TWI770482B - dehumidifier - Google Patents

Abstract

[課題]可得到一種除濕機，該除濕機係可使在蒸發器之除濕量與凝結器之散熱效率雙全。 [解決手段]除濕機1係包括：蒸發器31；第1凝結器33a；吸熱部35及散熱部36，係被配置成隔著蒸發器31；以及送風風扇21，係在框體10之內部取入空氣。吸熱部35與散熱部36係被熱媒體所循環之熱管連接。吸熱部35係被配置於蒸發器31之上風側，散熱部36係被配置於蒸發器31之下風側。在框體10之內部，係在散熱部36與第1凝結器33a之間形成混合空間41。藉送風風扇21所取入之空氣的一部分係依序通過吸熱部35、蒸發器31以及散熱部36並被送往混合空間41，藉送風風扇21所取入的空氣之剩下的部分係不經由吸熱部35、蒸發器31以及散熱部36地被送往混合空間41。[Subject] A dehumidifier can be obtained, which can achieve both the dehumidification capacity of the evaporator and the heat dissipation efficiency of the condenser. [Solution] The dehumidifier 1 includes: an evaporator 31; a first condenser 33a; Take in air. The heat absorption part 35 and the heat dissipation part 36 are connected by a heat pipe through which a heat medium circulates. The heat absorption part 35 is arranged on the windward side of the evaporator 31 , and the heat radiation part 36 is arranged on the windward side of the evaporator 31 . Inside the casing 10, a mixing space 41 is formed between the heat dissipation portion 36 and the first condenser 33a. A part of the air taken in by the blower fan 21 passes through the heat absorption part 35, the evaporator 31 and the heat dissipation part 36 in sequence and is sent to the mixing space 41, and the rest of the air taken in by the blower fan 21 is not. It is sent to the mixing space 41 via the heat absorption part 35 , the evaporator 31 , and the heat dissipation part 36 .

Description

除濕機dehumidifier

本發明係有關於一種除濕機。The present invention relates to a dehumidifier.

在專利文獻1，記載一種除濕機。此除濕機係利用形成冷媒循環之熱泵，對空氣除濕，而該冷媒循環係由壓縮機、凝結器、節流裝置以及蒸發器所構成。In Patent Document 1, a dehumidifier is described. This dehumidifier uses a heat pump to form a refrigerant cycle to dehumidify the air, and the refrigerant cycle is composed of a compressor, a condenser, a throttling device and an evaporator.

又，在專利文獻1所記載之除濕機係具有將兩側片作為吸熱部及散熱部之U字形熱管。熱管之吸熱部與散熱部係被配設成隔著熱泵之蒸發器。在專利文獻1所記載之除濕機係藉由具有熱管，使在蒸發器之除濕量增大。 [先行專利文獻] [專利文獻]Moreover, the dehumidifier described in patent document 1 has a U-shaped heat pipe which uses both side sheets as a heat absorption part and a heat radiation part. The heat absorbing part and the heat radiating part of the heat pipe are arranged so as to interpose the evaporator of the heat pump. The dehumidifier described in Patent Document 1 increases the amount of dehumidification in the evaporator by having a heat pipe. [Preceding Patent Documents] [Patent Literature]

[專利文獻1]日本特開昭61－211668號公報[Patent Document 1] Japanese Patent Laid-Open No. 61-211668

[發明所欲解決之課題][The problem to be solved by the invention]

在上述之專利文獻1所記載的除濕機，係在除濕機內的風路之空氣的壓力損失比未具有熱管之除濕機增加。因此，具有凝結器之散熱效率降低的課題。In the dehumidifier described in the above-mentioned Patent Document 1, the pressure loss of the air in the air duct in the dehumidifier is higher than that of a dehumidifier without a heat pipe. Therefore, there is a problem that the heat dissipation efficiency of the condenser is lowered.

本發明係為了解決如上述所示之課題而開發者。本發明之目的係得到一種除濕機，該除濕機係可使在蒸發器之除濕量與凝結器之散熱效率雙全。 [解決課題之手段]The present invention was developed in order to solve the above-mentioned problems. The object of the present invention is to obtain a dehumidifier which can achieve both the dehumidification capacity of the evaporator and the heat dissipation efficiency of the condenser. [Means of Solving Problems]

本發明之除濕機係包括：熱媒體所通過之蒸發器；壓縮機，係壓縮通過蒸發器之熱媒體；第1凝結器，係藉壓縮機所壓縮之熱媒體通過；降壓裝置，係將已通過第1凝結器之熱媒體降壓；吸熱部及散熱部，係被配置成隔著蒸發器；框體，係在內部收容蒸發器、壓縮機、第1凝結器、吸熱部以及散熱部；以及送風手段，係在框體之內部取入空氣，並向框體之外部送出所取入的空氣。吸熱部及散熱部係被熱媒體所循環之熱管連接；吸熱部係被配置於蒸發器之上風側，並冷卻藉送風手段在框體之內部所取入的空氣。散熱部係被配置於蒸發器之下風側，並對已通過蒸發器之空氣加熱。在框體之內部，係在散熱部與第1凝結器之間形成混合空間。藉送風手段在框體之內部所取入的空氣之一部分係依序通過吸熱部、蒸發器以及散熱部並被送往混合空間。藉送風手段在框體之內部所取入的空氣之剩下的部分係不經由吸熱部、蒸發器以及散熱部地被送往混合空間。 [發明之效果]The dehumidifier of the present invention includes: an evaporator through which the heat medium passes; a compressor, which compresses the heat medium passing through the evaporator; a first condenser, which passes through the heat medium compressed by the compressor; The heat medium that has passed through the first condenser is depressurized; the heat absorbing part and the heat radiating part are arranged across the evaporator; the frame body houses the evaporator, the compressor, the first condenser, the heat absorbing part and the heat radiating part inside. ; and air supply means, which take in air inside the frame and send the taken-in air to the outside of the frame. The heat-absorbing part and the heat-dissipating part are connected by a heat pipe circulating a heat medium; the heat-absorbing part is arranged on the upper wind side of the evaporator, and cools the air taken in by the air supply means inside the frame. The heat dissipation part is arranged on the downwind side of the evaporator, and heats the air that has passed through the evaporator. Inside the frame, a mixing space is formed between the heat sink and the first condenser. A part of the air taken in by the blowing means inside the frame body passes through the heat absorption part, the evaporator and the heat dissipation part in sequence and is sent to the mixing space. The remaining part of the air taken in by the blower means inside the casing is sent to the mixing space without passing through the heat absorption part, the evaporator, and the heat dissipation part. [Effect of invention]

若依據本發明之除濕機，可使在蒸發器之除濕量與凝結器之散熱效率雙全。According to the dehumidifier of the present invention, both the dehumidification capacity of the evaporator and the heat dissipation efficiency of the condenser can be achieved.

以下，參照附加之圖面，說明實施形態。在各圖之相同的符號係表示相同的部分或相當的部分。又，在本揭示，關於重複的說明，係適當地簡化或省略。此外，本揭示係在不超出其主旨的範圍，可包含在以下之實施形態說明的構成之所有的組合及各種的變形例。 實施形態1Hereinafter, embodiments will be described with reference to the attached drawings. The same symbols in the various figures denote the same parts or corresponding parts. In addition, in the present disclosure, overlapping descriptions are appropriately simplified or omitted. In addition, the present disclosure can include all combinations and various modifications of the configurations described in the following embodiments without departing from the gist of the present disclosure. Embodiment 1

圖1係實施形態1之除濕機1的正視圖。圖1係表示除濕機1之外觀。除濕機1係例如以降低室內之濕度為目的所使用。圖2係實施形態1之除濕機1的剖面圖。圖2係表示在圖1之A－A位置的剖面。圖2係表示實施形態1的除濕機1之內部的構成。FIG. 1 is a front view of the dehumidifier 1 according to the first embodiment. FIG. 1 shows the appearance of the dehumidifier 1 . The dehumidifier 1 is used for the purpose of reducing indoor humidity, for example. FIG. 2 is a cross-sectional view of the dehumidifier 1 according to the first embodiment. FIG. 2 is a cross section at the AA position in FIG. 1 . FIG. 2 shows the internal configuration of the dehumidifier 1 according to the first embodiment.

圖2之紙面上的左方向係除濕機1的正面方向。圖2之紙面上的右方向係除濕機1的背面方向。正面方向係亦稱為前方向。背面方向係亦稱為後方向。在本揭示，係原則上，將除濕機1被放置於水平面上的狀態作為基準，定義各方向。The left direction on the paper surface of FIG. 2 is the front direction of the dehumidifier 1 . The right direction on the paper surface of FIG. 2 is the back direction of the dehumidifier 1 . The front direction is also called the front direction. The rear direction is also referred to as the rear direction. In the present disclosure, in principle, each direction is defined on the basis of a state in which the dehumidifier 1 is placed on a horizontal plane.

如圖1及圖2所示，除濕機1係具有框體10。框體10係被形成為可自立。在框體10，係形成吸入口11及吹出口12。吸入口11係用以從框體10之外部向內部取入空氣的開口。吹出口12係用以從框體10之內部向外部送出空氣的開口。As shown in FIGS. 1 and 2 , the dehumidifier 1 includes a housing 10 . The casing 10 is formed to be self-supporting. In the housing|casing 10, the suction port 11 and the blower outlet 12 are formed. The suction port 11 is an opening for taking in air from the outside of the casing 10 to the inside. The air outlet 12 is an opening for sending air from the inside of the casing 10 to the outside.

在本實施形態，吸入口11係被形成於框體10之背面部分。又，吹出口12係被形成於框體10之上面部分。此外，亦可吸入口11及吹出口12係被設置於任意的位置。例如，亦可吸入口11係被形成於框體10之側面部分。在吸入口11被形成於框體10之不是背面部分之部分的情況，除濕機1係成為在背面與壁接觸或靠近的狀態可使用。In the present embodiment, the suction port 11 is formed in the rear surface portion of the housing 10 . Moreover, the blower outlet 12 is formed in the upper surface part of the housing|casing 10. As shown in FIG. In addition, the suction port 11 and the blower outlet 12 may be provided at arbitrary positions. For example, the suction port 11 may be formed on the side surface of the frame body 10 . When the suction port 11 is formed in a part of the casing 10 that is not the back surface, the dehumidifier 1 can be used in a state where the back surface is in contact with or close to the wall.

除濕機1係作為送風手段之一例，具有送風風扇21。送風風扇21係被收容於框體10之內部。在框體10之內部，係形成從吸入口11往吹出口12相通的風路。送風風扇21係被配置於此風路。送風風扇21係在框體10之內部取入空氣，並向框體10之外部送出所取入之空氣的裝置。The dehumidifier 1 has a ventilation fan 21 as an example of the ventilation means. The blower fan 21 is accommodated in the casing 10 . Inside the casing 10, an air passage that communicates from the suction port 11 to the air outlet 12 is formed. The blower fan 21 is arranged in this air passage. The blower fan 21 is a device that takes in air inside the casing 10 and sends the taken-in air to the outside of the casing 10 .

又，本實施形態之除濕機1係包括蒸發器31、壓縮機32、第1凝結器33a以及第2凝結器33b。蒸發器31、壓縮機32、第1凝結器33a以及第2凝結器33b係如圖2所示，被收容於框體10之內部。Moreover, the dehumidifier 1 of this embodiment is provided with the evaporator 31, the compressor 32, the 1st condenser 33a, and the 2nd condenser 33b. The evaporator 31 , the compressor 32 , the first condenser 33 a and the second condenser 33 b are housed in the casing 10 as shown in FIG. 2 .

除濕機1係具有除濕手段。除濕手段係用以除去空氣中之水分。除濕手段係由熱媒體迴路所構成。熱媒體迴路係熱媒體所循環之迴路。圖3係在模式上表示實施形態1之熱媒體迴路的圖。除濕機1係如圖3所示，具有降壓裝置34。降壓裝置34係被收容於框體10之內部。The dehumidifier 1 series has dehumidification means. Dehumidification means is used to remove moisture from the air. The dehumidification means is composed of a heat medium circuit. The heat medium circuit is the circuit in which the heat medium circulates. Fig. 3 is a diagram schematically showing the heat medium circuit of the first embodiment. The dehumidifier 1 has a pressure reducing device 34 as shown in FIG. 3 . The depressurizing device 34 is accommodated in the casing 10 .

在本實施形態，構成除濕手段之熱媒體迴路係冷凍循環迴路。此冷凍循環迴路係由蒸發器31、壓縮機32、第1凝結器33a、第2凝結器33b以及降壓裝置34所構成。In the present embodiment, the heat medium circuit constituting the dehumidification means is a refrigeration cycle circuit. This refrigeration cycle is constituted by an evaporator 31 , a compressor 32 , a first condenser 33 a , a second condenser 33 b , and a pressure reducing device 34 .

在蒸發器31、壓縮機32、第1凝結器33a、第2凝結器33b以及降壓裝置34，係熱媒體循環。蒸發器31、壓縮機32、第1凝結器33a、第2凝結器33b以及降壓裝置34係經由熱媒體所流動的配管被連接。In the evaporator 31, the compressor 32, the first condenser 33a, the second condenser 33b, and the pressure reducing device 34, a heat medium circulates. The evaporator 31, the compressor 32, the first condenser 33a, the second condenser 33b, and the depressurizing device 34 are connected via piping through which the heat medium flows.

蒸發器31、第1凝結器33a以及第2凝結器33b係分別是用以在熱媒體與空氣之間進行熱交換的熱交換器。壓縮機32係壓縮熱媒體的裝置。降壓裝置34係使熱媒體降壓的裝置。在降壓裝置34，係例如膨脹閥或毛細管等符合。The evaporator 31, the first condenser 33a, and the second condenser 33b are heat exchangers for exchanging heat between the heat medium and air, respectively. The compressor 32 is a device for compressing the heat medium. The depressurizing device 34 is a device for depressurizing the heat medium. At the pressure reducing device 34, for example, an expansion valve or a capillary tube is fitted.

蒸發器31、壓縮機32、第1凝結器33a、第2凝結器33b以及降壓裝置34係分別具有熱媒體之入口及出口。蒸發器31之出口係與壓縮機32之入口連接。在壓縮機32，係已通過蒸發器31之熱媒體流入。壓縮機32係壓縮已流入該壓縮機32之熱媒體。壓縮機32所壓縮之熱媒體係從該壓縮機32之出口流出。The evaporator 31, the compressor 32, the first condenser 33a, the second condenser 33b, and the pressure reducing device 34 have an inlet and an outlet of the heat medium, respectively. The outlet of the evaporator 31 is connected to the inlet of the compressor 32 . In the compressor 32, the heat medium which has passed through the evaporator 31 flows in. The compressor 32 compresses the heat medium that has flowed into the compressor 32 . The heat medium compressed by the compressor 32 flows out from the outlet of the compressor 32 .

壓縮機32之出口係與第1凝結器33a之入口連接。第1凝結器33a之出口係與第2凝結器33b之入口連接。在第1凝結器33a及第2凝結器33b，係壓縮機32所壓縮之熱媒體流動。The outlet of the compressor 32 is connected to the inlet of the first condenser 33a. The outlet of the first condenser 33a is connected to the inlet of the second condenser 33b. The heat medium compressed by the compressor 32 flows through the first condenser 33a and the second condenser 33b.

第2凝結器33b之出口係與降壓裝置34之入口連接。在降壓裝置34，係已通過第1凝結器33a及第2凝結器33b之熱媒體流入。降壓裝置34係使已流入該降壓裝置34之熱媒體降壓。降壓裝置34所降壓之熱媒體係膨脹。The outlet of the second condenser 33b is connected to the inlet of the pressure reducing device 34 . In the depressurizing device 34, the heat medium that has passed through the first condenser 33a and the second condenser 33b flows in. The depressurizing device 34 depressurizes the heat medium that has flowed into the depressurizing device 34 . The heat medium depressurized by the depressurizing device 34 expands.

降壓裝置34之出口係與蒸發器31之入口連接。在蒸發器31，係降壓裝置34所降壓之熱媒體流入。The outlet of the pressure reducing device 34 is connected to the inlet of the evaporator 31 . In the evaporator 31, the heat medium depressurized by the depressurizing device 34 flows in.

在本實施形態，熱媒體係依序通過蒸發器31、壓縮機32、第1凝結器33a、第2凝結器33b以及降壓裝置34。熱媒體係在蒸發器31從空氣中吸收熱而氣化。在蒸發器31已氣化的熱媒體係被壓縮機32壓縮而成為高溫高壓狀態。已通過壓縮機32之熱媒體係在第1凝結器33a及第2凝結器33b向空氣中放出熱而成為液體。已通過第1凝結器33a及第2凝結器33b之熱媒體係藉降壓裝置34膨脹而成為低溫低壓狀態。然後，已通過降壓裝置34之熱媒體係再在蒸發器31流動。在本實施形態，熱媒體係如上述所示，在冷凍循環迴路循環。此外，亦可在冷凍循環迴路之第1凝結器33a及第2凝結器33b的連接順序係相反。In the present embodiment, the heat medium passes through the evaporator 31, the compressor 32, the first condenser 33a, the second condenser 33b, and the pressure reducing device 34 in this order. The heat medium is vaporized by absorbing heat from the air in the evaporator 31 . The heat medium vaporized in the evaporator 31 is compressed by the compressor 32 to be in a high temperature and high pressure state. The heat medium which has passed through the compressor 32 emits heat to the air in the first condenser 33a and the second condenser 33b and becomes a liquid. The heat medium that has passed through the first condenser 33a and the second condenser 33b is expanded by the pressure reducing device 34 to be in a low temperature and low pressure state. Then, the heat medium that has passed through the pressure reducing device 34 flows through the evaporator 31 again. In the present embodiment, the heat medium circulates in the refrigeration cycle as described above. In addition, the connection order of the 1st condenser 33a and the 2nd condenser 33b in a refrigeration cycle may be reversed.

又，除濕機1係如圖2及圖3所示，包括吸熱部35及散熱部36。吸熱部35及散熱部36係被收容於框體10之內部。如圖2及圖3所示，吸熱部35及散熱部36係被配置成隔著蒸發器31。Moreover, as shown in FIGS. 2 and 3 , the dehumidifier 1 includes a heat absorption part 35 and a heat dissipation part 36 . The heat absorbing part 35 and the heat radiating part 36 are accommodated in the casing 10 . As shown in FIGS. 2 and 3 , the heat absorption part 35 and the heat dissipation part 36 are arranged so as to sandwich the evaporator 31 .

吸熱部35及散熱部36係用以在熱媒體與空氣之間進行熱交換的熱交換器。吸熱部35與散熱部36係被熱媒體所循環之熱管連接。本實施形態之除濕機1係具有預冷手段。預冷手段係用以預先冷卻被除濕手段除濕之前的空氣。預冷手段係由熱媒體迴路所構成。在本實施形態，構成預冷手段之熱媒體迴路係由吸熱部35及散熱部36所構成。The heat absorption part 35 and the heat dissipation part 36 are heat exchangers for exchanging heat between the heat medium and the air. The heat absorption part 35 and the heat dissipation part 36 are connected by a heat pipe through which a heat medium circulates. The dehumidifier 1 of this embodiment has a precooling means. The pre-cooling means is used to pre-cool the air before being dehumidified by the dehumidifying means. The pre-cooling means is composed of a heat medium circuit. In the present embodiment, the heat medium circuit constituting the precooling means is constituted by the heat absorption part 35 and the heat dissipation part 36 .

吸熱部35及散熱部36係分別具有熱媒體之入口及出口。吸熱部35之出口係與散熱部36之入口連接。在散熱部36，係已通過吸熱部35之熱媒體流入。散熱部36之出口係與吸熱部35之入口連接。在吸熱部35，係已通過散熱部36之熱媒體流入。The heat absorption part 35 and the heat dissipation part 36 respectively have an inlet and an outlet of the heat medium. The outlet of the heat absorption part 35 is connected to the inlet of the heat dissipation part 36 . In the heat dissipation part 36, the heat medium which has passed through the heat absorption part 35 flows in. The outlet of the heat dissipation part 36 is connected to the inlet of the heat absorption part 35 . In the heat absorbing portion 35, the heat medium that has passed through the heat radiating portion 36 flows in.

在本實施形態，吸熱部35之出口係位於比吸熱部35之入口上方。又，在框體10被放置於水平面的狀態，吸熱部35之出口係位於比散熱部36之入口更下方。散熱部36之出口係位於比散熱部36之入口下方。散熱部36之出口係位於比吸熱部35之入口更上方。In this embodiment, the outlet of the heat absorbing portion 35 is positioned above the inlet of the heat absorbing portion 35 . In addition, in the state in which the housing|casing 10 is set on a horizontal surface, the exit of the heat absorption part 35 is located in the lower part than the entrance of the heat dissipation part 36. FIG. The outlet of the heat dissipation portion 36 is located below the inlet of the heat dissipation portion 36 . The outlet of the heat dissipation part 36 is located above the inlet of the heat absorption part 35 .

如上述所示，吸熱部35及散熱部36係被配置成隔著蒸發器31。吸熱部35係被配置於蒸發器31之上風側。散熱部36係被配置於蒸發器31之下風側。藉送風風扇21在框體10之內部所取入的空氣之至少一部分係依序通過吸熱部35、蒸發器31以及散熱部36。即，在蒸發器31，係通過吸熱部35之後的空氣通過。又，在散熱部36，係通過蒸發器31之後的空氣通過。As described above, the heat absorption part 35 and the heat dissipation part 36 are arranged so as to sandwich the evaporator 31 . The heat absorption part 35 is arranged on the windward side of the evaporator 31 . The heat dissipation part 36 is arranged on the leeward side of the evaporator 31 . At least a part of the air taken in by the blower fan 21 inside the casing 10 passes through the heat absorption part 35 , the evaporator 31 and the heat dissipation part 36 in this order. That is, in the evaporator 31, the air after passing through the heat absorption part 35 passes. In addition, the air after passing through the evaporator 31 passes through the heat dissipation portion 36 .

已通過蒸發器31之空氣係被該蒸發器31冷卻。蒸發器31所冷卻之空氣係成為比室內之空氣更低溫。藉由蒸發器31所冷卻之空氣通過散熱部36，散熱部36內之熱媒體係被冷卻。散熱部36內之熱媒體係向空氣中散熱，而液化。The air that has passed through the evaporator 31 is cooled by the evaporator 31 . The air cooled by the evaporator 31 becomes cooler than the air in the room. The air cooled by the evaporator 31 passes through the heat dissipation portion 36, and the heat medium in the heat dissipation portion 36 is cooled. The heat medium in the heat-dissipating portion 36 dissipates heat into the air and liquefies.

已液化之熱媒體係密度比氣體之狀態的熱媒體更大。因此，已液化之熱媒體係在散熱部36內下降，再從散熱部36之出口流出。從散熱部36之出口所流出的熱媒體係流入位於比該出口更下方之吸熱部35的入口。The liquefied heat medium is denser than the heat medium in the gaseous state. Therefore, the liquefied heat medium descends in the heat dissipation part 36 and flows out from the outlet of the heat dissipation part 36 . The heat medium flowing out from the outlet of the heat radiating portion 36 flows into the inlet of the heat absorbing portion 35 located below the outlet.

散熱部36所冷卻之熱媒體係成為比室內之空氣更低溫。在蒸發器31之上風側所配置的吸熱部35，藉送風風扇21在框體10之內部所取入之室內的空氣通過。從散熱部36被送至吸熱部35之低溫的熱媒體係在吸熱部35吸收空氣中之熱而氣化。已氣化之熱媒體係密度比液體之狀態的熱媒體更小。因此，已氣化之熱媒體係在吸熱部35內上升，再從吸熱部35之出口流出。從吸熱部35之出口所流出的熱媒體係流入位於比該出口更上方之散熱部36的入口。流入散熱部36之熱媒體係再被送至吸熱部35。The heat medium cooled by the heat dissipation part 36 becomes lower temperature than the indoor air. The heat absorption part 35 arrange|positioned on the windward side of the evaporator 31 passes the air in the room which was taken in by the blower fan 21 inside the housing|casing 10. The low-temperature heat medium sent from the heat dissipation part 36 to the heat absorption part 35 is vaporized by absorbing the heat in the air in the heat absorption part 35 . The vaporized heat medium is less dense than the heat medium in the liquid state. Therefore, the vaporized heat medium rises in the heat absorbing part 35 and flows out from the outlet of the heat absorbing part 35 . The heat medium flowing out from the outlet of the heat absorbing portion 35 flows into the inlet of the heat radiating portion 36 located above the outlet. The heat medium flowing into the heat dissipation part 36 is sent to the heat absorption part 35 again.

在本實施形態，在吸熱部35及散熱部36，係如上述所示，利用吸熱部35內之熱媒體與散熱部36內之熱媒體的相變，熱媒體自動循環，不需要壓縮機等之動力。吸熱部35係與蒸發器31相異，不需要壓縮機等之動力，就可吸收空氣中之熱。In this embodiment, in the heat absorbing part 35 and the heat radiating part 36, as described above, the heat medium in the heat absorbing part 35 and the heat medium in the heat radiating part 36 are used for phase change, and the heat medium is automatically circulated, and a compressor or the like is not required. the driving force. The heat absorbing part 35 is different from the evaporator 31, and can absorb the heat in the air without the power of a compressor or the like.

圖4係在模式上表示實施形態1的框體之內部之風路的圖。圖4係相當於在模式上表示圖2之剖面圖的一部分。參照圖2及圖4，更詳細地說明在框體10之內部所形成的風路及在該風路所配置之各元件的構成。FIG. 4 is a diagram schematically showing an air passage inside the casing of Embodiment 1. FIG. FIG. 4 corresponds to a part of the cross-sectional view schematically showing FIG. 2 . 2 and 4, the air passage formed inside the casing 10 and the configuration of each element arranged in the air passage will be described in more detail.

如圖2及圖4所示，蒸發器31、第1凝結器33a、第2凝結器33b、吸熱部35以及散熱部36係被配置於從吸入口11往吹出口12相通的風路。在本實施形態，蒸發器31、第1凝結器33a、第2凝結器33b、吸熱部35以及散熱部36係被配置於送風風扇21與吸入口11之間。又，吸熱部35、蒸發器31、散熱部36、第2凝結器33b以及第1凝結器33a係作為一例，從後方往前方按照此順序排列。As shown in FIGS. 2 and 4 , the evaporator 31 , the first condenser 33 a , the second condenser 33 b , the heat absorption part 35 , and the heat dissipation part 36 are arranged in the air passage that communicates from the suction port 11 to the air outlet 12 . In the present embodiment, the evaporator 31 , the first condenser 33 a , the second condenser 33 b , the heat absorption part 35 and the heat dissipation part 36 are arranged between the blower fan 21 and the suction port 11 . In addition, the heat absorption part 35, the evaporator 31, the heat radiation part 36, the 2nd condenser 33b, and the 1st condenser 33a are an example, and are arranged in this order from the back to the front.

第1凝結器33a係被配置於送風風扇21之上風側。作為一例，第1凝結器33a係與送風風扇21鄰接。又，第2凝結器33b係被配置於第1凝結器33a之上游側。在本實施形態，第1凝結器33a與第2凝結器33b係在相鄰之狀態所排列。The first condenser 33a is arranged on the windward side of the blower fan 21 . As an example, the first condenser 33a is adjacent to the blower fan 21 . Moreover, the 2nd condenser 33b is arrange|positioned on the upstream side of the 1st condenser 33a. In the present embodiment, the first condenser 33a and the second condenser 33b are arranged in an adjacent state.

在與送風風扇21鄰接之第1凝結器33a的上風側，係有預設之尺寸的間隙。在本揭示，係將此間隙稱為混合空間41。即，混合空間41係在從吸入口11往吹出口12相通的風路，被形成於第1凝結器33a的上游側。On the windward side of the first condenser 33a adjacent to the blower fan 21, there is a gap of a predetermined size. In the present disclosure, this gap is referred to as the mixing space 41 . That is, the mixing space 41 is formed on the upstream side of the first condenser 33a in the air passage that communicates from the suction port 11 to the air outlet 12.

混合空間41係在從吸入口11往吹出口12相通的風路，被形成於散熱部36的下游側。即，混合空間41係被形成於散熱部36與第1凝結器33a之間。又，在本實施形態，第2凝結器33b位於散熱部36與第1凝結器33a之間，混合空間41係亦是位於第1凝結器33a與第2凝結器33b之間的空間。The mixing space 41 is formed on the downstream side of the heat dissipation portion 36 in the air passage that communicates from the suction port 11 to the air outlet 12 . That is, the mixing space 41 is formed between the heat dissipation part 36 and the first condenser 33a. Moreover, in this embodiment, the 2nd condenser 33b is located between the radiator part 36 and the 1st condenser 33a, and the mixing space 41 is also the space located between the 1st condenser 33a and the 2nd condenser 33b.

在從吸入口11往吹出口12相通的風路，包含第1風路及第2風路。在框體10之內部，係形成此第1風路及第2風路。第1風路係以藉送風風扇21在框體10之內部所取入的空氣之一部分依序通過吸熱部35、蒸發器31以及散熱部36並被送往混合空間41的方式所形成的風路。第2風路係以藉送風風扇21在框體10之內部所取入的空氣之剩下的部分不經由吸熱部35、蒸發器31以及散熱部36地被送往該混合空間41的方式所形成的風路。The air passage that communicates from the suction port 11 to the air outlet 12 includes a first air passage and a second air passage. Inside the casing 10, the first air passage and the second air passage are formed. The first air passage is an air formed so that a part of the air taken in by the blower fan 21 inside the casing 10 passes through the heat absorption part 35 , the evaporator 31 and the heat dissipation part 36 in this order and is sent to the mixing space 41 . road. The second air passage is formed so that the remaining part of the air taken in by the blower fan 21 inside the casing 10 is sent to the mixing space 41 without passing through the heat absorption part 35 , the evaporator 31 and the heat dissipation part 36 . formed wind path.

在本實施形態，在框體10之內部，係形成是第1風路之一例的除濕風路42。在框體10之內部，係形成是第2風路之一例的旁通風路43。如圖2及圖4所示，除濕風路42及旁通風路43係分別是從吸入口11往混合空間41相通的風路。In the present embodiment, a dehumidification air duct 42 which is an example of the first air duct is formed inside the housing 10 . Inside the casing 10, a bypass air passage 43, which is an example of the second air passage, is formed. As shown in FIGS. 2 and 4 , the dehumidification air passage 42 and the bypass air passage 43 are air passages that communicate from the suction port 11 to the mixing space 41, respectively.

除濕風路42係以藉送風風扇21在框體10之內部所取入的空氣之一部分依序通過吸熱部35、蒸發器31、散熱部36、第2凝結器33b以及第1凝結器33a的方式所形成。吸熱部35、蒸發器31、散熱部36以及第2凝結器33b係被配置於此除濕風路42。除濕風路42係從吸入口11，經由吸熱部35、蒸發器31、散熱部36以及第2凝結器33b，至往混合空間41。The dehumidification air duct 42 passes through the heat absorption part 35 , the evaporator 31 , the heat dissipation part 36 , the second condenser 33 b and the first condenser 33 a in this order by part of the air taken in by the blower fan 21 inside the casing 10 . way formed. The heat absorption part 35 , the evaporator 31 , the heat dissipation part 36 , and the second condenser 33 b are arranged in this dehumidification air passage 42 . The dehumidification air duct 42 goes from the suction port 11 to the mixing space 41 via the heat absorption part 35 , the evaporator 31 , the heat dissipation part 36 , and the second condenser 33 b .

旁通風路43係以藉送風風扇21在框體10之內部所取入的空氣之剩下的部分不經由吸熱部35、蒸發器31、散熱部36以及第2凝結器33b地通過第1凝結器33a的方式所形成。旁通風路43係以繞過吸熱部35、蒸發器31、散熱部36以及第2凝結器33b的方式所形成。旁通風路43係從吸入口11，不經由蒸發器31、散熱部36以及第2凝結器33b地至往混合空間41。The bypass passage 43 passes the remaining part of the air taken in by the blower fan 21 into the casing 10 through the first condensing part without passing through the heat absorbing part 35, the evaporator 31, the radiating part 36 and the second condenser 33b. formed in the manner of the device 33a. The bypass passage 43 is formed so as to bypass the heat absorption part 35, the evaporator 31, the heat dissipation part 36, and the second condenser 33b. The bypass passage 43 goes from the suction port 11 to the mixing space 41 without going through the evaporator 31 , the heat dissipation part 36 , and the second condenser 33 b .

是第1風路之一例的除濕風路42與是第2風路之一例的旁通風路43係藉任意的方法所形成。例如，在框體10之內部，係設置劃分除濕風路42與旁通風路43之隔開構件50。隔開構件50係例如是平板狀的構件。隔開構件50係被配置於吸熱部35、蒸發器31、散熱部36以及第2凝結器33b之上部。隔開構件50係被固定於框體10。The dehumidifying air passage 42 which is an example of the first air passage and the bypass air passage 43 which is an example of the second air passage are formed by an arbitrary method. For example, in the inside of the housing|casing 10, the partition member 50 which divides the dehumidification air passage 42 and the bypass air passage 43 is provided. The partition member 50 is, for example, a flat plate-shaped member. The partition member 50 is arrange|positioned at the upper part of the heat absorption part 35, the evaporator 31, the heat radiation part 36, and the 2nd condenser 33b. The partition member 50 is fixed to the frame body 10 .

在本實施形態，除濕風路42係被形成於此隔開構件50的下方。旁通風路43係被形成於隔開構件50的上方。在本實施形態，旁通風路43係被形成於吸熱部35、蒸發器31、散熱部36以及第2凝結器33b的上方。In the present embodiment, the dehumidification air passage 42 is formed below the partition member 50 . The bypass passage 43 is formed above the partition member 50 . In this embodiment, the bypass passage 43 is formed above the heat absorption part 35, the evaporator 31, the heat dissipation part 36, and the second condenser 33b.

本實施形態之除濕風路42及旁通風路43係由框體10與隔開構件50所形成。此外，亦可框體10與隔開構件50係一體地形成。又，除濕風路42及旁通風路43係如上述所示，藉任意的方法形成即可。亦可在框體10之內部，係未設置隔開構件50。亦可除濕風路42及旁通風路43係由與框體10及隔開構件50係不同的構件所形成。The dehumidification air duct 42 and the bypass air duct 43 in this embodiment are formed by the frame body 10 and the partition member 50 . In addition, the frame body 10 and the partition member 50 may be integrally formed. In addition, the dehumidification air duct 42 and the bypass air duct 43 may be formed by any method as described above. The partition member 50 may not be provided inside the frame body 10 . The dehumidification air duct 42 and the bypass air duct 43 may be formed by members different from the frame body 10 and the partition member 50 .

其次，說明本實施形態之除濕機1的動作。圖4中之箭號係表示除濕機1動作時之空氣的流動。Next, the operation of the dehumidifier 1 of the present embodiment will be described. The arrows in FIG. 4 indicate the flow of air when the dehumidifier 1 operates.

除濕機1係藉由送風風扇21轉動而動作。如上述所示，除濕機1係例如在室內所使用。送風風扇21轉動時，發生從吸入口11往吹出口12的氣流。 藉 送風風扇21產生氣流，藉此，從吸入口11向框體10之內部取入室內之空氣A1。The dehumidifier 1 operates when the blower fan 21 rotates. As mentioned above, the dehumidifier 1 is used indoors, for example. When the blower fan 21 is rotated, an air flow from the suction port 11 to the air outlet 12 is generated. The air A1 in the room is taken in from the suction port 11 to the inside of the casing 10 by generating an air flow by the blower fan 21.

向框體10之內部所取入之室內的空氣A1係分支至除濕風路42與旁通風路43。是空氣A1之一部分的第1空氣A2係被導向除濕風路42。又，是空氣A1之剩下的部分的第2空氣A3係被導向旁通風路43。第2空氣A3係向框體10之內部所取入的空氣A1中，被導向除濕風路42之第1空氣A2以外的部分。The indoor air A1 taken into the casing 10 is branched to the dehumidification air duct 42 and the bypass air duct 43 . The first air A2 that is a part of the air A1 is guided to the dehumidification air passage 42 . In addition, the second air A3 which is the remainder of the air A1 is guided to the bypass passage 43 . The second air A3 is guided to a portion other than the first air A2 of the dehumidification air passage 42 among the air A1 taken into the casing 10 .

被導向除濕風路42之第1空氣A2係通過吸熱部35。通過吸熱部35之第1空氣A2與在該吸熱部35流動的熱媒體之間進行熱交換。在吸熱部35，係如上述所示，在散熱部36所冷卻之熱媒體流動。在吸熱部35，係比向框體10之內部所取入之空氣A1更低溫的熱媒體流動。在吸熱部35流動之熱媒體係從通過該吸熱部35的第1空氣A2吸收熱。結果，已通過吸熱部35之第1空氣A2的溫度降低。依此方式，吸熱部35係將第1空氣A2在通過蒸發器31之前預冷。第1空氣A2之相對溫度係在通過吸熱部35之後比在通過吸熱部35之前更高。換言之，吸熱部35係藉由將第1空氣A2預冷，提高第1空氣A2的相對溫度。The first air A2 guided to the dehumidifying air duct 42 passes through the heat absorption portion 35 . Heat exchange is performed between the first air A2 passing through the heat absorbing portion 35 and the heat medium flowing through the heat absorbing portion 35 . In the heat absorbing portion 35, as described above, the heat medium cooled by the heat radiating portion 36 flows. In the heat absorbing portion 35 , a heat medium having a lower temperature than the air A1 taken into the casing 10 flows. The heat medium flowing in the heat absorption part 35 absorbs heat from the first air A2 passing through the heat absorption part 35 . As a result, the temperature of the first air A2 that has passed through the heat absorbing portion 35 is lowered. In this way, the heat absorption part 35 pre-cools the first air A2 before passing through the evaporator 31 . The relative temperature of the first air A2 is higher after passing through the heat sink 35 than before passing through the heat sink 35 . In other words, the heat absorption part 35 raises the relative temperature of the 1st air A2 by precooling the 1st air A2.

藉吸熱部35所預冷之第1空氣A2係通過蒸發器31。通過蒸發器31之第1空氣A2與在該蒸發器31流動的熱媒體之間進行熱交換。在蒸發器31，係如上述所示，藉降壓裝置34所降壓之熱媒體流動。在蒸發器31，係比藉吸熱部35所預冷之第1空氣A2更低溫的熱媒體流動。在蒸發器31流動之熱媒體係從通過該蒸發器31的第1空氣A2吸收熱。The first air A2 precooled by the heat absorption part 35 passes through the evaporator 31 . Heat exchange is performed between the first air A2 passing through the evaporator 31 and the heat medium flowing through the evaporator 31 . In the evaporator 31, as described above, the heat medium depressurized by the depressurizing device 34 flows. In the evaporator 31 , a heat medium having a lower temperature than the first air A2 precooled by the heat absorption part 35 flows. The heat medium flowing in the evaporator 31 absorbs heat from the first air A2 passing through the evaporator 31 .

通過蒸發器31之第1空氣A2係被在該蒸發器31流動的熱媒體吸熱。通過蒸發器31之第1空氣A2係被在蒸發器31流動的熱媒體冷卻。因被冷卻之第1空氣A2的溫度達到露點，在蒸發器31發生結露。即，第1空氣A2所含的水分凝結。所凝結之水分係從第1空氣A2被除去。從第1空氣A2所除去之水分係例如被貯存於貯水槽13。The first air A2 passing through the evaporator 31 absorbs heat by the heat medium flowing in the evaporator 31 . The first air A2 passing through the evaporator 31 is cooled by the heat medium flowing in the evaporator 31 . When the temperature of the cooled first air A2 reaches the dew point, dew condensation occurs in the evaporator 31 . That is, the moisture contained in the 1st air A2 condenses. The condensed water is removed from the first air A2. The water system removed from the 1st air A2 is stored in the water storage tank 13, for example.

除濕機1係依此方式除去空氣中的水分，即進行除濕。如上述所示，第1空氣A2係在通過蒸發器31之前被預冷。第1空氣A2係在通過蒸發器31之前預先成為相對溫度高的狀態。藉此，可使在蒸發器31的除濕量增大。若依據本實施形態，可得到除濕量比未搭載熱管之除濕機優異的除濕機1。若依據本實施形態，例如，可減少在蒸發器31之每單位除濕量的耗電力。The dehumidifier 1 removes moisture in the air in this way, that is, dehumidifies. As described above, the first air A2 is pre-cooled before passing through the evaporator 31 . Before passing through the evaporator 31, the first air A2 is in a state with a relatively high temperature. Thereby, the amount of dehumidification in the evaporator 31 can be increased. According to this embodiment, the dehumidifier 1 which is excellent in the dehumidification quantity compared with the dehumidifier which is not equipped with a heat pipe can be obtained. According to this embodiment, for example, the power consumption per unit dehumidification amount in the evaporator 31 can be reduced.

在蒸發器31所冷卻之第1空氣A2係往散熱部36。從蒸發器31往散熱部36之第1空氣A2係溫度比從吸入口11往吸熱部35之第1空氣A2更低。藉蒸發器31已除去水分的第1空氣A2係通過散熱部36。在通過散熱部36之第1空氣A2與在該散熱部36流動的熱媒體之間進行熱交換。在散熱部36流動的熱媒體係被通過該散熱部36之第1空氣A2冷卻。又，已通過散熱部36之第1空氣A2係成為比通過散熱部36之前的第1空氣A2更高溫。The first air A2 cooled by the evaporator 31 is directed to the heat sink 36 . The temperature of the first air A2 from the evaporator 31 to the heat dissipation part 36 is lower than that of the first air A2 from the suction port 11 to the heat absorption part 35 . The first air A2 from which moisture has been removed by the evaporator 31 passes through the heat dissipation portion 36 . Heat exchange is performed between the first air A2 passing through the heat dissipation portion 36 and the heat medium flowing through the heat dissipation portion 36 . The heat medium flowing in the heat dissipation part 36 is cooled by the first air A2 passing through the heat dissipation part 36 . Moreover, the 1st air A2 which has passed the heat dissipation part 36 becomes higher temperature than the 1st air A2 before passing through the heat dissipation part 36.

通過散熱部36之第1空氣A2係被在該散熱部36流動之熱媒體加熱。在散熱部36所加熱之空氣係往第2凝結器33b。在散熱部36所加熱之空氣係通過第2凝結器33b。在通過第2凝結器33b之第1空氣A2與在該第2凝結器33b流動的熱媒體之間進行熱交換。在第2凝結器33b流動的熱媒體係被通過該第2凝結器33b之第1空氣A2冷卻。The first air A2 passing through the heat dissipation portion 36 is heated by the heat medium flowing in the heat dissipation portion 36 . The air heated by the radiator 36 is directed to the second condenser 33b. The air heated by the radiator 36 passes through the second condenser 33b. Heat exchange is performed between the first air A2 passing through the second condenser 33b and the heat medium flowing through the second condenser 33b. The heat medium flowing through the second condenser 33b is cooled by the first air A2 passing through the second condenser 33b.

通過第2凝結器33b之第1空氣A2係被在該第2凝結器33b流動之熱媒體加熱。已通過第2凝結器33b之第1空氣A2係至往混合空間41。依此方式，被導向除濕風路42之第1空氣A2係通過吸熱部35、蒸發器31、散熱部36以及第2凝結器33b後，被送往混合空間41。The first air A2 passing through the second condenser 33b is heated by the heat medium flowing in the second condenser 33b. The first air A2 that has passed through the second condenser 33b is directed to the mixing space 41 . In this way, the first air A2 guided to the dehumidification air passage 42 is sent to the mixing space 41 after passing through the heat absorption part 35, the evaporator 31, the heat dissipation part 36, and the second condenser 33b.

又，被導向旁通風路43之第2空氣A3係如圖4所示，不會通過吸熱部35、蒸發器31、散熱部36以及第2凝結器33b地被送往混合空間41。在混合空間41，係被送入已通過除濕風路42之第1空氣A2與已通過旁通風路43之第2空氣A3。Moreover, as shown in FIG. 4, the 2nd air A3 guided to the bypass passage 43 is sent to the mixing space 41 without passing through the heat absorption part 35, the evaporator 31, the heat radiation part 36, and the 2nd condenser 33b. The mixing space 41 is fed with the first air A2 that has passed through the dehumidification air passage 42 and the second air A3 that has passed through the bypass passage 43 .

在混合空間41，係已通過除濕風路42之第1空氣A2與已通過旁通風路43之第2空氣A3被混合。藉由第1空氣A2與第2空氣A3被混合，產生混合空氣B1。混合空氣B1係如圖4所示，通過第1凝結器33a，在通過第1凝結器33a之混合空氣B1與在該第1凝結器33a流動的熱媒體之間進行熱交換。在第1凝結器33a流動的熱媒體係被通過該第1凝結器33a之混合空氣B1冷卻。In the mixing space 41, the first air A2 that has passed through the dehumidification air duct 42 and the second air A3 that has passed through the bypass duct 43 are mixed. The mixed air B1 is generated by mixing the first air A2 and the second air A3. As shown in FIG. 4, the mixed air B1 passes through the first condenser 33a, and heat exchange is performed between the mixed air B1 passing through the first condenser 33a and the heat medium flowing through the first condenser 33a. The heat medium flowing through the first condenser 33a is cooled by the mixed air B1 passing through the first condenser 33a.

通過第1凝結器33a之混合空氣B1係被在該第1凝結器33a流動之熱媒體加熱。藉由混合空氣B1被熱媒體加熱，產生乾燥空氣B2。乾燥空氣B2係比室內之空氣A1更乾燥之狀態的空氣。又，乾燥空氣B2係比室內之空氣A1更高溫。乾燥空氣B2係通過送風風扇21。已通過送風風扇21之乾燥空氣B2係從吹出口12往框體10之外部被送出。依此方式，除濕機1係向該除濕機1之外部供給乾燥空氣B2。The mixed air B1 passing through the first condenser 33a is heated by the heat medium flowing in the first condenser 33a. Dry air B2 is generated by heating the mixed air B1 by the heat medium. The dry air B2 is air in a drier state than the indoor air A1. In addition, the dry air B2 is higher in temperature than the indoor air A1. The drying air B2 is passed through the blower fan 21 . The dry air B2 that has passed through the blower fan 21 is sent out from the air outlet 12 to the outside of the casing 10 . In this way, the dehumidifier 1 supplies the dry air B2 to the outside of the dehumidifier 1 .

本實施形態之除濕機1係以在框體10之內部所取入之空氣的一部分依序通過吸熱部35、蒸發器31、散熱部36、第2凝結器33b以及第1凝結器33a的方式所構成。又，除濕機1係以在框體10之內部所取入的空氣之剩下的部分不經由吸熱部35、蒸發器31、散熱部36以及第2凝結器33b地通過第1凝結器33a的方式所構成。藉由如上述所示構成除濕機1，可在將通過蒸發器31之空氣的風量維持於高效率地進行在蒸發器31流動之熱媒體與通過蒸發器31之空氣的熱交換之適當的量下，增加通過第1凝結器33a之空氣的風量。In the dehumidifier 1 of the present embodiment, a part of the air taken in inside the casing 10 passes through the heat absorption part 35, the evaporator 31, the heat dissipation part 36, the second condenser 33b, and the first condenser 33a in this order constituted. In the dehumidifier 1, the remaining part of the air taken into the casing 10 passes through the first condenser 33a without passing through the heat absorption part 35, the evaporator 31, the heat dissipation part 36, and the second condenser 33b. way constituted. By configuring the dehumidifier 1 as described above, the air volume of the air passing through the evaporator 31 can be maintained at an appropriate amount to efficiently perform heat exchange between the heat medium flowing in the evaporator 31 and the air passing through the evaporator 31. Next, the air volume of the air passing through the first condenser 33a is increased.

在本實施形態，在框體10之內部，係形成混合空間41。在混合空間41，係藉由已通過除濕風路42之第1空氣A2與已通過旁通風路43之第2空氣A3被混合，而產生混合空氣B1。若依據本實施形態，可增加通過第1凝結器33a之空氣的風量。又，例如，變更配置隔開構件50之高度的位置，調整第1空氣A2與第2空氣A3之風量的比例，藉此，可調整通過第1凝結器33a之空氣的風量。若是本實施形態，藉由可增加通過第1凝結器33a之混合空氣B1的風量，可提高第1凝結器33a之散熱量及散熱效率。藉此，在第1凝結器33a之熱交換的效率成為更良好。In the present embodiment, a mixing space 41 is formed inside the casing 10 . In the mixing space 41, the mixed air B1 is generated by mixing the first air A2 having passed through the dehumidification air passage 42 and the second air A3 having passed through the bypass passage 43. According to this embodiment, the flow rate of the air passing through the first condenser 33a can be increased. Also, for example, the air volume of the air passing through the first condenser 33a can be adjusted by changing the position where the height of the partition member 50 is arranged and adjusting the ratio of the air volume of the first air A2 and the second air A3. According to this embodiment, since the air volume of the mixed air B1 passing through the first condenser 33a can be increased, the heat radiation amount and the heat radiation efficiency of the first condenser 33a can be improved. Thereby, the efficiency of heat exchange in the 1st condenser 33a becomes more favorable.

在旁通風路43，係未配置熱交換器等。因此，在旁通風路43之壓力損失係比除濕風路42小。若依據本實施形態，可高效率地增加通過第1凝結器33a之空氣的風量。又，在旁通風路43，係未配置使散熱部36及第2凝結器33b等之空氣升溫的熱交換器。因此，不會使混合空氣B1之溫度上升，並可增加該混合空氣B1的風量。A heat exchanger or the like is not arranged in the bypass passage 43 . Therefore, the pressure loss in the bypass air passage 43 is smaller than that in the dehumidification air passage 42 . According to this embodiment, the flow rate of the air passing through the first condenser 33a can be increased efficiently. Moreover, in the bypass passage 43, the heat exchanger which raises the temperature of the air of the heat radiation part 36, the 2nd condenser 33b, etc. is not arrange|positioned. Therefore, the air volume of the mixed air B1 can be increased without raising the temperature of the mixed air B1.

又，本實施形態之除濕機1係包括第1凝結器33a與第2凝結器33b。藉由除濕機1具有複數個凝結器，在冷凍循環之熱媒體的凝結溫度降低。藉此，在冷凍循環之凝結壓力變低，而凝結壓力與蒸發壓力的差變小。藉由凝結壓力與蒸發壓力的差變小，壓縮機32之負載被減輕，而耗電力變少。Moreover, the dehumidifier 1 of this embodiment is equipped with the 1st condenser 33a and the 2nd condenser 33b. Since the dehumidifier 1 has a plurality of condensers, the condensation temperature of the heat medium in the refrigeration cycle is lowered. Thereby, the condensation pressure in the refrigeration cycle becomes lower, and the difference between the condensation pressure and the evaporation pressure becomes smaller. By reducing the difference between the condensation pressure and the evaporation pressure, the load on the compressor 32 is reduced, and the power consumption is reduced.

亦可第2凝結器33b係例如被配置於旁通風路43。藉由第2凝結器33b被設置於旁通風路43，可減少除濕風路42的厚度。藉此，可將除濕機1作成更小型。The 2nd condenser 33b may be arrange|positioned in the bypass passage 43, for example. By providing the second condenser 33b in the bypass duct 43, the thickness of the dehumidification duct 42 can be reduced. Thereby, the dehumidifier 1 can be made smaller.

如以上所示，本實施形態之除濕機1係包括被配置成隔著蒸發器之吸熱部35及散熱部36。吸熱部35與散熱部36係被熱媒體所循環之熱管連接。除濕機1係除濕量比未搭載熱管之除濕機優異。又，在除濕機1之框體10的內部，係形成混合空間41。在框體10之內部所取入的空氣之一部分係依序通過吸熱部35、蒸發器31以及散熱部36並被送往混合空間41。在框體10之內部所取入的空氣之剩下的部分係不經由吸熱部35、蒸發器31以及散熱部36地被送往混合空間。若依據上述之構成，可得到可使在蒸發器31之除濕量與第1凝結器33a之散熱效率雙全的除濕機1。As described above, the dehumidifier 1 of the present embodiment includes the heat absorbing part 35 and the heat radiating part 36 arranged across the evaporator. The heat absorption part 35 and the heat dissipation part 36 are connected by a heat pipe through which a heat medium circulates. Dehumidifier 1 series has better dehumidification capacity than dehumidifiers without heat pipes. Moreover, inside the housing|casing 10 of the dehumidifier 1, the mixing space 41 is formed. A part of the air taken in inside the casing 10 passes through the heat absorption part 35 , the evaporator 31 , and the heat dissipation part 36 in this order, and is sent to the mixing space 41 . The remainder of the air taken in inside the casing 10 is sent to the mixing space without passing through the heat absorption part 35 , the evaporator 31 , and the heat dissipation part 36 . According to the above-mentioned configuration, the dehumidifier 1 which can achieve both the dehumidification amount in the evaporator 31 and the heat dissipation efficiency of the first condenser 33a can be obtained.

亦可吸熱部35、蒸發器31、散熱部36、第1凝結器33a以及第2凝結器33b係例如各自之大概的形狀是平板狀。亦可平板狀之吸熱部35、蒸發器31以及散熱部36係具有最大面積之面被配置成與第1空氣A2之流動方向正交。平板狀之吸熱部35、蒸發器31以及散熱部36係作為一例，被配置成彼此平行。又，亦可平板狀第1凝結器33a及第2凝結器33b係被配置成對平板狀之吸熱部35、蒸發器31以及散熱部36平行。The heat absorption part 35, the evaporator 31, the heat dissipation part 36, the 1st condenser 33a, and the 2nd condenser 33b may be, for example, the approximate shape of each may be a flat plate shape. The flat plate-shaped heat absorbing portion 35, the evaporator 31, and the heat radiating portion 36 may be arranged so as to be orthogonal to the flow direction of the first air A2 on the surface having the largest area. The flat plate-shaped heat absorption portion 35 , the evaporator 31 , and the heat dissipation portion 36 are arranged parallel to each other as an example. In addition, the plate-shaped first condenser 33a and the second condenser 33b may be arranged in parallel to the plate-shaped heat absorption part 35 , the evaporator 31 , and the heat dissipation part 36 .

第1凝結器33a係從第2凝結器33b在第1方向僅相距固定距離。亦可第1凝結器33a與第2凝結器33b之間隔係被形成為比吸熱部35與蒸發器31之間隔、蒸發器31與散熱部36之間隔以及散熱部36與第2凝結器33b之間隔大。亦可第1凝結器33a與第2凝結器33b之間的間隙之沿著第1方向的尺寸係比吸熱部35與蒸發器31之間的間隙之沿著第1方向的尺寸、蒸發器31與散熱部36之間的間隙之沿著第1方向的尺寸以及散熱部36與第2凝結器33b之間的間隙之沿著第1方向的尺寸更大。亦可混合空間41係被形成為比在吸熱部35與蒸發器31之間所形成的間隙、在蒸發器31與散熱部36之間所形成的間隙以及在散熱部36與第2凝結器33b之間所形成的間隙更寬廣。The first condenser 33a is separated from the second condenser 33b by a fixed distance in the first direction. The space between the first condenser 33a and the second condenser 33b may be formed to be larger than the space between the heat absorption part 35 and the evaporator 31, the space between the evaporator 31 and the heat dissipation part 36, and the space between the heat dissipation part 36 and the second condenser 33b. The interval is large. The dimension along the first direction of the gap between the first condenser 33a and the second condenser 33b may be larger than the dimension along the first direction of the gap between the heat absorption part 35 and the evaporator 31, and the evaporator 31 The dimension along the first direction of the gap with the heat dissipation part 36 and the dimension along the first direction of the gap between the heat dissipation part 36 and the second condenser 33b are larger. The mixing space 41 may be formed to be larger than the gap formed between the heat absorption part 35 and the evaporator 31 , the gap formed between the evaporator 31 and the heat dissipation part 36 , and the gap between the heat dissipation part 36 and the second condenser 33 b The gap formed between them is wider.

藉由混合空間41的體積被形成為更寬廣，藉該混合空間41引入很多第2空氣A3，第1空氣A2與第2空氣A3更均勻地被混合。藉此，混合空氣B1之溫度分布成為更均勻。藉由混合空氣B1之溫度分布成為均勻，在第1凝結器33a流動之熱媒體係被該混合空氣B1高效率地冷卻。在第1凝結器33a之熱交換的效率成為更良好。Since the volume of the mixing space 41 is made wider, a large amount of the second air A3 is introduced through the mixing space 41, and the first air A2 and the second air A3 are mixed more uniformly. Thereby, the temperature distribution of the mixed air B1 becomes more uniform. By making the temperature distribution of the mixed air B1 uniform, the heat medium flowing in the first condenser 33a is efficiently cooled by the mixed air B1. The efficiency of heat exchange in the first condenser 33a becomes more favorable.

在本實施形態，藉由在混合空間41第1空氣A2與第2空氣A3被混合，產生與室內之空氣A1之溫差小的混合空氣B1及乾燥空氣B2。而且，從吹出口12吹出與室內之空氣A1之溫差小的乾燥空氣B2。因此，不會吹出太低溫之空氣或太高溫之空氣。若依據本實施形態，減輕除濕機1之使用者所感覺的不舒服。In the present embodiment, by mixing the first air A2 and the second air A3 in the mixing space 41, the mixed air B1 and the dry air B2 having a small temperature difference with the indoor air A1 are generated. Then, the dry air B2 having a small temperature difference with the indoor air A1 is blown out from the air outlet 12 . Therefore, air that is too low temperature or air that is too high is not blown out. According to this embodiment, the discomfort felt by the user of the dehumidifier 1 is reduced.

在上述之實施形態，在第1凝結器33a，係混合空氣B1通過。混合空氣B1係由已通過除濕風路42之第1空氣A2與已通過旁通風路43之第2空氣A3所匯流者。亦可框體10之內部係構成為通過第1凝結器33a之混合空氣B1的風量比通過除濕風路42內之吸熱部35、蒸發器31以及散熱部36之第1空氣A2的風量更多。例如，亦可框體10之內部係構成為由第1空氣A2與第2空氣A3所匯流之混合空氣B1的全部通過第1凝結器33a。藉此，不增加通過蒸發器31之空氣的風量，亦可使通過第1凝結器33a之空氣的風量成為更多。藉由通過第1凝結器33a之空氣的風量成為更多，該第1凝結器33a之散熱量增加，而熱交換效率成為更良好。又，能以適合除濕的量維持通過蒸發器31之空氣的風量，而該蒸發器31可將對空氣除濕之性能保持於良好的狀態。此外，亦可在框體10，係不僅形成吸入口11，而且另外形成在該框體10之內部取入空氣的開口。此開口係構成為通過第1凝結器33a之空氣的風量比通過吸熱部35、蒸發器31以及散熱部36之空氣的風量更多。In the above-mentioned embodiment, the mixed air B1 passes through the first condenser 33a. The mixed air B1 is a confluence of the first air A2 having passed through the dehumidification air passage 42 and the second air A3 having passed through the bypass passage 43 . The inside of the casing 10 may be configured such that the air volume of the mixed air B1 passing through the first condenser 33 a is greater than the air volume of the first air A2 passing through the heat absorption part 35 , the evaporator 31 and the heat dissipation part 36 in the dehumidification air passage 42 . . For example, the inside of the housing|casing 10 may be comprised so that all the mixed air B1 which merged by the 1st air A2 and the 2nd air A3 may pass the 1st condenser 33a. Thereby, it is possible to increase the air volume of the air passing through the first condenser 33a without increasing the volume of the air passing through the evaporator 31 . By increasing the air volume of the air passing through the first condenser 33a, the heat radiation amount of the first condenser 33a increases, and the heat exchange efficiency becomes better. In addition, the air volume of the air passing through the evaporator 31 can be maintained at an amount suitable for dehumidification, and the evaporator 31 can maintain the performance of dehumidifying the air in a good state. Further, not only the suction port 11 but also an opening for taking in air inside the casing 10 may be formed separately in the casing 10 . This opening is configured so that the air volume of the air passing through the first condenser 33 a is larger than that of the air passing through the heat absorption part 35 , the evaporator 31 , and the heat dissipation part 36 .

如圖2及圖4所示，亦可第1凝結器33a之大小係第2凝結器33b之大小相異。藉此，可分別調整在第1凝結器33a之熱交換量與在第2凝結器33b之熱交換量。又，可將已通過除濕風路42之第1空氣A2的溫度與在混合空間所產生之混合空氣B1的溫度設定成更適當的溫度。例如，可在混合空間41得到更低溫的混合空氣B1。若利用低溫的混合空氣B1，可在第1凝結器33a高效率地冷卻熱媒體，而可提高在第1凝結器33a之熱交換效率。As shown in FIGS. 2 and 4, the size of the first condenser 33a may be different from the size of the second condenser 33b. Thereby, the amount of heat exchange in the first condenser 33a and the amount of heat exchange in the second condenser 33b can be adjusted separately. In addition, the temperature of the first air A2 that has passed through the dehumidification air duct 42 and the temperature of the mixed air B1 generated in the mixing space can be set to more appropriate temperatures. For example, a lower temperature mixed air B1 can be obtained in the mixing space 41 . By using the low-temperature mixed air B1, the heat medium can be efficiently cooled in the first condenser 33a, and the heat exchange efficiency in the first condenser 33a can be improved.

又，亦可第1凝結器33a係如圖2及圖4所示，被形成為比吸熱部35、蒸發器31、散熱部36以及第2凝結器33b更大。藉此，旁通風路43之體積成為更大。又，例如，即使藉隔開構件50從旁通風路43未完全地遮斷在吸熱部35、蒸發器31以及散熱部36流動的空氣，亦可確保第2空氣A3的風量。依此方式，藉由第1凝結器33a被形成為比吸熱部35、蒸發器31、散熱部36以及第2凝結器33b更大，不需要隔開構件50等，就可在框體10之內部形成旁通風路43。In addition, as shown in FIGS. 2 and 4 , the first condenser 33a may be formed larger than the heat absorption part 35, the evaporator 31, the heat dissipation part 36, and the second condenser 33b. Thereby, the volume of the bypass passage 43 becomes larger. Also, for example, even if the air flowing through the heat absorption part 35 , the evaporator 31 , and the heat dissipation part 36 is not completely blocked from the bypass passage 43 by the partition member 50 , the air volume of the second air A3 can be ensured. In this way, since the first condenser 33a is formed to be larger than the heat absorption portion 35, the evaporator 31, the heat dissipation portion 36, and the second condenser 33b, the partition member 50 and the like are not required, so that the space between the frame body 10 can be formed. A bypass passage 43 is formed inside.

如圖2及圖4所示，在框體10被放置於水平面的狀態，亦可第1凝結器33a的上端係位於比吸熱部35、蒸發器31以及散熱部36之各自的上端更上方。藉此，可將旁通風路43配置於吸熱部35、蒸發器31以及散熱部36的上方。又，亦可第1凝結器33a的上端係位於比第2凝結器33b的上端更上方。藉此，可將旁通風路43配置於第2凝結器33b的上方。As shown in FIGS. 2 and 4 , the upper end of the first condenser 33a may be positioned above the respective upper ends of the heat absorption part 35 , the evaporator 31 and the heat dissipation part 36 when the frame body 10 is placed on a horizontal surface. Thereby, the bypass passage 43 can be arranged above the heat absorption part 35 , the evaporator 31 , and the heat dissipation part 36 . Moreover, the upper end of the 1st condenser 33a may be located above the upper end of the 2nd condenser 33b. Thereby, the bypass passage 43 can be arrange|positioned above the 2nd condenser 33b.

在被配置於吸熱部35、蒸發器31以及散熱部36之上方的旁通風路43，係連接蒸發器31、壓縮機32、第1凝結器33a、第2凝結器33b以及降壓裝置34的配管、與連接吸熱部35及散熱部36的配管不存在。藉由在旁通風路43無障礙物，調整在該旁通風路43流動之空氣的風量成為更容易。又，減少在旁通風路43之壓力損失。The bypass passage 43 arranged above the heat absorption part 35 , the evaporator 31 , and the heat dissipation part 36 is connected to the evaporator 31 , the compressor 32 , the first condenser 33 a , the second condenser 33 b , and the pressure reducing device 34 . There are no pipes and pipes connecting the heat absorption part 35 and the heat dissipation part 36 . Since there are no obstacles in the bypass passage 43 , it becomes easier to adjust the air volume of the air flowing in the bypass passage 43 . In addition, the pressure loss in the bypass passage 43 is reduced.

除濕機1係作為一例，亦可構成為已通過除濕風路42之第1空氣A2的溫度和已通過旁通風路43之第2空氣A3的溫度相同或比其高溫。在此情況，在混合空間41，可藉第2空氣A3降低第1空氣A2的溫度。即，產生更低溫的混合空氣B1。藉由更低溫的混合空氣B1通過第1凝結器33a，該第1凝結器33a之散熱效率成為更佳。As an example, the dehumidifier 1 may be configured such that the temperature of the first air A2 that has passed through the dehumidification air duct 42 and the temperature of the second air A3 that has passed through the bypass duct 43 are the same or higher. In this case, in the mixing space 41, the temperature of the first air A2 can be lowered by the second air A3. That is, lower temperature mixed air B1 is generated. By passing the lower temperature mixed air B1 through the first condenser 33a, the heat dissipation efficiency of the first condenser 33a becomes better.

圖5係表示實施形態1之除濕機1之第1變形例的圖。圖6係表示實施形態1之除濕機1之第2變形例的圖。如圖5及圖6所示，亦可除濕機1係不具有第2凝結器33b。亦可除濕機1係具有一台除濕機1。FIG. 5 is a diagram showing a first modification of the dehumidifier 1 according to the first embodiment. FIG. 6 is a diagram showing a second modification of the dehumidifier 1 according to the first embodiment. As shown in FIGS. 5 and 6 , the dehumidifier 1 may not include the second condenser 33b. The dehumidifier 1 may also have one dehumidifier 1 .

在圖5及圖6所示之變形例，第1凝結器33a係從散熱部36在第1方向僅相距固定距離。在圖5及圖6所示之變形例，混合空間41係作為第1凝結器33a與散熱部36之間的間隙所形成的空間。亦可第1凝結器33a與散熱部36之間隔係被形成為比吸熱部35與蒸發器31之間隔及蒸發器31與散熱部36之間隔大。亦可第1凝結器33a與散熱部36之間的間隙之沿著第1方向的尺寸係比吸熱部35與蒸發器31之間的間隙之沿著第1方向的尺寸及蒸發器31與散熱部36之間的間隙之沿著第1方向的尺寸更大。亦可混合空間41係被形成為比在吸熱部35與蒸發器31之間所形成的間隙及在蒸發器31與散熱部36之間所形成的間隙更寬廣。In the modification shown in FIGS. 5 and 6 , the first condenser 33 a is spaced from the heat dissipation portion 36 by a fixed distance in the first direction. In the modification shown in FIGS. 5 and 6 , the mixing space 41 is a space formed as a gap between the first condenser 33 a and the heat dissipation portion 36 . The interval between the first condenser 33 a and the heat dissipation portion 36 may be formed to be larger than the interval between the heat absorption portion 35 and the evaporator 31 and the interval between the evaporator 31 and the heat dissipation portion 36 . The dimension along the first direction of the gap between the first condenser 33a and the heat dissipation part 36 may be greater than the dimension along the first direction of the gap between the heat absorption part 35 and the evaporator 31 and the dimension between the evaporator 31 and the heat dissipation part. The size of the gap between the parts 36 along the first direction is larger. The mixing space 41 may be formed wider than the gap formed between the heat absorption part 35 and the evaporator 31 and the gap formed between the evaporator 31 and the heat dissipation part 36 .

又，如圖5所示，亦可第1凝結器33a係例如被形成為比吸熱部35、蒸發器31以及散熱部36更大。如圖6所示，亦可吸熱部35、蒸發器31、散熱部36以及第1凝結器33a係彼此同程度的大小。亦可旁通風路43係如圖6所示，藉由在彼此錯開的狀態配置同程度之大小的吸熱部35、蒸發器31、散熱部36以及第1凝結器33a所形成。Moreover, as shown in FIG. 5, the 1st condenser 33a may be formed larger than the heat absorption part 35, the evaporator 31, and the heat radiation part 36, for example. As shown in FIG. 6 , the heat absorption part 35 , the evaporator 31 , the heat dissipation part 36 , and the first condenser 33 a may have the same size as each other. As shown in FIG. 6 , the bypass passage 43 may be formed by arranging the heat absorbing part 35 , the evaporator 31 , the heat radiating part 36 and the first condenser 33 a of the same size in a staggered state.

又，圖7係表示實施形態1之除濕機1之第3變形例的圖。圖7係在模式上表示在本變形例之框體10之內部的構造。圖7係與在圖1中之B－B位置的剖面圖相當的模式圖。如圖7所示，在框體10被放置於水平面的狀態，亦可第1凝結器33a的橫寬係比吸熱部35的橫寬、蒸發器31的橫寬以及散熱部36的橫寬更寬。又，在圖7係雖未圖示，亦可第1凝結器33a的橫寬係比第2凝結器33b的橫寬更寬。Moreover, FIG. 7 is a figure which shows the 3rd modification of the dehumidifier 1 of Embodiment 1. FIG. FIG. 7 schematically shows the structure inside the housing 10 of this modification. FIG. 7 is a schematic view corresponding to the cross-sectional view at the BB position in FIG. 1 . As shown in FIG. 7 , when the frame body 10 is placed on a horizontal surface, the lateral width of the first condenser 33 a may be larger than the lateral width of the heat absorption portion 35 , the lateral width of the evaporator 31 , and the lateral width of the heat dissipation portion 36 . width. In addition, although not shown in the figure in FIG. 7, the lateral width of the first condenser 33a may be wider than the lateral width of the second condenser 33b.

第1凝結器33a的橫寬係在與通過該第1凝結器33a之混合空氣B1的流動方向及鉛垂方向垂直的方向之該第1凝結器33a的尺寸。吸熱部35的橫寬係在與通過該吸熱部35之第1空氣A2的流動方向及鉛垂方向垂直的方向之該吸熱部35的尺寸。蒸發器31的橫寬係在與通過該蒸發器31之第1空氣A2的流動方向及鉛垂方向垂直的方向之該蒸發器31的尺寸。散熱部36的橫寬係在與通過該散熱部36之第1空氣A2的流動方向及鉛垂方向垂直的方向之該散熱部36的尺寸。第2凝結器33b的橫寬係在與通過該第2凝結器33b之第1空氣A2的流動方向及鉛垂方向垂直的方向之該第2凝結器33b的尺寸。The lateral width of the first condenser 33a is the dimension of the first condenser 33a in the direction perpendicular to the flow direction and the vertical direction of the mixed air B1 passing through the first condenser 33a. The lateral width of the heat absorption part 35 is the dimension of the heat absorption part 35 in the direction perpendicular to the flow direction and the vertical direction of the first air A2 passing through the heat absorption part 35 . The lateral width of the evaporator 31 is the dimension of the evaporator 31 in the direction perpendicular to the flow direction and the vertical direction of the first air A2 passing through the evaporator 31 . The lateral width of the heat dissipation portion 36 is the dimension of the heat dissipation portion 36 in the direction perpendicular to the flow direction and the vertical direction of the first air A2 passing through the heat dissipation portion 36 . The lateral width of the second condenser 33b is the dimension of the second condenser 33b in the direction perpendicular to the flow direction and the vertical direction of the first air A2 passing through the second condenser 33b.

藉由第1凝結器33a的橫寬比吸熱部35的橫寬、蒸發器31的橫寬以及散熱部36的橫寬寬，可更易於形成旁通風路43。又，如圖7所示，在吸熱部35、蒸發器31以及散熱部36之左方及右方，可形成旁通風路43。一樣地，藉由第1凝結器33a的橫寬比第2凝結器33b的橫寬寬，可在第2凝結器33b的側方易於形成旁通風路43。在吸熱部35、蒸發器31、散熱部36以及第2凝結器33b之側方所形成的旁通風路43，係遮斷空氣之流動的障礙物比除濕風路42少。藉此，在旁通風路43係高效率地引入第2空氣A3，而向混合空間41高效率地導引該第2空氣A3。又，藉由第1凝結器33a成為更大，第1凝結器33a與混合空氣B1之接觸面積增加。藉此，第1凝結器33a之散熱量增加，而該第1凝結器33a的性能成為更良好。By making the lateral width of the first condenser 33a wider than the lateral width of the heat absorption portion 35, the lateral width of the evaporator 31, and the lateral width of the heat dissipation portion 36, the bypass passage 43 can be formed more easily. Further, as shown in FIG. 7 , bypass passages 43 may be formed on the left and right sides of the heat absorption portion 35 , the evaporator 31 , and the heat dissipation portion 36 . Similarly, since the lateral width of the first condenser 33a is wider than the lateral width of the second condenser 33b, the bypass passage 43 can be easily formed on the side of the second condenser 33b. The bypass duct 43 formed on the sides of the heat absorbing part 35 , the evaporator 31 , the heat radiating part 36 and the second condenser 33 b has fewer obstacles than the dehumidifying air duct 42 for blocking the flow of air. As a result, the second air A3 is efficiently introduced into the bypass passage 43 , and the second air A3 is efficiently introduced into the mixing space 41 . Moreover, since the 1st condenser 33a becomes larger, the contact area of the 1st condenser 33a and the mixed air B1 increases. Thereby, the heat radiation amount of the 1st condenser 33a increases, and the performance of this 1st condenser 33a becomes more favorable.

圖8係表示實施形態1之除濕機1之第4變形例的圖。如圖8所示，亦可在框體10，係替代吸入口11，形成第1開口11a及第2開口11b。第1開口11a係例如被形成於框體10之背面。第2開口11b係例如被形成於框體10之上面。第1開口11a及第2開口11b係用以從框體10之外部向內部取入空氣的開口。若依據本變形例，藉由用以從框體10之外部向內部取入空氣的開口有複數個，例如，可使通過第1凝結器33a之空氣的風量比通過蒸發器31之空氣的風量更易於變多。若依據本變形例的構成，可更易於調整第1凝結器33a之散熱量。FIG. 8 is a diagram showing a fourth modification of the dehumidifier 1 according to the first embodiment. As shown in FIG. 8 , a first opening 11 a and a second opening 11 b may be formed in the housing 10 instead of the suction port 11 . The first opening 11 a is formed on the back surface of the frame body 10 , for example. The second opening 11 b is formed on the upper surface of the frame body 10 , for example. The first opening 11 a and the second opening 11 b are openings for taking in air from the outside of the housing 10 to the inside. According to this modification, by having a plurality of openings for taking in air from the outside of the casing 10 to the inside, for example, the air volume of the air passing through the first condenser 33 a can be made higher than the air volume of the air passing through the evaporator 31 . Easier to multiply. According to the structure of this modification, the heat radiation amount of the 1st condenser 33a can be adjusted more easily.

從第1開口11a所取入的空氣係與在表示本實施形態及其變形例之各圖的第1空氣A2對應。從第1開口11a所取入的第1空氣A2係依序通過吸熱部35、蒸發器31以及散熱部36。又，從第2開口11b所取入的空氣係與在各圖的第2空氣A3對應。第2開口11b係以從第2開口11b所取入的第2空氣A3係不經由吸熱部35、蒸發器31以及散熱部36地被送往該混合空間41的方式所形成。例如，在吸熱部35、蒸發器31、散熱部36以及第1凝結器33a在水平方向依序排列的情況，在水平方向之第2開口11b的位置係位於散熱部36與第1凝結器33a之間。在圖8所示之變形例，亦與上述之實施形態及各變形例一樣，可將通過蒸發器31之空氣的風量與通過第1凝結器33a之空氣的風量分別調整至適當的量。又，高效率地冷卻熱媒體，而在第1凝結器33a之熱交換效率成為良好。The air taken in from the 1st opening 11a corresponds to the 1st air A2 in each figure which shows this embodiment and its modification. The first air A2 taken in from the first opening 11 a passes through the heat absorption part 35 , the evaporator 31 , and the heat dissipation part 36 in this order. In addition, the air system taken in from the 2nd opening 11b corresponds to the 2nd air A3 in each figure. The second opening 11b is formed so that the second air A3 taken in from the second opening 11b is sent to the mixing space 41 without passing through the heat absorption part 35 , the evaporator 31 and the heat dissipation part 36 . For example, when the heat absorption part 35, the evaporator 31, the heat dissipation part 36 and the first condenser 33a are arranged in order in the horizontal direction, the position of the second opening 11b in the horizontal direction is located between the heat dissipation part 36 and the first condenser 33a. between. In the modification shown in FIG. 8, the air volume of the air passing through the evaporator 31 and the air volume of the air passing through the first condenser 33a can be adjusted to appropriate amounts, respectively, as in the above-described embodiment and each modification. In addition, the heat medium is efficiently cooled, and the heat exchange efficiency in the first condenser 33a becomes good.

此外，在上述之實施形態及各變形例，亦可混合空氣B1通過第1凝結器33a時之該混合空氣B1與該第1凝結器33a的接觸面積，係比第1空氣A2通過吸熱部35時之該第1空氣A2與該吸熱部35的接觸面積、第1空氣A2通過蒸發器31時之該第1空氣A2與該蒸發器31的接觸面積以及第1空氣A2通過散熱部36時之該第1空氣A2與該散熱部36的接觸面積更大。又，亦可混合空氣B1通過第1凝結器33a時之該混合空氣B1與該第1凝結器33a的接觸面積，係比第1空氣A2通過第2凝結器33b時之該第1空氣A2與該第2凝結器33b的接觸面積更大。亦可框體10之內部係如上述所示構成。若依據本構成，在第1凝結器33a之熱媒體的散熱量增加，而更高效率地進行在第1凝結器33a之熱媒體與混合空氣B1的熱交換。In addition, in the above-mentioned embodiment and each modification, the contact area between the mixed air B1 and the first condenser 33a when the mixed air B1 passes through the first condenser 33a may be smaller than that of the first air A2 passing through the heat absorbing part 35 The contact area between the first air A2 and the heat absorbing part 35 when the first air A2 passes through the evaporator 31 , the contact area between the first air A2 and the evaporator 31 when the first air A2 passes through the evaporator 31 , and the first air A2 when passing through the heat dissipation part 36 . The contact area between the first air A2 and the heat dissipation portion 36 is larger. In addition, the contact area between the mixed air B1 and the first condenser 33a when the mixed air B1 passes through the first condenser 33a may be greater than the contact area between the first air A2 and the first air A2 when the first air A2 passes through the second condenser 33b The contact area of the second condenser 33b is larger. The inside of the housing 10 may be configured as described above. According to this configuration, the heat dissipation amount of the heat medium in the first condenser 33a increases, and the heat exchange between the heat medium in the first condenser 33a and the mixed air B1 is performed more efficiently.

1:除濕機 10:框體 11:吸入口 11a:第1開口 11b:第2開口 12:吹出口 13:貯水槽 21:送風風扇 31:蒸發器 32:壓縮機 33a:第1凝結器 33b:第2凝結器 34:降壓裝置 35:吸熱部 36:散熱部 41:混合空間 42:除濕風路 43:旁通風路 50:隔開構件1: Dehumidifier 10: Frame 11: Suction port 11a: 1st opening 11b: 2nd opening 12: Blow Out 13: Water storage tank 21: Air supply fan 31: Evaporator 32: Compressor 33a: 1st condenser 33b: 2nd condenser 34: Decompression device 35: heat sink 36: heat dissipation department 41: Mixed Space 42: Dehumidification air path 43: Bypass ventilation 50: Spacer Components

[圖1]係實施形態1之除濕機的正視圖。 [圖2]係實施形態1之除濕機的剖面圖。 [圖3]係在模式上表示實施形態1之熱媒體迴路的圖。 [圖4]係在模式上表示實施形態1的框體之內部之風路的圖。 [圖5]係表示實施形態1之除濕機之第1變形例的圖。 [圖6]係表示實施形態1之除濕機之第2變形例的圖。 [圖7]係表示實施形態1之除濕機之第3變形例的圖。 [圖8]係表示實施形態1之除濕機之第4變形例的圖。1] It is a front view of the dehumidifier of Embodiment 1. [FIG. Fig. 2 is a cross-sectional view of the dehumidifier according to the first embodiment. Fig. 3 is a diagram schematically showing the heat medium circuit of the first embodiment. [ Fig. 4] Fig. 4 is a diagram schematically showing an air passage inside the casing of Embodiment 1. [Fig. [ Fig. 5] Fig. 5 is a diagram showing a first modification of the dehumidifier according to the first embodiment. 6] It is a figure which shows the 2nd modification of the dehumidifier of Embodiment 1. [FIG. [ Fig. 7] Fig. 7 is a diagram showing a third modification of the dehumidifier according to the first embodiment. [ Fig. 8] Fig. 8 is a diagram showing a fourth modification of the dehumidifier according to the first embodiment.

1:除濕機 1: Dehumidifier

10:框體 10: Frame

11:吸入口 11: Suction port

12:吹出口 12: Blow Out

21:送風風扇 21: Air supply fan

31:蒸發器 31: Evaporator

33a:第1凝結器 33a: 1st condenser

35:吸熱部 35: heat sink

36:散熱部 36: heat dissipation department

41:混合空間 41: Mixed Space

42:除濕風路 42: Dehumidification air path

43:旁通風路 43: Bypass ventilation

50:隔開構件 50: Spacer Components

A1:空氣 A1: Air

A2:第1空氣 A2: 1st Air

A3:第2空氣 A3: 2nd air

B1:混合空氣 B1: mixed air

B2:乾燥空氣 B2: Dry Air

Claims (15)

一種除濕機，係：包括：熱媒體所通過之蒸發器；壓縮機，係壓縮通過該蒸發器之熱媒體；第1凝結器，係藉該壓縮機所壓縮之熱媒體通過；降壓裝置，係將已通過該第1凝結器之熱媒體降壓；吸熱部及散熱部，係被配置成隔著該蒸發器；框體，係在內部收容該蒸發器、該壓縮機、該第1凝結器、該吸熱部以及該散熱部；以及送風手段，係在該框體之內部取入空氣，並向該框體之外部送出所取入的空氣；該吸熱部及該散熱部係被熱媒體所循環之熱管連接；該吸熱部係被配置於該蒸發器之上風側，並冷卻藉該送風手段在該框體之內部所取入的空氣；該散熱部係被配置於該蒸發器之下風側，並對已通過該蒸發器之空氣加熱；在該框體之內部，係在該散熱部與該第1凝結器之間形成混合空間；藉該送風手段在該框體之內部所取入的空氣之一部分係依序通過該吸熱部、該蒸發器以及該散熱部並被送往該混合空間；藉該送風手段在該框體之內部所取入的空氣之剩下的部分係不經由該吸熱部、該蒸發器以及該散熱部地被送往該混合空間；該第1凝結器與該散熱部之間隔，係比該蒸發器與該散熱部之間隔及該蒸發器與該吸熱部之間隔更大。 A dehumidifier, comprising: an evaporator through which a heat medium passes; a compressor, which compresses the heat medium passing through the evaporator; a first condenser, which passes through the heat medium compressed by the compressor; a pressure reducing device, The heat medium that has passed through the first condenser is depressurized; the heat absorption part and the heat dissipation part are arranged so as to be separated from the evaporator; the frame body houses the evaporator, the compressor, and the first condenser inside. The heat sink, the heat absorbing part and the heat radiating part; and the air supply means, which take in the air inside the frame and send the taken-in air to the outside of the frame; the heat absorbing part and the heat dissipating part are heated by the heat medium The circulating heat pipes are connected; the heat absorption part is arranged on the upper wind side of the evaporator, and cools the air taken in by the air supply means inside the frame; the heat dissipation part is arranged on the evaporator On the leeward side, it heats the air that has passed through the evaporator; inside the frame, a mixing space is formed between the heat dissipation part and the first condenser; A part of the air taken in passes through the heat absorption part, the evaporator and the heat dissipation part in sequence and is sent to the mixing space; the remaining part of the air taken in by the air supply means inside the frame is It is sent to the mixing space without passing through the heat absorption part, the evaporator and the heat dissipation part; the interval between the first condenser and the heat dissipation part is greater than the interval between the evaporator and the heat dissipation part and between the evaporator and the heat dissipation part The space between the heat sinks is larger. 如申請專利範圍第1項之除濕機，其中在該框體之內部，係設置： 第1風路，係以藉該送風手段在該框體之內部所取入的空氣之一部分依序通過該吸熱部、該蒸發器以及該散熱部並被送往該混合空間的方式所形成；第2風路，係以藉該送風手段在該框體之內部所取入的空氣之剩下的部分不經由該吸熱部、該蒸發器以及該散熱部地被送往該混合空間的方式所形成。 For the dehumidifier according to item 1 of the scope of the patent application, inside the frame, there are: The first air passage is formed in such a way that a part of the air taken in by the air supply means inside the frame body passes through the heat absorption part, the evaporator and the heat dissipation part in sequence and is sent to the mixing space; The second air passage is configured so that the remaining part of the air taken in by the air supply means is sent to the mixing space without passing through the heat absorption part, the evaporator and the heat dissipation part. form. 如申請專利範圍第1或2項之除濕機，其中藉該送風手段通過該第1凝結器之空氣的風量係比藉該送風手段通過該吸熱部、該蒸發器以及該散熱部之空氣的風量更多。 The dehumidifier according to claim 1 or 2, wherein the air volume of the air passing through the first condenser by the air supply means is higher than the air volume of the air passing through the heat absorption part, the evaporator and the heat dissipation part by the air supply means More. 如申請專利範圍第1或2項之除濕機，其中藉該送風手段依序通過該吸熱部、該蒸發器以及該散熱部並被送往該混合空間之空氣的溫度係與藉該送風手段不經由該吸熱部、該蒸發器以及該散熱部地被送往該混合空間之空氣的溫度相同或比其高溫。 According to the dehumidifier of claim 1 or 2 of the scope of the application, the temperature of the air that passes through the heat absorption part, the evaporator and the heat dissipation part in sequence and is sent to the mixing space by the air supply means is different from that by the air supply means. The temperature of the air sent to the mixing space through the heat absorption part, the evaporator and the heat dissipation part is the same or higher than that. 如申請專利範圍第1或2項之除濕機，其中藉該送風手段通過該第1凝結器之空氣與該第1凝結器的接觸面積，係比藉該送風手段通過該吸熱部之空氣與該吸熱部的接觸面積、藉該送風手段通過該蒸發器之空氣與該蒸發器的接觸面積以及藉該送風手段通過該散熱部之空氣與該散熱部的接觸面積更大。 For the dehumidifier according to claim 1 or 2, the contact area between the air passing through the first condenser by the air supply means and the first condenser is greater than the contact area between the air passing through the heat absorbing part by the air supply means and the first condenser. The contact area of the heat absorbing part, the contact area of the air passing through the evaporator by the air supply means and the evaporator, and the contact area of the air passing through the heat dissipation part by the air supply means and the heat dissipation part are larger. 如申請專利範圍第1或2項之除濕機，其中在該框體被放置於水平面的狀態，該第1凝結器的上端係位於比該吸熱部的上端、該蒸發器的上端以及該散熱部的上端更上方。 The dehumidifier of claim 1 or 2, wherein in the state where the frame is placed on a horizontal plane, the upper end of the first condenser is located more than the upper end of the heat absorption part, the upper end of the evaporator and the heat dissipation part The upper end is higher. 如申請專利範圍第1或2項之除濕機，其中在該框體被放置於水平面的狀態，在與藉該送風手段通過該第1凝結器之空氣的流動方向及鉛垂方向垂直的方向之該第1凝結器的尺寸，係比在與藉該送風手段通過該吸熱部、該蒸發器以及該散熱部之空氣的流動方向及鉛垂方向垂直的方向之該吸熱部的尺寸、該蒸發器的尺寸以及該散熱部的尺寸更大。 The dehumidifier according to claim 1 or 2, wherein the frame is placed on a horizontal plane in a direction perpendicular to the flow direction and the vertical direction of the air passing through the first condenser by the air supply means. The size of the first condenser is compared with the size of the heat absorbing part in the direction perpendicular to the vertical direction and the flow direction of the air passing through the heat absorbing part, the evaporator and the heat radiating part by the blowing means, the evaporator size and the size of the heat dissipation part are larger. 如申請專利範圍第1或2項之除濕機，其中藉該送風手段通過該蒸發器並通過該散熱部之前之空氣的溫度係比藉該送風手段通過該吸熱部之前之空氣的溫度更低。 The dehumidifier as claimed in claim 1 or 2, wherein the temperature of the air before passing through the evaporator and the heat dissipation part by the air supply means is lower than the temperature of the air before passing through the heat absorption part by the air supply means. 如申請專利範圍第1或2項之除濕機，其中在該框體被放置於水平面的狀態，熱媒體進入該吸熱部之入口係位於比熱媒體從該散熱部出來的出口更下方，熱媒體從該吸熱部出來的出口係位於比熱媒體進入該散熱部之入口更下方。 According to the dehumidifier of claim 1 or 2, when the frame body is placed on a horizontal plane, the inlet of the heat medium entering the heat absorbing part is located below the outlet of the heat medium coming out of the heat radiating part, and the heat medium is discharged from the heat sink. The outlet from the heat absorption part is located below the inlet of the heat medium entering the heat dissipation part. 如申請專利範圍第1或2項之除濕機，其中更具有第2凝結器，該第2凝結器係藉該壓縮機所壓縮之熱媒體通過；該混合空間係被形成於該第1凝結器與該第2凝結器之間；藉該送風手段在該框體之內部所取入的空氣之一部分係依序通過該吸熱部、該蒸發器、該散熱部以及該第2凝結器並被送往該混合空間；藉該送風手段在該框體之內部所取入的空氣之剩下的部分係不經由該吸熱部、該蒸發器、該散熱部以及該第2凝結器地被送往該混合空間。 If the dehumidifier of claim 1 or 2 of the scope of the application is further provided with a second condenser, the second condenser passes through the heat medium compressed by the compressor; the mixing space is formed in the first condenser Between the second condenser; a part of the air taken in by the air supply means inside the frame passes through the heat absorption part, the evaporator, the heat dissipation part and the second condenser in sequence and is sent to the To the mixing space; the remaining part of the air taken in by the air supply means inside the frame is sent to the heat sink, the evaporator, the heat dissipation part and the second condenser mixed space. 如申請專利範圍第10項之除濕機，其中該第1凝結器與該第2凝結器之間隔係比該蒸發器與該散熱部之間隔、該蒸發器與該吸熱部之間隔及該散熱部與該第2凝結器之間隔更大。 The dehumidifier of claim 10, wherein the interval between the first condenser and the second condenser is greater than the interval between the evaporator and the heat dissipation part, the interval between the evaporator and the heat absorption part, and the heat dissipation part The distance from the second condenser is larger. 一種除濕機，係：包括：熱媒體所通過之蒸發器；壓縮機，係壓縮通過該蒸發器之熱媒體；第1凝結器，係藉該壓縮機所壓縮之熱媒體通過；第2凝結器，係藉該壓縮機所壓縮之熱媒體通過；降壓裝置，係將已通過該第1凝結器之熱媒體降壓； 吸熱部及散熱部，係被配置成隔著該蒸發器；框體，係在內部收容該蒸發器、該壓縮機、該第1凝結器、該吸熱部以及該散熱部；以及送風手段，係在該框體之內部取入空氣，並向該框體之外部送出所取入的空氣；該吸熱部及該散熱部係被熱媒體所循環之熱管連接；該吸熱部係被配置於該蒸發器之上風側，並冷卻藉該送風手段在該框體之內部所取入的空氣；該散熱部係被配置於該蒸發器之下風側，並對已通過該蒸發器之空氣加熱；在該框體之內部，係在該散熱部與該第1凝結器之間形成混合空間；該混合空間係被形成於該第1凝結器與該第2凝結器之間；藉該送風手段在該框體之內部所取入的空氣之一部分係依序通過該吸熱部、該蒸發器、該散熱部以及該第2凝結器並被送往該混合空間；藉該送風手段在該框體之內部所取入的空氣之剩下的部分係不經由該吸熱部、該蒸發器、該散熱部以及該第2凝結器地被送往該混合空間；該第1凝結器與該第2凝結器之間隔係比該蒸發器與該散熱部之間隔、該蒸發器與該吸熱部之間隔及該散熱部與該第2凝結器之間隔更大。 A dehumidifier, comprising: an evaporator through which a heat medium passes; a compressor, which compresses the heat medium passing through the evaporator; a first condenser, which passes through the heat medium compressed by the compressor; a second condenser , is to pass through the heat medium compressed by the compressor; the pressure-reducing device is to depressurize the heat medium that has passed through the first condenser; A heat absorbing part and a heat radiating part are arranged so as to sandwich the evaporator; a frame body houses the evaporator, the compressor, the first condenser, the heat absorbing part and the heat radiating part; and an air supply means is Air is taken in inside the frame and the taken-in air is sent out of the frame; the heat absorbing part and the heat radiating part are connected by a heat pipe circulated by a heat medium; the heat absorbing part is arranged in the evaporation upwind side of the evaporator, and cools the air taken in by the air supply means inside the frame; the heat dissipation part is arranged on the downwind side of the evaporator, and heats the air that has passed through the evaporator; Inside the frame, a mixing space is formed between the heat dissipation part and the first condenser; the mixing space is formed between the first condenser and the second condenser; A part of the air taken in from the inside of the frame passes through the heat absorption part, the evaporator, the heat dissipation part and the second condenser in sequence and is sent to the mixing space; The remaining part of the air taken in is sent to the mixing space without passing through the heat absorption part, the evaporator, the heat dissipation part and the second condenser; the first condenser and the second condenser The interval is larger than the interval between the evaporator and the heat dissipation part, the interval between the evaporator and the heat absorption part, and the interval between the heat dissipation part and the second condenser. 如申請專利範圍第12項之除濕機，其中藉該送風手段通過該第1凝結器之空氣與該第1凝結器的接觸面積，係比藉該送風手段通過該第2凝結器之空氣與該第2凝結器的接觸面積更大。 For the dehumidifier of claim 12, the contact area between the air passing through the first condenser by the air supply means and the first condenser is greater than the contact area between the air passing through the second condenser by the air supply means and the first condenser. The contact area of the second condenser is larger. 如申請專利範圍第12項之除濕機，其中在該框體被放置於水平面的狀態，該第1凝結器的上端係位於比該第2凝結器的上端更上方。 The dehumidifier according to claim 12, wherein the upper end of the first condenser is positioned above the upper end of the second condenser when the frame is placed on a horizontal plane. 如申請專利範圍第12項之除濕機，其中在該框體被放置於水平面的狀態，在與藉該送風手段通過該第1凝結器之空氣的流動方向及鉛垂方向垂 直的方向之該第1凝結器的尺寸，係比在與藉該送風手段通過該第2凝結器之空氣的流動方向及鉛垂方向垂直的方向之該第2凝結器的尺寸更大。 The dehumidifier according to claim 12, wherein in the state where the frame is placed on a horizontal plane, it is perpendicular to the flow direction and the vertical direction of the air passing through the first condenser by the air supply means The dimension of the first condenser in the vertical direction is larger than the dimension of the second condenser in the direction perpendicular to the flow direction and the vertical direction of the air passing through the second condenser by the blowing means.

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