TW201518660A - Dehumidifier device - Google Patents

Abstract

This invention is a dehumidifier device which comprises of an outer shell, a fan, a heat pump device, and a heat exchanger. The outer shell equips with an air inlet and an air outlet. The air inlet is disposed at the upper portion of the outer peripheral wall of the outer shell. The heat pump device is constructed with a compressor, a heat sink, an expansion part, and a heat absorber. Arranged in a specific order, the heat sink, the expansion part, and followed by the heat absorber, are located at the downstream of the compressor along a direction of the flow of a cooling agent of the heat pump device. The heat sink is opposite to the heat absorber. The heat exchanger is installed between the heat sink and the heat absorber. The heat absorber is formed by a first region and a second region; furthermore, the second region is located at a further downstream of the flow direction of the cooling agent. The second region is protruding out between the air inlet and the heat exchanger.

Description

除濕裝置 Dehumidifier 發明領域 Field of invention

本發明是有關於一種利用冷凍循環進行冷卻除濕之除濕裝置。 The present invention relates to a dehumidification apparatus for performing cooling and dehumidification using a refrigeration cycle.

發明背景 Background of the invention

習知之除濕裝置已知的是裝設有如日本特開2005-214533號公報所揭示之熱交換手段的除濕裝置。如此之習知除濕裝置的構成如以下所述。 A conventional dehumidifying apparatus is known as a dehumidifying apparatus equipped with a heat exchange means as disclosed in Japanese Laid-Open Patent Publication No. 2005-214533. The composition of such a conventional dehumidifying apparatus is as follows.

在除濕裝置本體，壓縮機、散熱器(冷凝器)、膨脹部(限制裝置)、吸熱器(蒸發器)依序藉由冷媒配管而連接且形成了冷凍循環。接著在吸熱器中，為除濕對象之空氣進行冷卻除濕。在由吸熱器往散熱器之風路中，配置了直交流型之熱交換部。 In the main body of the dehumidifier, a compressor, a radiator (condenser), an expansion unit (restriction device), and a heat absorber (evaporator) are sequentially connected by a refrigerant pipe to form a refrigeration cycle. Then, in the heat absorber, the air of the dehumidifying object is cooled and dehumidified. A direct exchange type heat exchange unit is disposed in the air passage from the heat absorber to the radiator.

上述構成中，從流入口流入之空氣進入熱交換部、且與已經被吸熱器冷卻除濕之空氣熱交換而預冷、從流出口流出。接著，藉由風路，空氣的流向改變270°、通過吸熱器而進行冷卻除濕。然後、經冷卻除濕之空氣由熱交換部之流入口再次進入熱交換部，並被從流入口流入之空氣加熱、從流出口流出而在散熱器中進一步加熱、藉由送風 部送風到除濕裝置外。 In the above configuration, the air that has flowed in from the inflow enters the heat exchange unit, and is preheated by heat exchange with the air that has been cooled and dehumidified by the heat absorber, and flows out from the outflow port. Then, by the air passage, the flow direction of the air is changed by 270°, and cooling and dehumidification are performed by the heat absorber. Then, the air cooled and dehumidified enters the heat exchange portion again from the inlet of the heat exchange portion, and is heated by the air flowing in from the inflow port, flows out from the outflow port, and is further heated in the radiator, and is blown by the air. The part sends air to the dehumidifier.

發明概要 Summary of invention

一般而言，具有冷凍循環之除濕裝置中，由於壓縮機中冷媒被壓縮、往壓縮機流入之冷媒必須充分的氣化。因此，在流入壓縮機之前之吸熱器中，冷媒必須充分地氣化。 In general, in a dehumidification apparatus having a refrigeration cycle, the refrigerant in the compressor is compressed and the refrigerant flowing into the compressor must be sufficiently vaporized. Therefore, in the heat absorber before flowing into the compressor, the refrigerant must be sufficiently vaporized.

吸熱器中，混和有液體之冷媒、氣體之冷媒。因此習知之除濕裝置中，由於冷媒在吸熱器中充分氣化，而必須擴大不會有助於吸熱器之冷媒下游側之除濕之區域。 In the heat absorber, a refrigerant of a liquid and a refrigerant of a gas are mixed. Therefore, in the conventional dehumidifying apparatus, since the refrigerant is sufficiently vaporized in the heat absorber, it is necessary to enlarge the dehumidifying region which does not contribute to the downstream side of the refrigerant of the heat absorber.

因此習知之除濕裝置中，具有吸熱器變大而難以除濕裝置小型化的課題。 Therefore, in the conventional dehumidifier, there is a problem that the heat absorber becomes large and it is difficult to reduce the size of the dehumidifier.

是故本發明之目的在於提供一種可維持除濕性能並且更為小型化的除濕裝置。 It is therefore an object of the present invention to provide a dehumidifying apparatus which can maintain dehumidification performance and is more compact.

因此，本發明之除濕裝置具有本體外殼、送風機、熱泵裝置、及熱交換器。其中，送風機、熱泵裝置、及熱交換器設置於本體外殼內。本體外殼具有吸氣口與吹出口。吸氣口設置於本體外殼之外周壁上部。而且送風機由吸氣口吸入空氣而從吹出口吹出空氣。熱泵裝置由壓縮機、散熱器、膨脹部、及吸熱器構成。散熱器、膨脹部、及吸熱器在熱泵裝置之冷媒流動之方向上依序設置於壓縮機之下游。散熱器與吸熱器對向。在散熱器與吸熱器之間，設有熱交換器。吸熱器由第1區域與第2區域所構成，並且在冷媒流動之方向上，第2區域位於比第1區域更下游側。而且 第2區域突出於吸氣口與熱交換器之間。 Therefore, the dehumidifying apparatus of the present invention has a body casing, a blower, a heat pump device, and a heat exchanger. Wherein, the blower, the heat pump device, and the heat exchanger are disposed in the body casing. The body casing has an air inlet and a blow port. The suction port is disposed at an upper portion of the peripheral wall outside the body casing. Further, the blower draws in air from the intake port and blows air from the blow port. The heat pump device is composed of a compressor, a radiator, an expansion portion, and a heat absorber. The radiator, the expansion portion, and the heat absorber are sequentially disposed downstream of the compressor in the direction in which the refrigerant of the heat pump device flows. The heat sink is opposite the heat sink. A heat exchanger is provided between the radiator and the heat absorber. The heat absorber is composed of the first region and the second region, and the second region is located on the downstream side of the first region in the direction in which the refrigerant flows. and The second area protrudes between the suction port and the heat exchanger.

該除濕裝置藉由從吸氣口吸入到本體外殼內之空氣而暖化吸熱器之第2區域，並且促進在吸熱器中混和液體與氣體之冷媒的氣化。因此，得到一即使吸熱器不增大，亦可在吸熱器中充分地進行冷媒之氣化以冷媒氣化，維持除濕性能並且小型化之除濕裝置。 The dehumidification device warms the second region of the heat absorber by sucking air from the intake port into the body casing, and promotes vaporization of the refrigerant that mixes the liquid and the gas in the heat absorber. Therefore, it is possible to obtain a dehumidifying apparatus which can sufficiently vaporize the refrigerant in the heat absorber to vaporize the refrigerant, maintain the dehumidification performance, and miniaturize even if the heat absorber does not increase.

1‧‧‧本體外殼 1‧‧‧ body shell

1a‧‧‧外周壁上部 1a‧‧‧Upper peripheral wall

2‧‧‧吸氣口 2‧‧‧ suction port

2a‧‧‧吸氣口上端 2a‧‧‧ upper end of suction port

2b‧‧‧吸氣口下端 2b‧‧‧At the lower end of the suction port

3‧‧‧吹出口 3‧‧‧Blowing out

4‧‧‧儲水槽 4‧‧‧Water storage tank

5‧‧‧散熱器 5‧‧‧heatsink

5a‧‧‧散熱器上端部 5a‧‧‧ Upper end of the radiator

5b‧‧‧散熱器下端部 5b‧‧‧lower end of the radiator

5c‧‧‧散熱器上部 5c‧‧‧ Upper part of the radiator

5d‧‧‧散熱器下部 5d‧‧‧lower radiator

5e‧‧‧散熱器上部長度 5e‧‧‧ Upper length of the radiator

5f‧‧‧散熱器下部長度 5f‧‧‧lower radiator length

6‧‧‧壓縮機 6‧‧‧Compressor

7‧‧‧排水盤 7‧‧‧Drainage tray

8‧‧‧送風機 8‧‧‧Air blower

8a‧‧‧罩殼部 8a‧‧‧Shell Department

8b‧‧‧馬達部 8b‧‧‧Motor Department

8c‧‧‧葉片部 8c‧‧‧blade department

9a‧‧‧吸入口 9a‧‧‧Inhalation

9b‧‧‧吐出口 9b‧‧‧Exporting

10‧‧‧除濕裝置 10‧‧‧Dehumidification device

11‧‧‧熱交換器 11‧‧‧ heat exchanger

11a‧‧‧第1傳熱板 11a‧‧‧1st heat transfer plate

11b‧‧‧第2傳熱板 11b‧‧‧2nd heat transfer plate

11c‧‧‧第1熱交換風路 11c‧‧‧1st heat exchange airway

11d‧‧‧第2熱交換風路 11d‧‧‧2nd heat exchange airway

11e‧‧‧熱交換器上端部 11e‧‧‧ Upper end of heat exchanger

12‧‧‧膨脹部 12‧‧‧Expansion

13‧‧‧吸熱器 13‧‧‧heat absorber

13a‧‧‧第1區域 13a‧‧‧1st area

13b‧‧‧第2區域 13b‧‧‧2nd area

13c‧‧‧第2區域通風截面 13c‧‧‧2nd area ventilation section

13d‧‧‧第1區域通風截面 13d‧‧‧1st area ventilation section

14‧‧‧除濕風路 14‧‧‧Dehumidification Wind Road

15‧‧‧分流風路 15‧‧‧Diversion wind path

16‧‧‧空間部 16‧‧‧ Space Department

17‧‧‧冷媒配管 17‧‧‧Refrigerant piping

21‧‧‧冷媒流動之方向 21‧‧‧The direction of refrigerant flow

22‧‧‧水滴 22‧‧‧ water droplets

30‧‧‧熱泵裝置 30‧‧‧ heat pump unit

A‧‧‧平面 A‧‧‧ plane

B‧‧‧方向 B‧‧‧ directions

C‧‧‧箭頭記號 C‧‧‧arrow mark

D‧‧‧箭頭記號 D‧‧‧ arrow mark

圖1是本發明之實施型態之除濕裝置的立體圖。 Fig. 1 is a perspective view of a dehumidifying apparatus according to an embodiment of the present invention.

圖2是將圖1之除濕裝置從平面A切斷並且由B方向看的概略截面圖。 Fig. 2 is a schematic cross-sectional view showing the dehumidifying apparatus of Fig. 1 cut from a plane A and viewed in the direction B.

圖3是用以說明本發明之實施型態之除濕裝置之熱交換器的圖。 Fig. 3 is a view for explaining a heat exchanger of a dehumidifying apparatus according to an embodiment of the present invention.

圖4是用以說明同除濕裝置之吸熱器的圖。 Fig. 4 is a view for explaining a heat absorber of the same dehumidifying apparatus.

較佳實施例之詳細說明 Detailed description of the preferred embodiment

以下，參照圖式並說明本發明之實施型態。 Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(實施型態) (implementation type)

圖1是本發明之實施型態之除濕裝置的立體圖。如圖1所示，除濕裝置10之本體外殼1為箱形、具有吸氣口2與吹出口3。吸氣口2設置於本體外殼1之外周壁上部1a、吹出口3設置於與吸氣口2相同或者比吸氣口2更高的位置。 Fig. 1 is a perspective view of a dehumidifying apparatus according to an embodiment of the present invention. As shown in FIG. 1, the main body casing 1 of the dehumidifying apparatus 10 has a box shape and has an intake port 2 and a blow port 3. The intake port 2 is provided on the outer peripheral wall upper portion 1a of the main body casing 1, and the air outlet 3 is provided at the same position as the intake port 2 or at a position higher than the intake port 2.

其中，所謂本體外殼1之外周壁上部1a，是在設置有除濕裝置10之狀態下，比本體外殼1之中心還高的位置。又，在除濕裝置10之下部設有用以儲存因除濕而產生之水 的儲水槽4。 Here, the outer peripheral wall upper portion 1a of the main body casing 1 is at a position higher than the center of the main body casing 1 in a state where the dehumidifying device 10 is provided. Further, a lower portion of the dehumidifying device 10 is provided for storing water generated by dehumidification Storage tank 4.

圖2是將圖1之除濕裝置由平面A切斷且從B方向看的截面圖。圖2所示之除濕裝置10具有：本體外殼1、送風機8、熱泵裝置30、熱交換器(顯熱交換器)11。本體外殼1內設有送風機8、熱泵裝置30、及熱交換器11。 Fig. 2 is a cross-sectional view showing the dehumidifying apparatus of Fig. 1 cut from a plane A and viewed from a B direction. The dehumidifying apparatus 10 shown in Fig. 2 has a main body casing 1, a blower 8, a heat pump device 30, and a heat exchanger (sensible heat exchanger) 11. A blower 8, a heat pump device 30, and a heat exchanger 11 are disposed in the main body casing 1.

熱泵裝置30是由壓縮機(compressor)6、依序設置在冷媒流動之方向21之壓縮機6之下游的散熱器(冷凝器)5、膨脹部(毛細管)12、及吸熱器(蒸發器)13所構成。熱泵裝置30將該等藉由冷媒配管17連接、並且形成了冷凍循環。而且在吸熱器13中，為除濕對象之空氣進行冷卻除濕。 The heat pump device 30 is a heat sink (condenser) 5, an expansion portion (capillary) 12, and a heat absorber (evaporator) which are disposed downstream of the compressor 6 in the direction 21 in which the refrigerant flows in a compressor 6. 13 constitutes. The heat pump device 30 connects the refrigerant pipes 17 and forms a refrigeration cycle. Further, in the heat absorber 13, the air to be dehumidified is cooled and dehumidified.

送風機8由渦形之罩殼部8a、固定於罩殼部8a之馬達部8b、藉由馬達部8b旋轉之葉片部8c形成。送風機8由吸氣口2吸入空氣並從吹出口3吹出空氣。 The blower 8 is formed by a scroll cover portion 8a, a motor portion 8b fixed to the cover portion 8a, and a blade portion 8c that is rotated by the motor portion 8b. The blower 8 takes in air from the intake port 2 and blows air from the blower port 3.

罩殼部8a具有吸入口9a與吐出口9b。吸入口9a與吸熱器13、熱交換器11、及散熱器5對向。即吸熱器13、熱交換器11、散熱器5、及吸入口9a是配置在一直線上。 The casing portion 8a has a suction port 9a and a discharge port 9b. The suction port 9a faces the heat absorber 13, the heat exchanger 11, and the radiator 5. That is, the heat absorber 13, the heat exchanger 11, the radiator 5, and the suction port 9a are arranged on a straight line.

又，本體外殼1內設有儲水槽4、排水盤7。排水盤7設置於吸熱器13之下方、盛接因通過吸熱器13之空氣進行除濕而產生的水、並將水送到儲水槽4。散熱器5與吸熱器13是對向、並且在散熱器5與吸熱器13之間設有熱交換器11。 Further, the main body casing 1 is provided with a water storage tank 4 and a drain pan 7. The drain pan 7 is disposed below the heat absorber 13, and receives water generated by dehumidification by the air passing through the heat absorber 13, and sends the water to the water storage tank 4. The radiator 5 is opposed to the heat absorber 13, and a heat exchanger 11 is provided between the radiator 5 and the heat absorber 13.

圖3是說明本發明之實施型態之除濕裝置之熱交換器的圖。如圖3所示，熱交換器11是例如直交流型之顯熱 交換器。熱交換器11是由樹脂或金屬等構成之第1傳熱板11a與第2傳熱板11b交互地積層而形成。 Fig. 3 is a view for explaining a heat exchanger of a dehumidifying apparatus according to an embodiment of the present invention. As shown in FIG. 3, the heat exchanger 11 is, for example, a sensible heat of a direct current type. Switch. The heat exchanger 11 is formed by laminating a first heat transfer plate 11a made of resin, metal or the like and a second heat transfer plate 11b.

熱交換器11具有彼此進行熱交換之第1熱交換風路11c與第2熱交換風路11d。本發明之實施型態中，第1熱交換風路11c為垂直方向之風路、第2熱交換風路11d為水平方向之風路。 The heat exchanger 11 has a first heat exchange air passage 11c and a second heat exchange air passage 11d that exchange heat with each other. In the embodiment of the present invention, the first heat exchange air passage 11c is an air passage in the vertical direction, and the second heat exchange air passage 11d is an air passage in the horizontal direction.

如圖2之箭頭記號C所示，藉由送風機8從吸氣口2吸入之空氣往熱交換器11之上面之第1熱交換風路11c的流入口流入。而且往第1熱交換風路11c之流入口流入之空氣與已經被吸熱器13冷卻除濕之空氣進行熱交換而預冷、並從熱交換器11之下面之第1熱交換風路11c的流出口流出。接著從第1熱交換風路11c之流出口流出之空氣通過吸熱器13而進行冷卻除濕。 As indicated by an arrow C in Fig. 2, the air sucked from the intake port 2 by the blower 8 flows into the inflow port of the first heat exchange air passage 11c on the upper surface of the heat exchanger 11. Further, the air that has flowed into the inflow port of the first heat exchange air passage 11c exchanges heat with the air that has been cooled and dehumidified by the heat absorber 13 to be precooled, and flows from the first heat exchange air passage 11c below the heat exchanger 11. The exit is out. Then, the air that has flowed out from the outlet of the first heat exchange air passage 11c passes through the heat absorber 13 to be cooled and dehumidified.

被吸熱器13冷卻除濕之空氣從第2熱交換風路11d之流入口再次進入熱交換器11、並藉由從第1熱交換風路11c之流入口流入之空氣進行加熱。接著，從第2熱交換風路11d之流出口流出之空氣在散熱器5中進一步加熱、並且藉由送風機8送風到除濕裝置10外。 The air cooled and dehumidified by the heat absorber 13 enters the heat exchanger 11 again from the inlet of the second heat exchange air passage 11d, and is heated by the air flowing in from the inlet of the first heat exchange air passage 11c. Then, the air that has flowed out from the outlet of the second heat exchange air passage 11d is further heated in the radiator 5, and is blown to the outside of the dehumidifying device 10 by the blower 8.

圖4是用以說明本發明之實施型態之除濕裝置之吸熱器的圖。如圖4所示，吸熱器13由第1區域13a與第2區域13b構成。冷媒流動之方向21中，第2區域13b是位於較第1區域13a下游側。第1區域13a是吸熱器13之結露區域。第1區域13a中，空氣進行冷卻除濕時會產生水滴22、水滴22經由圖2所示之排水盤7送到儲水槽4。 Fig. 4 is a view for explaining a heat absorber of a dehumidifying apparatus according to an embodiment of the present invention. As shown in FIG. 4, the heat absorber 13 is composed of a first region 13a and a second region 13b. In the direction 21 in which the refrigerant flows, the second region 13b is located on the downstream side of the first region 13a. The first region 13a is a condensation region of the heat absorber 13. In the first region 13a, when the air is cooled and dehumidified, water droplets 22 and water droplets 22 are generated and sent to the water storage tank 4 via the drain pan 7 shown in Fig. 2 .

再者，由於第2區域13b位於在冷媒流動之方向21上比第1區域13a下游側之位置、因此比結露區域之第1區域13a更難結露。換言之第2區域13b比第1區域13a更難除濕。 Further, since the second region 13b is located at a position on the downstream side of the first region 13a in the direction 21 in which the refrigerant flows, it is more difficult to dew condensation than the first region 13a of the dew condensation region. In other words, the second region 13b is more difficult to dehumidify than the first region 13a.

本實施型態之除濕裝置10之特徴是，如圖2所示，吸熱器13之第2區域13b突出設置於吸氣口2與熱交換器11之間之風路內。 In the dehumidifying apparatus 10 of the present embodiment, as shown in FIG. 2, the second region 13b of the heat absorber 13 is protruded from the air passage between the intake port 2 and the heat exchanger 11.

結果藉由從吸氣口2吸入至本體外殼1內之空氣，暖化了吸熱器13之第2區域13b，促進第2區域13b冷媒的氣化而可確保充分的冷媒過熱度。因此，為了冷媒之氣化，即使沒有加大吸熱器13，亦可在吸熱器13充分地進行冷媒之氣化。接著，已經充分氣化之冷媒流入位於下游之壓縮機6，並且再次壓縮而繼續冷凍循環。換言之，從吸氣口2吸入之空氣的一部分在到達散熱器5之前會通過第2區域13b而預冷，因此提高散熱器5之冷卻效率，並且更為降低消耗電力。 As a result, the second region 13b of the heat absorber 13 is warmed by the air sucked into the inside of the main body casing 1 from the intake port 2, and the vaporization of the refrigerant in the second region 13b is promoted, thereby ensuring sufficient superheat of the refrigerant. Therefore, in order to vaporize the refrigerant, even if the heat absorber 13 is not enlarged, the refrigerant can be sufficiently vaporized in the heat absorber 13. Then, the refrigerant that has been sufficiently vaporized flows into the compressor 6 located downstream, and is compressed again to continue the refrigeration cycle. In other words, a part of the air taken in from the intake port 2 is pre-cooled by the second region 13b before reaching the radiator 5, so that the cooling efficiency of the radiator 5 is improved, and the power consumption is further reduced.

又如圖2所示，吸熱器13之第2區域13b宜位於吸氣口2之吸氣口上端2a與吸氣口下端2b之間之高度。結果，由於可有效地暖化第2區域13b，因此可更為促進第2區域13b之中之冷媒的氣化。 Further, as shown in Fig. 2, the second region 13b of the heat absorber 13 is preferably located at a height between the upper end 2a of the intake port 2 and the lower end 2b of the intake port 2. As a result, since the second region 13b can be effectively warmed, the vaporization of the refrigerant in the second region 13b can be further promoted.

又，為了圖1之除濕裝置10之小型化化，不太能除濕之圖4之第2區域13b之第2區域通風截面13c宜較小。因此，相較於第1區域13a之第1區域通風截面13d、第2區域13b之第2區域通風截面13c宜較小。具體而言，若是第2區域通風截面13c在第1區域通風截面13d之5%以上、25%以下， 則除濕裝置10更為小型化。 Further, in order to reduce the size of the dehumidifying apparatus 10 of Fig. 1, the second region venting section 13c of the second region 13b of Fig. 4 which is less likely to be dehumidified is preferably small. Therefore, the second region ventilation cross section 13c is preferably smaller than the first region ventilation cross section 13d of the first region 13a and the second region 13b. Specifically, if the second region ventilation cross section 13c is 5% or more and 25% or less of the first region ventilation cross section 13d, The dehumidification device 10 is further miniaturized.

再者如圖2所示，除濕裝置10具有：從吸氣口2經由第1熱交換風路11c、吸熱器13之第1區域13a、第2熱交換風路11d、散熱器5到吹出口3之除濕風路14、及從吸氣口2經由散熱器5到吹出口3之分流風路15。因此藉由送風機8而從吸氣口2吸入本體外殼1內之空氣分成通過除濕風路14之空氣、及通過分流風路15之空氣二種。 Further, as shown in FIG. 2, the dehumidifying apparatus 10 has a first heat exchange air passage 11c, a first region 13a of the heat absorber 13, a second heat exchange air passage 11d, and a radiator 5 to a blowout port. The dehumidification air passage 14 of 3 and the split air passage 15 from the intake port 2 via the radiator 5 to the air outlet 3. Therefore, the air sucked into the main body casing 1 from the intake port 2 by the blower 8 is divided into air passing through the dehumidification air passage 14 and air passing through the split air passage 15.

可是，圖2之散熱器5上端之散熱器上端部5a、熱交換器11上端之熱交換器上端部11e之高度相同，即使沒有分流風路15而僅有除濕風路14，也能得到上述之本發明之效果。以下是存在非必要之分流風路15之情況的例子。 However, the upper end portion 5a of the heat sink 5 at the upper end of the heat sink 5 of FIG. 2 and the upper end portion 11e of the heat exchanger 11 at the upper end of the heat exchanger 11 have the same height, and even if there is only the split air passage 15 and only the dehumidification air passage 14 is provided, the above can be obtained. The effect of the present invention. The following is an example of the case where there is a non-essential split air path 15.

如圖2之箭頭記號D所示，被送風機8從吸氣口2吸入到本體外殼1內之空氣的一部分從吸氣口2不經過熱交換器11與吸熱器13之第1區域13a而流過從散熱器5到吹出口3之分流風路15。又散熱器上端部5a設置於比熱交換器上端部11e更高的位置。而且，從散熱器5之熱交換器上端部11e之位置到散熱器上端部5a之散熱器上部5c形成了分流風路15之一部分。 As shown by the arrow mark D in Fig. 2, a part of the air sucked into the main body casing 1 by the blower 8 from the intake port 2 flows from the intake port 2 without passing through the heat exchanger 11 and the first region 13a of the heat absorber 13. The split air passage 15 from the radiator 5 to the blower outlet 3 passes. Further, the radiator upper end portion 5a is provided at a position higher than the heat exchanger upper end portion 11e. Further, a portion of the split air passage 15 is formed from the position of the heat exchanger upper end portion 11e of the heat sink 5 to the heat sink upper portion 5c of the heat sink upper end portion 5a.

本實施型態之圖2之除濕裝置10藉由增加流入到散熱器5之空氣而增加了散熱器5之冷媒與吸氣之空氣的熱交換量，並且散熱器5更為冷卻。 The dehumidifying apparatus 10 of Fig. 2 of the present embodiment increases the amount of heat exchange between the refrigerant of the radiator 5 and the inhaled air by increasing the air flowing into the radiator 5, and the radiator 5 is further cooled.

又如圖2所示，吸入之空氣分成通過除濕風路14之空氣、及通過分流風路15之空氣二種。藉此，送風到熱交換器11與吸熱器13之風量會保持最適當的除濕能力，並 且增加送風到散熱器5之風量。再者，通過除濕風路14與分流風路15之空氣藉由送風機8混合而由吹出口3吹出。 As shown in Fig. 2, the inhaled air is divided into air passing through the dehumidification air passage 14 and air passing through the split air passage 15. Thereby, the amount of air supplied to the heat exchanger 11 and the heat absorber 13 maintains the most appropriate dehumidification capacity, and And increase the amount of air supplied to the radiator 5. Further, the air passing through the dehumidifying air passage 14 and the split air passage 15 is blown by the blower 8 by being mixed by the blower 8.

又，由於分流風路15不經過熱交換器11等，因此風阻比除濕風路14小、減輕送風機8之輸出增加。特別是，由於僅散熱器5之散熱器上部5c形成有分流風路15之一部分，因此分流風路15之風阻變小、有效率地進行散熱器5之冷卻。由以上，除濕裝置10之除濕能力不會下降而可減少消耗電力。 Further, since the split air passage 15 does not pass through the heat exchanger 11 or the like, the wind resistance is smaller than that of the dehumidification air passage 14, and the output of the blower 8 is reduced. In particular, since only one portion of the split air passage 15 is formed in the radiator upper portion 5c of the radiator 5, the wind resistance of the split air passage 15 is reduced, and the radiator 5 is efficiently cooled. From the above, the dehumidification capability of the dehumidifying apparatus 10 does not decrease, and power consumption can be reduced.

又，如圖2所示，散熱器上端部5a亦可位於吸氣口2之吸氣口上端2a與吸氣口下端2b之間的高度。從吸氣口2吸入之空氣在熱交換器11之上方朝水平方向前進、並滯留於為分流風路15之一部分之散熱器上部5c。該空氣可從吸氣口2到散熱器上部5c，進行方向幾乎沒有彎曲地滯留於散熱器上部5c，因此分流風路15之風阻變得更小。 Further, as shown in FIG. 2, the upper end portion 5a of the radiator may be located at a height between the upper end 2a of the intake port 2 and the lower end 2b of the intake port 2. The air taken in from the intake port 2 advances in the horizontal direction above the heat exchanger 11 and stays in the upper portion 5c of the radiator which is a part of the split air passage 15. This air can be retained in the upper portion 5c of the radiator from the intake port 2 to the upper portion 5c of the radiator, and the wind direction of the split air passage 15 becomes smaller.

又，從圖2之散熱器5之熱交換器上端部11e之位置到散熱器5下端之散熱器下端部5b之散熱器下部5d形成了除濕風路14之一部分。而且從散熱器上部5c之散熱器上端部5a到熱交換器上端部11e之位置之散熱器上部長度5e，亦可比從散熱器下部5d之散熱器下端部5b到熱交換器上端部11e之位置之散熱器下部長度5f。 Further, a portion of the dehumidification air passage 14 is formed from the position of the heat exchanger upper end portion 11e of the radiator 5 of Fig. 2 to the radiator lower portion 5d of the radiator lower end portion 5b at the lower end of the radiator 5. Further, the upper portion length 5e of the heat sink from the upper end portion 5a of the radiator upper portion 5c to the upper end portion 11e of the heat exchanger may be higher than the lower end portion 5b of the radiator from the lower portion 5d of the radiator to the upper end portion 11e of the heat exchanger. The lower part of the radiator is 5f in length.

分流風路15之風阻比除濕風路14小，因此即使散熱器上部5c比散熱器下部5d小，可保持除濕風路14進行之除濕、與分流風路15進行之散熱器5之冷卻的平衡、除濕裝置10可防止除濕能力下降，進而降低消耗電力。 Since the wind resistance of the split air passage 15 is smaller than that of the dehumidification air passage 14, even if the radiator upper portion 5c is smaller than the radiator lower portion 5d, the dehumidification by the dehumidification air passage 14 and the cooling of the radiator 5 by the split air passage 15 can be maintained. The dehumidifying device 10 can prevent the dehumidification capability from being lowered, thereby reducing the power consumption.

又，通過圖2之分流風路15之空氣流量亦可比通過除濕風路14之空氣流量多。結果，可更平衡地進行除濕風路14之除濕、及分流風路15進行之散熱器5之冷卻，可防止除濕裝置10之除濕能力下降，並且更為降低消耗電力。 Further, the air flow rate through the split air passage 15 of FIG. 2 may be larger than the air flow rate through the dehumidification air passage 14. As a result, the dehumidification of the dehumidification air passage 14 and the cooling of the radiator 5 by the split air passage 15 can be performed more evenly, and the dehumidification capability of the dehumidifying apparatus 10 can be prevented from being lowered, and the power consumption can be further reduced.

如圖2所示，散熱器上部5c連接來自壓縮機6之冷媒配管17、且於散熱器下部5d連接由來自膨脹部12之冷媒配管17。壓縮機6中，成為高溫之冷媒流入散熱器上部5c。因此散熱器上部5c的溫度比散熱器下部5d高。又，分流風路15的風阻比除濕風路14小。 As shown in FIG. 2, the radiator upper portion 5c is connected to the refrigerant pipe 17 from the compressor 6, and the refrigerant pipe 17 from the expansion portion 12 is connected to the radiator lower portion 5d. In the compressor 6, the high-temperature refrigerant flows into the radiator upper portion 5c. Therefore, the temperature of the upper portion 5c of the radiator is higher than the lower portion 5d of the radiator. Further, the wind speed of the split air passage 15 is smaller than that of the dehumidification air passage 14.

因此散熱器上部5c流入比通過除濕風路14之空氣還多的空氣，因此，可平衡地進行除濕風路14進行之除濕與分流風路15進行之散熱器5之冷卻。 Therefore, the radiator upper portion 5c flows into the air more than the air passing through the dehumidification air passage 14, so that the dehumidification by the dehumidification air passage 14 and the cooling of the radiator 5 by the split air passage 15 can be performed in a balanced manner.

又如圖2所示，本體外殼1之吹出口3亦可設置在與吸氣口2或者比吸氣口2高之位置。由於吹出口3設置在較高的位置，因此可有效地吹出從除濕裝置10除濕後之空氣，提高除濕效率。 As shown in FIG. 2, the air outlet 3 of the main body casing 1 may be disposed at a position higher than the air intake port 2 or the air intake port 2. Since the air outlet 3 is disposed at a higher position, the air dehumidified from the dehumidifying device 10 can be effectively blown to improve the dehumidification efficiency.

又如圖2所示，吸熱器13之第2區域13b亦可設置在比散熱器上端部5a低之位置。結果，從吸氣口2吸入之空氣進入吸熱器13及熱交換器11之上方、停留於形成分流風路15之一部分之散熱器上部5c。該空氣從吸氣口2到散熱器上部5c，進行方向不會頻繁地彎曲，因此分流風路15之風阻變得更小。 Further, as shown in Fig. 2, the second region 13b of the heat absorber 13 may be disposed at a position lower than the upper end portion 5a of the heat sink. As a result, the air taken in from the intake port 2 enters the heat absorber 13 and the heat exchanger 11 and stays in the upper portion 5c of the radiator which forms part of the split air passage 15. Since the air is not bent frequently from the intake port 2 to the upper portion 5c of the radiator, the wind resistance of the split air passage 15 becomes smaller.

又如圖2所示，送風機8之罩殼部8a之吸入口9a亦可與吸熱器13、熱交換器11、及散熱器5對向，並且分流 風路15連通於散熱器5之周緣部之一部分的附近。 Further, as shown in Fig. 2, the suction port 9a of the casing portion 8a of the blower 8 may be opposed to the heat absorber 13, the heat exchanger 11, and the radiator 5, and may be branched. The air passage 15 is in communication with a portion of a portion of the peripheral portion of the radiator 5.

又，往圖2所示之散熱器上部5c，愈靠近散熱器上端部5a，則送風之風量愈大。由於在散熱器上部5c，散熱器上端部5a最高溫，因此愈靠近散熱器上端部5a，則送風量愈多時，散熱器5之熱交換量變大。結果，可有效率地冷卻散熱器5，降低除濕裝置10之消耗電力。 Further, as the heat sink upper portion 5c shown in Fig. 2 is closer to the upper end portion 5a of the heat sink, the amount of air blown is larger. Since the upper end portion 5a of the heat sink is the highest temperature in the upper portion 5c of the heat sink, the closer to the upper end portion 5a of the heat sink, the larger the amount of air blown, the larger the amount of heat exchange of the heat sink 5. As a result, the radiator 5 can be efficiently cooled, and the power consumption of the dehumidifying device 10 can be reduced.

具體而言，散熱器上端部5a位於吸氣口上端2a與吸氣口下端2b之間之高度，進而散熱器上端部5a位於比吸氣口上端2a更靠近吸氣口下端2b的位置。而且、在散熱器上端部5a與本體外殼1之間，亦可具有空間部16。在本體外殼1內，從吸氣口2側依序配置有吸熱器13、熱交換器11、散熱器5、及送風機8。空間部16之一部分被散熱器上端部5a與送風機8之罩殼部8a之外面包圍。藉此，往散熱器上部5c變得可容易由下述之2個面流入。 Specifically, the upper end portion 5a of the radiator is located at a height between the upper end 2a of the intake port and the lower end 2b of the intake port, and the upper end portion 5a of the radiator is located closer to the lower end 2b of the intake port than the upper end 2a of the intake port. Further, a space portion 16 may be provided between the upper end portion 5a of the heat sink and the main body casing 1. In the main body casing 1, a heat absorber 13, a heat exchanger 11, a radiator 5, and a blower 8 are disposed in this order from the side of the intake port 2. One portion of the space portion 16 is surrounded by the upper end portion 5a of the radiator and the outer surface of the casing portion 8a of the blower 8. Thereby, the heat sink upper portion 5c can easily flow in from the following two faces.

上述之2個面中之第1面為與散熱器上部5c之吸氣口2對向之面。第2面為散熱器上端部5a。空氣經由分流風路15與空間部16而流入到散熱器上端部5a。又，到達空間部16之空氣的一部分碰到與吸氣口2對向之罩殼部8a之外面，藉此往下方改變方向而流入散熱器上端部5a。 The first surface of the two surfaces described above faces the air inlet 2 of the heat sink upper portion 5c. The second surface is the heat sink upper end portion 5a. The air flows into the radiator upper end portion 5a via the branch air passage 15 and the space portion 16. Further, a part of the air reaching the space portion 16 hits the outer surface of the casing portion 8a opposed to the intake port 2, thereby changing the direction downward and flowing into the radiator upper end portion 5a.

即、空氣從2個面流入散熱器上部5c，從吸氣口2流往分流風路15之空氣愈靠近散熱器上端部5a則流入愈多。如此，在散熱器上部5c中，由於愈靠近散熱器上端部5a，有更多空氣流入，因此可平衡地進行散熱器上部5c之冷 卻。 That is, air flows into the radiator upper portion 5c from the two surfaces, and the air flowing from the intake port 2 to the branch air passage 15 is closer to the radiator upper end portion 5a. Thus, in the upper portion 5c of the radiator, since more air flows in toward the upper end portion 5a of the radiator, the cold portion 5c of the radiator can be balancedly cooled. but.

1‧‧‧本體外殼 1‧‧‧ body shell

2‧‧‧吸氣口 2‧‧‧ suction port

2a‧‧‧吸氣口上端 2a‧‧‧ upper end of suction port

2b‧‧‧吸氣口下端 2b‧‧‧At the lower end of the suction port

3‧‧‧吹出口 3‧‧‧Blowing out

4‧‧‧儲水槽 4‧‧‧Water storage tank

5‧‧‧散熱器 5‧‧‧heatsink

5a‧‧‧散熱器上端部 5a‧‧‧ Upper end of the radiator

5b‧‧‧散熱器下端部 5b‧‧‧lower end of the radiator

5c‧‧‧散熱器上部 5c‧‧‧ Upper part of the radiator

5d‧‧‧散熱器下部 5d‧‧‧lower radiator

5e‧‧‧散熱器上部長度 5e‧‧‧ Upper length of the radiator

5f‧‧‧散熱器下部長度 5f‧‧‧lower radiator length

6‧‧‧壓縮機 6‧‧‧Compressor

7‧‧‧排水盤 7‧‧‧Drainage tray

8‧‧‧送風機 8‧‧‧Air blower

8a‧‧‧罩殼部 8a‧‧‧Shell Department

8b‧‧‧馬達部 8b‧‧‧Motor Department

8c‧‧‧葉片部 8c‧‧‧blade department

9a‧‧‧吸入口 9a‧‧‧Inhalation

9b‧‧‧吐出口 9b‧‧‧Exporting

10‧‧‧除濕裝置 10‧‧‧Dehumidification device

11‧‧‧熱交換器 11‧‧‧ heat exchanger

11c‧‧‧第1熱交換風路 11c‧‧‧1st heat exchange airway

11d‧‧‧第2熱交換風路 11d‧‧‧2nd heat exchange airway

11e‧‧‧熱交換器上端部 11e‧‧‧ Upper end of heat exchanger

12‧‧‧膨脹部 12‧‧‧Expansion

13‧‧‧吸熱器 13‧‧‧heat absorber

13a‧‧‧第1區域 13a‧‧‧1st area

13b‧‧‧第2區域 13b‧‧‧2nd area

14‧‧‧除濕風路 14‧‧‧Dehumidification Wind Road

15‧‧‧分流風路 15‧‧‧Diversion wind path

16‧‧‧空間部 16‧‧‧ Space Department

17‧‧‧冷媒配管 17‧‧‧Refrigerant piping

21‧‧‧冷媒流動之方向 21‧‧‧The direction of refrigerant flow

30‧‧‧熱泵裝置 30‧‧‧ heat pump unit

C‧‧‧箭頭記號 C‧‧‧arrow mark

D‧‧‧箭頭記號 D‧‧‧ arrow mark

Claims (10)

一種除濕裝置，包含有：本體外殼、送風機、熱泵裝置及熱交換器，前述送風機、前述熱泵裝置、及前述熱交換器設置於前述本體外殼內，前述本體外殼具有吸氣口與吹出口，前述吸氣口設置於前述本體外殼之外周壁上部，前述送風機從前述吸氣口吸入空氣而從前述吹出口吹出前述空氣，前述熱泵裝置由壓縮機、散熱器、膨脹部及吸熱器構成，前述散熱器、前述膨脹部、及前述吸熱器在前述熱泵裝置之冷媒流動之方向上依序設置於前述壓縮機之下游，前述散熱器與前述吸熱器對向，在前述散熱器與前述吸熱器之間設置前述熱交換器，前述吸熱器由第1區域與第2區域構成並且在前述冷媒流動之方向上，前述第2區域位於前述第1區域較下游側，前述第2區域突出於前述吸氣口與前述熱交換器之間。 A dehumidifying device comprising: a main body casing, a blower, a heat pump device, and a heat exchanger; wherein the air blower, the heat pump device, and the heat exchanger are disposed in the main body casing, wherein the main body casing has an air inlet and a blowout port, and the foregoing The air intake port is disposed at an upper portion of the outer peripheral wall of the main body casing, and the air blower sucks air from the air intake port to blow the air from the air outlet. The heat pump device is composed of a compressor, a radiator, an expansion portion, and a heat sink, and the heat dissipation device The heat sink, the expansion portion, and the heat absorber are sequentially disposed downstream of the compressor in a direction in which the refrigerant of the heat pump device flows, and the heat sink is opposed to the heat absorber between the heat sink and the heat absorber The heat exchanger is provided, wherein the heat absorber is composed of a first region and a second region, and in a direction in which the refrigerant flows, the second region is located downstream of the first region, and the second region protrudes from the suction port Between the aforementioned heat exchangers. 如請求項1之除濕裝置，其中前述第2區域位於前述吸 氣口之吸氣口上端與吸氣口下端之間之高度。 The dehumidifying device of claim 1, wherein the aforementioned second region is located in the aforementioned suction The height between the upper end of the suction port of the port and the lower end of the suction port. 如請求項1或2之除濕裝置，其中前述第2區域之第2區域通風截面比前述第1區域之第1區域通風截面小。 The dehumidifying apparatus according to claim 1 or 2, wherein the second region ventilation section of the second region is smaller than the first region ventilation section of the first region. 如請求項3之除濕裝置，其中前述第2區域通風截面是前述第1區域通風截面之5%以上、25%以下。 The dehumidifying apparatus according to claim 3, wherein the second region ventilation section is 5% or more and 25% or less of the ventilation section of the first region. 如請求項2之除濕裝置，其中前述熱交換器具有互相進行熱交換之第1熱交換風路與第2熱交換風路，並且具有從前述吸氣口經由前述第1熱交換風路、前述第1區域、前述第2熱交換風路、及前述散熱器到前述吹出口之除濕風路，及從前述吸氣口經由前述散熱器到前述吹出口之分流風路，藉由前述送風機從前述吸氣口吸入到前述本體外殼內之前述空氣分成前述除濕風路與前述分流風路，通過前述除濕風路與前述分流風路之前述空氣會混合而從前述吹出口吹出，前述散熱器上端之散熱器上端部設置於比前述熱交換器上端之熱交換器上端部高的位置，從前述散熱器之前述熱交換器上端部到前述散熱器上端部之散熱器上部形成前述分流風路之一部分。 The dehumidifier of claim 2, wherein the heat exchanger has a first heat exchange air passage and a second heat exchange air passage that exchange heat with each other, and has the first heat exchange air passage from the intake port, and the a first region, the second heat exchange air passage, and a dehumidification air passage of the radiator to the air outlet, and a split air passage from the intake port to the air outlet through the radiator, and the air blower from the air blower The air sucked into the main body casing by the intake port is divided into the dehumidification air passage and the split air passage, and the air is mixed with the air of the split air passage through the dehumidification air passage, and is blown out from the air outlet, and the upper end of the radiator is The upper end portion of the heat sink is disposed at a position higher than the upper end portion of the heat exchanger at the upper end of the heat exchanger, and a portion of the shunt air passage is formed from an upper end portion of the heat exchanger from the upper end portion of the heat sink to an upper portion of the heat sink upper end portion . 如請求項5之除濕裝置，其中前述散熱器上端部位於前述吸氣口上端與前述吸氣口下端之間的高度，並且在前述散熱器上端部與前述本體外殼之間具有空間部。 The dehumidifying device of claim 5, wherein the upper end portion of the heat sink is located at a height between the upper end of the suction port and the lower end of the suction port, and has a space portion between the upper end portion of the heat sink and the body casing. 如請求項5之除濕裝置，其中從前述散熱器之前述熱交換器上端部到前述散熱器下端之散熱器下端部之散熱器下部形成前述除濕風路之一部分，從前述散熱器上部之前述散熱器上端部到前述熱交換器上端部之散熱器上部長度，比前述散熱器下部之散熱器下端部到前述熱交換器上端部之散熱器下部長度短。 The dehumidifying device of claim 5, wherein a portion of the dehumidifying air passage is formed from a lower end portion of the heat exchanger from an upper end portion of the heat sink to a lower end portion of the heat sink at a lower end portion of the heat sink, and the heat dissipation from the upper portion of the heat sink The length of the upper portion of the heat sink from the upper end of the heat exchanger to the upper end of the heat exchanger is shorter than the length of the lower portion of the heat sink at the lower end of the heat sink to the lower end of the heat exchanger. 如請求項5之除濕裝置，其中前述吹出口設置於與前述吸氣口相同或者比前述吸氣口高的位置。 The dehumidifying apparatus according to claim 5, wherein the air outlet is provided at a position equal to or higher than the intake port. 如請求項5之除濕裝置，其中前述第2區域設置於比前述散熱器上端部低之位置。 The dehumidifying device of claim 5, wherein the second region is disposed at a position lower than an upper end portion of the heat sink. 如請求項5之除濕裝置，其中前述送風機由渦形之罩殼部、固定於前述罩殼部之馬達部、及藉由前述馬達部來旋轉之葉片部形成，前述罩殼部具有吸入口與吐出口，前述吸入口與前述吸熱器、前述熱交換器、及前述散熱器對向。 The dehumidifying device according to claim 5, wherein the blower is formed by a scroll casing portion, a motor portion fixed to the casing portion, and a blade portion that is rotated by the motor portion, wherein the casing portion has a suction port and The discharge port faces the heat absorber, the heat exchanger, and the heat sink.