Nothing Special   »   [go: up one dir, main page]

JPH0248773Y2 - - Google Patents

Info

Publication number
JPH0248773Y2
JPH0248773Y2 JP1984155073U JP15507384U JPH0248773Y2 JP H0248773 Y2 JPH0248773 Y2 JP H0248773Y2 JP 1984155073 U JP1984155073 U JP 1984155073U JP 15507384 U JP15507384 U JP 15507384U JP H0248773 Y2 JPH0248773 Y2 JP H0248773Y2
Authority
JP
Japan
Prior art keywords
heat exchanger
heat
partition wall
extending direction
air
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
JP1984155073U
Other languages
Japanese (ja)
Other versions
JPS6171837U (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 JP1984155073U priority Critical patent/JPH0248773Y2/ja
Publication of JPS6171837U publication Critical patent/JPS6171837U/ja
Application granted granted Critical
Publication of JPH0248773Y2 publication Critical patent/JPH0248773Y2/ja
Expired legal-status Critical Current

Links

Classifications

    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02BCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
    • Y02B30/00Energy efficient heating, ventilation or air conditioning [HVAC]
    • Y02B30/56Heat recovery units

Landscapes

  • Heat-Exchange Devices With Radiators And Conduit Assemblies (AREA)

Description

【考案の詳細な説明】 〈産業上の利用分野〉 本考案は室外空気を室外へ排出される室内空気
と熱交換させた後に室内に吸入するようにした空
調換気扇に配設される熱交換器に係り、特に積層
式熱交換器の改良に関する。
[Detailed description of the invention] <Industrial application field> The present invention is a heat exchanger installed in an air conditioning ventilation fan that exchanges heat between outdoor air and indoor air discharged outside and then sucks it into the room. In particular, the present invention relates to improvements in laminated heat exchangers.

〈従来の技術〉 この種の空調換気扇としては、例えば第6図に
示すように構成されたものがある。
<Prior Art> As this type of air conditioning ventilation fan, there is one constructed as shown in FIG. 6, for example.

即ち、室内と室外とを隔成する壁に取付けられ
る空調換気扇1は、本体ケース内に室内空気排出
通路2と室外空気吸入通路3とが交叉して配設さ
れ、該交叉部に室内空気と室外空気とを間接的に
熱交換せしめ除湿機能をも備えた熱交換器4が配
設される。
That is, an air conditioning ventilation fan 1 that is attached to a wall that separates indoors and outdoors is provided with an indoor air exhaust passage 2 and an outdoor air intake passage 3 that intersect with each other in the main body case. A heat exchanger 4 is provided that indirectly exchanges heat with outdoor air and also has a dehumidifying function.

この熱交換器4は積層式熱交換器で、例えば第
7図に示すように、所謂ダンボールプラスチツク
と称して市販されている熱交換子5、即ち一対の
仕切板5bの間の複数の仕切壁5aを平行に列設
して層状の通路空間をさらに細かく区切つて独立
した狭い通路に形成した熱交換子5を交互に多数
積層して、室内空気排出通路2と室外空気吸入通
路3を交互に形成している。
This heat exchanger 4 is a laminated heat exchanger, for example, as shown in FIG. Indoor air exhaust passages 2 and outdoor air intake passages 3 are alternately formed by stacking a large number of heat exchangers 5 which are arranged in parallel in parallel to further divide the layered passage space to form independent narrow passages. is forming.

尚、6,7は両通路2,3の室内側端部にそれ
ぞれ配設され、室内空気を図中点線矢印で示すよ
うに室外へ、室外空気を図中実線矢印で示すよう
に室内へ積極的に送風する排気フアン,吸気フア
ンである。
Note that 6 and 7 are installed at the indoor ends of both passages 2 and 3, respectively, to actively direct indoor air to the outside as shown by the dotted line arrow in the figure, and outdoor air to the room as shown by the solid line arrow in the figure. These are an exhaust fan and an intake fan that blow air.

かかる空調換気扇1は、室内空気を室外へ排出
して室内空気中の汚染物質例えばCO2,CO、粉
塵及び湿気等を除去すると同時に、室外空気を排
出される室内空気と熱交換させた後に室内に吐出
する空調換気運転を行う。
Such an air conditioning ventilation fan 1 discharges indoor air to the outdoors to remove pollutants such as CO 2 , CO, dust, moisture, etc. from the indoor air, and at the same time exchanges heat with the exhausted indoor air and then returns the indoor air to the indoor air. Perform air conditioning ventilation operation to discharge air.

〈考案が解決しようとする問題点〉 ところで、このような空調換気扇1は、特に寒
冷地域において、熱交換子5内部に発生する結露
が凍結し、熱交換効率の低下を招く恐れがある。
<Problems to be Solved by the Invention> By the way, in such an air conditioning ventilation fan 1, especially in a cold region, there is a risk that the condensation generated inside the heat exchanger 5 will freeze, leading to a decrease in heat exchange efficiency.

この故に、熱交換子5の配設方法は所謂十字流
式よりも対向流式とした方が良い。即ち、室内空
気排出通路2と室外空気吸入通路3とのそれぞれ
の空気流方向が十字流式の場合には、室内空気排
出通路2における室外空気吸入通路3の給気入口
側と出口側とで大きな温度差が生じるから、低温
となる入口側の結露水が凍結し易くなる一方、両
通路2,3の空気流方向が対向流式の場合には、
この種の室内空気排出通路2内での温度の片寄り
がないので、排気流通路全体として見たときに上
記十字流式のものに比べて結露水の凍結が起こり
にくいからである。
For this reason, it is better to arrange the heat exchanger 5 in a counter-flow type rather than in a so-called cross-flow type. That is, when the air flow direction of each of the indoor air exhaust passage 2 and the outdoor air intake passage 3 is a cross flow type, the air supply inlet side and the outlet side of the outdoor air intake passage 3 in the indoor air exhaust passage 2 are Since there is a large temperature difference, the condensed water on the inlet side, which is at a low temperature, is likely to freeze. On the other hand, if the air flow directions in both passages 2 and 3 are counter-flow type,
This is because there is no unevenness in temperature within the indoor air exhaust passage 2 of this type, so when looking at the exhaust flow passage as a whole, freezing of condensed water is less likely to occur compared to the above-mentioned cross-flow type.

しかしながら、上記第7図に示すような熱交換
子5を用い、これを複数積層することによつて形
成される従来の熱交換器4にあつて、隣接する熱
交換子5の仕切壁5aが交互に直交するように積
層した十字流式のものはあるが、仕切壁5aが平
行になるように積層した対向流式のものはない。
However, in the conventional heat exchanger 4 formed by stacking a plurality of heat exchangers 5 as shown in FIG. 7 above, the partition walls 5a of adjacent heat exchangers 5 are Although there is a cross-flow type in which the partitions are stacked alternately orthogonally, there is no counter-flow type in which the partition walls 5a are stacked in parallel.

本考案はこのような従来の実情に着目してなさ
れたもので、熱媒体の入口部と出口部の構造の工
夫により、上記従来のような市販されている熱交
換子を用いて対向流式に容易に製作した積層式熱
交換器を提供しようとするものである。
The present invention was developed by focusing on the conventional situation, and by devising the structure of the inlet and outlet of the heat medium, it is possible to create a counter-flow system using a commercially available heat exchanger like the conventional one described above. The purpose of the present invention is to provide a laminated heat exchanger that is easily manufactured.

〈問題点を解決するための手段〉 このため、本考案は、1対の仕切板間を複数の
平行な仕切壁で仕切つてなる複数の熱交換子夫々
の仕切壁の延びる方向の一端部を該方向に対して
斜めに切断して熱媒体の入口部として開口すると
共に、他端部を仕切壁の延びる方向に対して直角
に切断して熱媒体の出口部として開口し、各熱交
換子を前記仕切壁相互に平行になるようにかつ前
記入口部と出口部が交互に相反する方向に開口す
るように積層し、該積層体の前記入口部が臨む端
面であつて仕切壁の延びる方向に直交する一端面
側の両側位置から熱媒体を流入させ、前記出口部
が開口する端面であつて仕切壁の延びる方向に相
対向する両端面から熱媒体を流出させるように構
成した。
<Means for Solving the Problems> For this reason, the present invention has a plurality of heat exchangers in which a pair of partition plates is partitioned by a plurality of parallel partition walls. Each heat exchanger are stacked so that the partition walls are parallel to each other and the inlet portions and outlet portions open in opposite directions alternately, and the end face of the laminate facing the inlet portion is the direction in which the partition walls extend. The heat medium is allowed to flow in from both sides of one end face perpendicular to the partition wall, and the heat medium is allowed to flow out from both end faces that are opposite to each other in the extending direction of the partition wall and are the end face where the outlet portion opens.

〈作用〉 かかる構成においては、積層体の仕切壁の延び
る方向に直交する一端面側の両側位置から流入さ
れた熱媒体は入口部から熱交換子内に入つて流
れ、仕切壁の延びる方向に相対向する両端面から
出口部を経て流出する。
<Function> In such a configuration, the heat medium flowing from both sides of one end surface perpendicular to the extending direction of the partition wall of the laminate enters the heat exchanger from the inlet and flows in the extending direction of the partition wall. It flows out from the opposing end faces through the outlet section.

従つて、熱媒体が対向して流れ、相互に熱交換
される。
Therefore, the heat carriers flow oppositely and exchange heat with each other.

〈実施例〉 以下、本考案の実施例を第1図〜第5図に基づ
いて説明する。
<Example> Hereinafter, an example of the present invention will be described based on FIGS. 1 to 5.

図において、1対の仕切板10間を複数の平行
な仕切壁11で仕切つてなる複数の熱交換子12
(市販されているダンボールプラスチツク)夫々
の仕切壁11の延びる方向の一端部は該方向に対
して約45゜の角度でで斜めに切断されて熱媒体の
入口部13として開口されると共に、他端部は前
記仕切壁11の延びる方向と直角に切断されて熱
媒体の出口部14として開口される。そして、各
熱交換子12は、前記仕切壁11相互が平行にな
るようにかつ前記入口部13と出口部14に交互
に相反する方向に開口するように積層される。こ
の積層体15の前記入口部13が臨む端面であつ
て仕切壁11の延びる方向に直交する一端面側の
両側位置から熱媒体が流入され、前記出口部14
が開口する端面であつて仕切壁11の延びる方向
に相対向する両端面から熱媒体が流出される。
In the figure, a plurality of heat exchangers 12 are formed by partitioning a pair of partition plates 10 with a plurality of parallel partition walls 11.
(Commercially available cardboard plastic) One end in the extending direction of each partition wall 11 is cut diagonally at an angle of about 45 degrees with respect to the partition wall 11 to be opened as an inlet 13 for the heat medium, and the other The end portion is cut at right angles to the extending direction of the partition wall 11 and opened as an outlet portion 14 for the heat medium. The heat exchangers 12 are stacked so that the partition walls 11 are parallel to each other and the inlet portions 13 and outlet portions 14 are opened in alternate directions. The heat medium is introduced from both sides of the end face of the laminate 15 facing the inlet part 13 and perpendicular to the extending direction of the partition wall 11, and the heat medium flows into the outlet part 14.
The heating medium flows out from both end faces which are open and are opposite to each other in the direction in which the partition wall 11 extends.

ここで、上記熱交換子12の出口部14として
開口された端部の上側には、熱交換子12と略同
じ高さの画壁16が熱交換子12の積層時に仕切
壁として機能するように立設されている(第3図
及び第4図参照)。又、最上部に位置する熱交換
子12には、この画壁16は設けられていない
(第2図参照)。
Here, above the end of the heat exchanger 12 which is opened as the outlet part 14, a partition wall 16 having approximately the same height as the heat exchanger 12 is provided so as to function as a partition wall when the heat exchangers 12 are stacked. (See Figures 3 and 4). Further, the heat exchanger 12 located at the top is not provided with this partition wall 16 (see FIG. 2).

積層された各熱交換子12は例えば接着剤等で
接合され、熱交換子ユニツトとして熱交換器本体
内に配設される。
The stacked heat exchangers 12 are bonded together, for example, with an adhesive, and are disposed within the heat exchanger body as a heat exchanger unit.

かかる構成の熱交換器においては、熱交換子ユ
ニツトの仕切壁11の延びる方向に直交する一端
面側の両側位置から夫々流入された熱媒体として
の室外空気(第5図実線で示す)と室内空気(第
5図点線で示す)は入口部13から積層位置され
る熱交換子12内に入つて流れ、仕切壁11の延
びる方向に相対向する両端面から出口部14を経
て流出する。
In a heat exchanger having such a configuration, outdoor air (shown by solid lines in FIG. 5) as a heat medium and indoor air are respectively introduced from both sides of one end surface perpendicular to the extending direction of the partition wall 11 of the heat exchanger unit. Air (indicated by dotted lines in FIG. 5) enters and flows into the stacked heat exchangers 12 from the inlet portion 13, and flows out through the outlet portion 14 from both end faces facing each other in the extending direction of the partition wall 11.

従つて、熱媒体としての室外空気と室内空気と
が対向して流れ、相互に熱交換される。
Therefore, the outdoor air and the indoor air as heat carriers flow oppositely and exchange heat with each other.

次に作用を説明する。 Next, the action will be explained.

いま、第6図に示すような吸気フアン7、排気
フアン6をオン状態に維持し、室外空気吸入通路
3及び室内空気排出通路2内にそれぞれ空気流を
生じせしめて換気運転を続行すると、暖房運転時
には新鮮な室外空気は室内空気と対向流式の熱交
換器において熱交換して適度に温められた室内に
吐出される。
Now, if the intake fan 7 and the exhaust fan 6 are kept in the ON state as shown in FIG. 6, and air flows are generated in the outdoor air intake passage 3 and the indoor air exhaust passage 2, respectively, and the ventilation operation is continued, the heating will start. During operation, fresh outdoor air exchanges heat with indoor air in a counterflow type heat exchanger and is discharged into the room where it is appropriately heated.

この熱交換時、高温多湿な室内空気は、熱交換
子12内の室内空気排出通路2における排気の入
口側から出口側まで略平行に流れる比較的低温な
室外空気と熱交換しつつ排出される。即ち、室内
空気は、排気通路2内に仕切壁11により隔成さ
れる独立した狭い通路のいずれの通路を流通する
空気も全て略同じように熱交換しつつ排出され
る。
During this heat exchange, the high-temperature and humid indoor air is discharged while exchanging heat with the relatively low-temperature outdoor air that flows approximately parallel from the exhaust inlet side to the outlet side of the indoor air exhaust passage 2 in the heat exchanger 12. . That is, the indoor air is discharged while all the air flowing through any of the independent narrow passages separated by the partition wall 11 in the exhaust passage 2 undergoes heat exchange in substantially the same way.

このため、十字流式の熱交換器4のように、室
内空気排出通路2内の両端に各別に形成される独
立した通路のうち、室外空気吸入通路3の給気入
口側に位置する一端側の通路の方が他端側の通路
より低温となることがなく、いずれの独立した通
路とも略同じ状態で熱交換され、全ての独立した
通路それぞれが平均的な温度分布となるので、結
露水の凍結が起こりにくく、寒冷地での使用に有
利である。
For this reason, like the cross-flow type heat exchanger 4, among the independent passages formed separately at both ends of the indoor air exhaust passage 2, one end located on the air supply inlet side of the outdoor air intake passage 3 The passage at the end does not become colder than the passage at the other end, and heat is exchanged under almost the same conditions as any independent passage, and all the independent passages have an average temperature distribution, so condensation water does not It is difficult to freeze, making it advantageous for use in cold regions.

このように、市販の熱交換子12の一端部を所
定角度で切断しかつ他端部に画壁16を立設する
だけで、簡単な奇数層と偶数層との空気を分けて
両層間で熱交換する対向流式の熱交換子ユニツト
を経済的にも有利に製作でき、結露水の凍結しに
くい熱交換器を提供できる。
In this way, by simply cutting one end of the commercially available heat exchanger 12 at a predetermined angle and erecting the partition wall 16 at the other end, it is possible to easily separate the air between the odd and even layers. A counterflow heat exchanger unit for exchanging heat can be manufactured economically, and a heat exchanger in which condensed water is less likely to freeze can be provided.

しかも、熱交換子12の段数を変えることによ
つて、種々の換気風量に対応できるとともに熱交
換効率の増減も容易に調整できると同時に、各段
とも同形状の熱交換子12を使用しているので、
積層の方向を変えるだけで吸・排気口の向きを変
更することも容易にできる。
Moreover, by changing the number of stages of the heat exchanger 12, it is possible to correspond to various ventilation airflow rates and easily adjust the increase or decrease in heat exchange efficiency. Because there are
The direction of the intake and exhaust ports can be easily changed by simply changing the direction of the stack.

更に、かかる構成によると、熱交換子12夫々
の仕切壁11の延びる方向の一端部を該方向に対
して約45゜の角度で斜めに切断して入口部13と
して開口するようにしたから、流通する空気を均
一に分配できると共に、材料を有効に使用できる
という利点がある。尚、切断角度は上記の約45゜
の角度に限るものではない。又、切断面も完全な
直線状でなくとも良い。
Furthermore, according to this configuration, one end of each of the heat exchangers 12 in the direction in which the partition wall 11 extends is cut diagonally at an angle of about 45 degrees to the direction to open as the inlet part 13. This has the advantage that circulating air can be uniformly distributed and materials can be used effectively. Note that the cutting angle is not limited to the above-mentioned approximately 45° angle. Furthermore, the cut surface does not have to be completely straight.

また、隣接する熱交換子12同士を接着剤等で
接合する構成としたが、これに限らず、所定寸法
のケースに嵌め込むように積層して収納する構成
としても良い。
Further, although the adjacent heat exchangers 12 are bonded to each other with an adhesive or the like, the present invention is not limited to this, and the heat exchangers 12 may be stacked and stored so as to be fitted into a case of a predetermined size.

〈考案の効果〉 以上説明したように本考案によれば、市販され
ている熱交換子を使用して、容易かつ安価に対向
流式の積層式熱交換器を形成できるので、結露水
の凍結しにくい熱交換器を提供できる。特に、熱
交換子夫々の仕切壁の延びる方向の一端部を該方
向に対して斜めに切断して入口部として開口する
ようにしたから、流通する空気を均一に分配でき
ると共に、材料を有効に使用できるという利点が
ある。
<Effects of the invention> As explained above, according to the invention, a counterflow stacked heat exchanger can be easily and inexpensively formed using a commercially available heat exchanger, thereby preventing freezing of condensed water. We can provide heat exchangers that are difficult to use. In particular, one end of the extending direction of the partition wall of each heat exchanger is cut diagonally with respect to the direction to open as an inlet, so that the circulating air can be uniformly distributed and the material can be used effectively. It has the advantage of being usable.

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

第1図は本考案にかかる熱交換子ユニツトの一
実施例を示す斜視図、第2図〜第4図はそれぞれ
第1図の要部である熱交換子の平面図、第5図は
同上実施例における空気流の説明図、第6図は空
調熱交換器の一例を示す構成図、第7図は熱交換
子の従来例を示す斜視図である。 10…仕切板、11…仕切壁、12…熱交換
子、13…入口部、14…出口部、15…積層
体。
Fig. 1 is a perspective view showing one embodiment of a heat exchanger unit according to the present invention, Figs. 2 to 4 are plan views of the heat exchanger which are the main parts of Fig. 1, and Fig. 5 is the same as above. An explanatory diagram of air flow in the embodiment, FIG. 6 is a configuration diagram showing an example of an air conditioning heat exchanger, and FIG. 7 is a perspective view showing a conventional example of a heat exchanger. DESCRIPTION OF SYMBOLS 10... Partition plate, 11... Partition wall, 12... Heat exchanger, 13... Inlet part, 14... Outlet part, 15... Laminated body.

Claims (1)

【実用新案登録請求の範囲】[Scope of utility model registration request] 1対の仕切板間を複数の平行な仕切壁で仕切つ
てなる複数の熱交換子夫々の仕切壁の延びる方向
の一端部を該方向に対して斜めに切断して熱媒体
の入口部として開口すると共に、他端部を仕切壁
の延びる方向に対して直角に切断して熱媒体の出
口部として開口し、各熱交換子を前記仕切壁相互
が平行になるようにかつ前記入口部と出口部が交
互に相反する方向に開口するように積層し、該積
層体の前記入口部が臨む端面であつて仕切壁の延
びる方向に直交する一端面側の両側位置から熱媒
体を流入させ、前記出口部が開口する端面であつ
て仕切壁の延びる方向に相対向する両端面から熱
媒体を流出させるように構成したことを特徴とす
る空調換気扇の熱交換器。
A pair of partition plates are separated by a plurality of parallel partition walls, and one end of each of the partition walls in the extending direction is cut obliquely to the direction to open an opening as an inlet for the heat medium. At the same time, the other end is cut at right angles to the extending direction of the partition wall to open as an outlet section for the heat medium, and each heat exchanger is arranged so that the partition walls are parallel to each other and the inlet section and the outlet section are opened. The heating medium is laminated so that the sections are alternately opened in opposite directions, and the heating medium is introduced from both sides of the end surface facing the inlet section of the laminate, which is perpendicular to the extending direction of the partition wall. 1. A heat exchanger for an air conditioning ventilation fan, characterized in that the heat exchanger is configured to cause a heat medium to flow out from both end faces facing each other in the extending direction of a partition wall, the end faces having an opening.
JP1984155073U 1984-10-16 1984-10-16 Expired JPH0248773Y2 (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
JP1984155073U JPH0248773Y2 (en) 1984-10-16 1984-10-16

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP1984155073U JPH0248773Y2 (en) 1984-10-16 1984-10-16

Publications (2)

Publication Number Publication Date
JPS6171837U JPS6171837U (en) 1986-05-16
JPH0248773Y2 true JPH0248773Y2 (en) 1990-12-20

Family

ID=30713070

Family Applications (1)

Application Number Title Priority Date Filing Date
JP1984155073U Expired JPH0248773Y2 (en) 1984-10-16 1984-10-16

Country Status (1)

Country Link
JP (1) JPH0248773Y2 (en)

Families Citing this family (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20160252269A1 (en) * 2013-10-02 2016-09-01 Toray Industries, Inc. Heat exchange element and heat exchanger

Citations (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPS5855223B2 (en) * 1978-09-26 1983-12-08 三菱マテリアル株式会社 Heat-resistant and wear-resistant Cr↓-Fe↓-Ni↓-Co-based alloy

Family Cites Families (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPS5855223U (en) * 1981-10-09 1983-04-14 株式会社東芝 air conditioning ventilation fan

Patent Citations (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPS5855223B2 (en) * 1978-09-26 1983-12-08 三菱マテリアル株式会社 Heat-resistant and wear-resistant Cr↓-Fe↓-Ni↓-Co-based alloy

Also Published As

Publication number Publication date
JPS6171837U (en) 1986-05-16

Similar Documents

Publication Publication Date Title
JP3577863B2 (en) Counter-flow heat exchanger
JP4409914B2 (en) Air conditioner air conditioning system
US20090126913A1 (en) Vertical counterflow evaporative cooler
US6845629B1 (en) Vertical counterflow evaporative cooler
US6282915B1 (en) Evaporative cooler
JPH0248773Y2 (en)
JP3045146B2 (en) Dehumidifier
JP6078602B1 (en) Indirect vaporization air conditioner and indirect vaporization air conditioning method
JP2000042344A (en) Dehumidifying device
JP2575861B2 (en) Air conditioning ventilation fan
EP1453623A1 (en) Patterned sheets for making heat exchangers and other structures
JP3156162U (en) Total heat exchange element
JPS6135867Y2 (en)
JPS6133425Y2 (en)
JPS6347791Y2 (en)
JP4021048B2 (en) Heat exchange element
JPH04371794A (en) Lamination type heat exchanger
JP2630552B2 (en) Crossflow cooling tower
JPS5934276B2 (en) heat exchange equipment
JPS6124995A (en) Heat exchanger
KR20170124794A (en) Hybrid economizer heat exchanger
JPH0129469Y2 (en)
KR200201508Y1 (en) Heat exchanger by ventilation facilities
JPH0412374Y2 (en)
JPS6234143Y2 (en)