱交換器7が蒸
発器として作用する。第1熱交換器7を通つた冷
媒は、冷媒加熱器17、圧縮機18からバイパス
回路21を通り第2熱交換器8に至る。このと
き、送風機9,9を運転することにより、第1熱
交換器7を通つて冷却された風は室上方に向けて
吐出され、第2熱交換器8を通つて加熱された風
は室下方に向けて吐出される。また、上下に送風
路5,6を形成していることで冷却された空気と
加熱された空気が混合することがない。これによ
り、室内の温度分布は第4図に示すようにほぼ均
一化され、従来との温度差(図中の斜線部分)の
熱量が有効に使用され、居住空間における不快感
が無く、かつ省エネにもなる。一方、冷房時には
電磁弁16をONして開放し、バーナ23の燃焼
はOFF、かつ電磁弁をOFFして閉塞する。また、
風向板13,14のいずれも吐出方向が室上方に
なるように移動させる。これにより冷媒は実線で
示すように、圧縮機18、室外熱交換器19、絞
り抵抗部20、第2熱交換器8、電磁弁16、第
1熱交換器7、冷媒加熱器17を順次通つて圧縮
機18に戻る。このとき、室外熱交換器19は凝
縮器として作用し、第1および第2熱交換器7,
8は蒸発器として作用する。これに送風機9,9
を運転して送風することにより、空気は冷却され
て室上方に向けて吐出され室内に冷房される。
To explain the operation of the device configured as described above, first, during heating, when the room temperature is low such as in the early stage of heating, when performing heating (hereinafter referred to as heating and heating), this is detected by the temperature sensing element 25.
Detected by
3 is combusted, and the solenoid valve 22 is also turned on and opened. Further, the wind direction plates 13 and 14 are moved so that the discharge direction is downward. As a result, the refrigerant is heated by the refrigerant heater 17 and evaporated to become a high-temperature, high-pressure gas refrigerant, as shown by the broken line, and is sucked into and discharged from the compressor 18, and passes through the bypass circuit 21 to the second heat exchanger 8,
Further, it passes through the electromagnetic valve 16 to reach the first heat exchanger 7 and returns to the refrigerant heater 17. At this time, by heating the first and second heat exchangers 7 and 8 and operating the blowers 9 and 9, heat is exchanged and the room is heated and heated.
At this time, the indoor temperature distribution will be as shown in Figure 1, as in the past, but when the temperature in the upper part of the room rises to a predetermined temperature, the temperature detection element 25 detects this and utilizes the heat in the heated upper part of the room. The system then switches to heat utilization operation (hereinafter referred to as heat utilization operation), which heats the lower part of the room. That is, when the temperature in the upper part of the room reaches a predetermined temperature, the electromagnetic valve 16 is turned off and closed by the temperature detection element 25, the combustion of the burner 23 is stopped, and the wind direction plate 14 is moved while leaving only the side of the wind direction plate 14 as it is. Move it so that it is discharged upwards in the chamber. As a result, the refrigerant flows as shown by the dashed line, and since the throttling resistor 15 is interposed, the second heat exchanger 8 acts as a condenser, and the first heat exchanger 7 acts as an evaporator. The refrigerant that has passed through the first heat exchanger 7 passes through the refrigerant heater 17 and the compressor 18, passes through the bypass circuit 21, and reaches the second heat exchanger 8. At this time, by operating the blowers 9, 9, the air cooled through the first heat exchanger 7 is discharged upward into the room, and the air heated through the second heat exchanger 8 is discharged into the room. It is discharged downward. Furthermore, by forming the air passages 5 and 6 above and below, cooled air and heated air do not mix. As a result, the temperature distribution in the room is almost uniform as shown in Figure 4, and the amount of heat from the temperature difference (shaded area in the diagram) compared to the conventional one is used effectively, eliminating discomfort in the living space and saving energy. It also becomes. On the other hand, during cooling, the solenoid valve 16 is turned on and opened, combustion of the burner 23 is turned off, and the solenoid valve is turned off and closed. Also,
Both of the wind direction plates 13 and 14 are moved so that the discharge direction is upward in the room. As a result, the refrigerant passes through the compressor 18, the outdoor heat exchanger 19, the throttle resistor 20, the second heat exchanger 8, the solenoid valve 16, the first heat exchanger 7, and the refrigerant heater 17 in order, as shown by the solid line. Then return to the compressor 18. At this time, the outdoor heat exchanger 19 acts as a condenser, and the first and second heat exchangers 7,
8 acts as an evaporator. This blower 9,9
By operating and blowing air, the air is cooled and discharged upward into the room to cool the room.

なお、上記実施例においては送風機9,9を別
個に設けているが、例えば横流フアンの分割して
共通に使用し送風方向を変えてやれば1つの送風
機でも同様の効果がある。
In the above embodiment, the blowers 9, 9 are provided separately, but if, for example, a cross-flow fan is divided and used in common, and the direction of blowing air is changed, the same effect can be achieved even with a single blower.

この考案は以上説明したとおり、第1通風路と
第2通風路を設けた外筐と、上記第1通風路と上
記第2通風路のそれぞれに設けられた送風機と、
上記第1通風路内に設けられ冷凍サイクルの蒸発
器として作用する第1熱交換器と、上記第2通風
路内に設けられ冷凍サイクルの凝縮器として作用
する第2熱交換器とを備え、上記第1通風路を上
部に上記第2通風路を下部に配設し、上記第1通
風路の風を室内上方に吐出し、上記第2通風路の
風を室内下方に吐出するようにしたことにより、
暖房によつて加熱される室内上部の熱を有効に利
用して室内上部を冷却するとともに、室内下部を
加熱することができ、室内の温度分布を均一にす
ることができ、送風路が単純であり組立性も良
く、快適、かつ熱損失の少ない空気調和装置の室
内機が得られる効果がある。
As described above, this invention comprises an outer casing in which a first ventilation passage and a second ventilation passage are provided, a blower provided in each of the first ventilation passage and the second ventilation passage,
The present invention is provided with a first heat exchanger provided in the first ventilation passage and acting as an evaporator of a refrigeration cycle, and a second heat exchanger provided in the second ventilation passage and acting as a condenser of a refrigeration cycle, the first ventilation passage being disposed at an upper portion and the second ventilation passage being disposed at a lower portion, and the wind in the first ventilation passage being discharged upward inside the room and the wind in the second ventilation passage being discharged downward inside the room,
To provide an indoor unit for an air conditioner which can effectively utilize the heat from the upper part of the room heated by the heater to cool the upper part of the room while heating the lower part of the room, thereby making the temperature distribution in the room uniform, has a simple air duct, is easy to assemble, and is comfortable and has little heat loss.

【図面の簡単な説明】[Brief explanation of the drawing]

第1図は従来の室内温度を示す分布図、第2図
はこの考案の一実施例を示す冷媒回路図、第3図
は同じくその室内機を示す斜視図、第4図は同じ
くこの考案による室内温度を示す分布図である。 なお、図中1は空気調和装置、2は室内機、4
は外筐、5は第1通風路、6は第2通風路、7は
第1熱交換器、8は第2熱交換器、9は送風機、
15は絞り抵抗、16は電磁弁、25は温度検知
素子である。
Figure 1 is a conventional indoor temperature distribution diagram, Figure 2 is a refrigerant circuit diagram showing an embodiment of this invention, Figure 3 is a perspective view of the indoor unit, and Figure 4 is also based on this invention. It is a distribution map showing indoor temperature. In addition, in the figure, 1 is an air conditioner, 2 is an indoor unit, and 4 is an indoor unit.
is an outer casing, 5 is a first ventilation path, 6 is a second ventilation path, 7 is a first heat exchanger, 8 is a second heat exchanger, 9 is a blower,
15 is an aperture resistor, 16 is a solenoid valve, and 25 is a temperature detection element.

Claims (1)

【実用新案登録請求の範囲】[Scope of utility model registration request] 第1通風路と第2通風路を設けた外筐と、上記
第1通風路と上記第2通風路のそれぞれに設けら
れた送風機と、上記第1通風路内に設けられ冷凍
サイクルの蒸発器として作用する第1熱交換器
と、上記第2通風路内に設けられ冷凍サイクルの
凝縮器として作用する第2熱交換器とを備え、上
記第1通風路を上部に、また上記第2通風路を下
部にそれぞれ配設するとともに、上記第1通風路
の風を室内上方に吐出させ、上記第2通風路の風
を室内下方に吐出させるように構成し、かつ上記
第1熱交換器と第2熱交換器とを絞り抵抗とこれ
に並設させた電磁弁とを介して接続して、暖房運
転時においては、室内の上部に配設した温度検知
素子の検知出力で上記電磁弁を開閉制御させるよ
うにしたことを特徴とする空気調和装置の室内
機。
an outer casing provided with a first ventilation path and a second ventilation path; a blower provided in each of the first ventilation path and the second ventilation path; and an evaporator of a refrigeration cycle provided in the first ventilation path. a first heat exchanger acting as a refrigeration cycle; and a second heat exchanger provided in the second ventilation passage and acting as a condenser of the refrigeration cycle; the first heat exchanger and the first heat exchanger. The second heat exchanger is connected via a throttle resistor and a solenoid valve installed in parallel with the throttle resistor, and during heating operation, the solenoid valve is activated by the detection output of the temperature detection element installed at the top of the room. An indoor unit of an air conditioner characterized by controlling opening and closing.
JP878583U 1983-01-25 1983-01-25 Indoor unit of air conditioner Granted JPS59115226U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
JP878583U JPS59115226U (en) 1983-01-25 1983-01-25 Indoor unit of air conditioner

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP878583U JPS59115226U (en) 1983-01-25 1983-01-25 Indoor unit of air conditioner

Publications (2)

Publication Number Publication Date
JPS59115226U JPS59115226U (en) 1984-08-03
JPS634895Y2 true JPS634895Y2 (en) 1988-02-09

Family

ID=30140266

Family Applications (1)

Application Number Title Priority Date Filing Date
JP878583U Granted JPS59115226U (en) 1983-01-25 1983-01-25 Indoor unit of air conditioner

Country Status (1)

Country Link
JP (1) JPS59115226U (en)

Citations (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPS55105129A (en) * 1979-02-06 1980-08-12 Matsushita Electric Ind Co Ltd Air conditioner

Patent Citations (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPS55105129A (en) * 1979-02-06 1980-08-12 Matsushita Electric Ind Co Ltd Air conditioner

Also Published As

Publication number Publication date
JPS59115226U (en) 1984-08-03

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