JP2022088903A - Dehumidifier - Google Patents

Abstract

To provide a dehumidifier capable of suppressing size increase while combining desiccant type dehumidifying function with compressor type dehumidifying function.SOLUTION: A dehumidifier 100 has a dehumidifying part 110. Air is dehumidified by the dehumidifying part 110. A first heat exchanging part is included in the dehumidifying part 110. Heat is exchanged by the first heat exchanging part. The first heat exchanging part has a first flowing part 84 and a second flowing part 85. Air is flown in the first flowing part 84. A coolant is flown in the second flowing part 85. The first flowing part 84 preferably crosses the second flowing part 85. The second flowing part 85 preferably penetrates the first flowing part 84.SELECTED DRAWING: Figure 2

Description

The present invention relates to a dehumidifier.

The dehumidifier described in Patent Document 1 includes a first blower, a compressor, a condenser, a decompression device, an evaporator, a second blower, a heater, a moisture absorption rotor, and a sensible heat exchanger. The first blower sends out air. The compressor, condenser, decompressor and evaporator form a refrigeration cycle. The second blower sends air to the moisture absorbing rotor. The heater heats the air. The moisture absorption rotor absorbs moisture. The sensible heat exchanger cools the air and causes condensation. According to the dehumidifier described in Patent Document 1, a moisture absorption rotor type dehumidifier and a refrigeration cycle type dehumidifier can be combined.

Japanese Unexamined Patent Publication No. 2004-28481

However, in the dehumidifier described in Patent Document 1, since the rotor type (desiccant type) dehumidifier and the refrigeration cycle type (compressor type) dehumidifier are combined as they are, the size of the dehumidifier has been increased.

The present invention has been made in view of the above problems, and an object of the present invention is to provide a dehumidifier capable of suppressing an increase in size while combining a desiccant type dehumidifying function and a compressor type dehumidifying function.

According to one aspect of the invention, the dehumidifier comprises a dehumidifying section. The dehumidifying section dehumidifies the air. The dehumidifying section includes a first heat exchange section. The first heat exchange unit exchanges heat. The first heat exchange unit has a first distribution unit and a second distribution unit. The air circulates in the first distribution section. Refrigerant flows through the second distribution section.

According to the dehumidifier of the present invention, it is possible to suppress an increase in the size of the dehumidifier while combining the desiccant type dehumidification function and the compressor type dehumidifier function.

It is a perspective view of the dehumidifier which concerns on Embodiment 1 of this invention. It is a schematic diagram which shows the inside of the dehumidifier which concerns on this Embodiment 1. It is a figure which shows the cooling part of the dehumidifier which concerns on this Embodiment 1 in an enlarged scale. It is a figure which shows the IV-IV cross section shown in FIG. It is a figure which shows the cooling part of Embodiment 3.

An embodiment of the present invention will be described with reference to the drawings. In the figure, the same or corresponding parts are designated by the same reference numerals and the description is not repeated.

[Embodiment 1]
The dehumidifier 100 according to the first embodiment of the present invention will be described with reference to FIGS. 1 and 2. FIG. 1 is a perspective view of the dehumidifier 100 according to the first embodiment of the present invention. FIG. 2 is a schematic view showing the inside of the dehumidifier 100.

As shown in FIGS. 1 and 2, the dehumidifier 100 includes a casing 1, a cover member 2a, a drainage tank 4, and an operation unit C.

The casing 1 is a hollow member. As shown in FIG. 2, the casing 1 is formed with an air outlet 2 and a first suction port 3a.

The outlet 2 is arranged on the side of the casing 1 in the first direction D1. The first direction D1 indicates a direction from the drainage tank 4 toward the operation unit C. Further, the opposite direction of the first direction D1 is the second direction D2. The outlet 2 is formed, for example, on the front surface of the casing 1. The front surface of the casing 1 is a surface arranged toward the third direction D3. The third direction D3 indicates a direction from the first suction port 3a toward the outlet 2. Further, the direction from the outlet 2 toward the first suction port 3a is the fourth direction D4.

The outlet 2 communicates the inside and the outside of the casing 1. The air outlet 2 discharges the air inside the casing 1 to the outside of the casing 1. The outlet 2 may be formed in the casing 1 and may be located at a place other than the front surface of the casing 1.

The cover member 2a is a substantially plate-shaped member. In FIG. 1, the cover member 2a covers the air outlet 2. The cover member 2a is rotatably attached to the casing 1. By changing the rotation angle, the cover member 2a functions as a wind direction plate that defines the direction in which the air discharged from the air outlet 2 flows in the direction corresponding to the rotation angle of the cover member 2a.

The first suction port 3a is formed on the back surface of the casing 1. The first suction port 3a communicates the inside and the outside of the casing 1. The first suction port 3a allows air outside the casing 1 to flow into the inside of the casing 1. The first suction port 3a may be formed in the casing 1 and may be located at a place other than the back surface of the casing 1.

The drainage tank 4 is arranged on the side of the casing 1 in the second direction D2. The drainage tank 4 is detachably stored in the casing 1. Specifically, by moving the drainage tank 4 to the fifth direction D5, the drainage tank 4 can be pulled out from the casing 1. The fifth direction D5 indicates the direction in which the drainage tank 4 is pulled out from the casing 1. Further, by moving the drainage tank 4 to the sixth direction D6, the drainage tank 4 can be pushed into the casing 1. The sixth direction D6 indicates the direction in which the drainage tank 4 is pushed into the casing 1. The drainage tank 4 stores the water generated by the dehumidifier 100.

The operation unit C is arranged on the side of the casing 1 in the first direction D1. That is, the operation unit C is provided on the upper part of the casing 1. The operation unit C receives an instruction from the outside.

As shown in FIG. 2, the dehumidifier 100 further includes a dehumidifying section 110 and a first blowing section 17. The dehumidifying unit 110 dehumidifies the air. The first blower unit 17 blows air. The first blower unit 17 includes a fan.

The dehumidifying unit 110 includes a second blower unit 5, a heater 6, a dehumidifying rotor 7, a cooling unit 8, a heat radiating unit 9, a water collecting unit 10, an expanding unit 11, and a compression unit 12. The second blower unit 5 corresponds to an example of the “blower part”. The heater 6 corresponds to an example of a "heating unit".

The first blower unit 17, the heater 6, the dehumidifying rotor 7, the cooling unit 8, the heat dissipation unit 9, the second blower unit 5, and the compression unit 12 are arranged inside the casing 1.

The second blower unit 5 blows air. The second blower unit 5 includes a fan. The second blower portion 5 is arranged on the third direction D3 side of the heater 6. That is, the second blower portion 5 is arranged upstream of the heater 6. The second blower unit 5 blows air to the heater 6.

The heater 6 heats the air by generating heat.

The dehumidifying rotor 7 includes a zeolite 71, a rotor 72, and a rotating shaft 73. The rotor 72 is a substantially disk-shaped member. The rotor 72 is provided with a plurality of zeolites 71 along the circumferential direction of the rotor 72. The rotor 72 rotates about the rotation shaft 73.

The dehumidifying rotor 7 further includes a moisture releasing portion 7a and a moisture absorbing portion 7b.

The moisture releasing portion 7a releases moisture. The moisture releasing section 7a humidifies the air by releasing moisture. The moisture releasing portion 7a is a portion of the rotor 72 on the first direction D1 side. The moisture releasing portion 7a is located on the first direction D1 side of the moisture absorbing portion 7b. The moisture discharging portion 7a faces the heater 6. The moisture discharging portion 7a is arranged on the fourth direction D4 side of the heater 6. Heat is supplied to the moisture discharging portion 7a from the heater 6.

The moisture releasing section 7a is supplied with air heated by the heater 6 to release air containing moisture (high humidity air) dehumidified by the moisture absorbing section 7b. Specifically, the air heated by the heater 6 is supplied to the zeolite 71 located in the moisture releasing portion 7a, so that the moisture dehumidified when the zeolite 71 is located in the moisture absorbing portion 7b is released in the moisture releasing portion 7a. It is vaporized by. As a result, high-humidity air is discharged from the moisture-releasing portion 7a.

The moisture absorbing portion 7b absorbs moisture. The moisture absorbing portion 7b dehumidifies the air by absorbing moisture. The moisture absorbing portion 7b is a portion of the rotor 72 on the second direction D2 side. The moisture absorbing portion 7b does not face the heater 6. The moisture absorbing portion 7b is arranged between the cooling portion 8 and the heat radiating portion 9.

The moisture absorbing portion 7b dehumidifies the air. Specifically, the zeolite 71 located in the moisture absorbing portion 7b dehumidifies the air. As a result, dehumidified air (dry air) is released from the moisture absorbing portion 7b.

By rotating together with the rotor 72, the zeolite 71 alternately repeats a state of being located in the moisture releasing portion 7a and a state of being located in the moisture absorbing portion 7b.

The compression unit 12 pumps the refrigerant. The compression unit 12 includes a compressor.

The expansion unit 11 depressurizes the refrigerant. The expansion portion 11 includes, for example, a capillary tube.

A refrigeration cycle F2 is formed inside the casing 1. The refrigeration cycle F2 is a cycle in which a circulation path is formed in which the compression section 12, the heat dissipation section 9, the expansion section 11, and the cooling section 8 are connected in a ring shape, and the refrigerant is circulated through the circulation path by the compression section 12.

In the refrigeration cycle F2, the temperature and pressure of the refrigerant are increased by the operation of the compression unit 12. The high temperature and high pressure refrigerant is sent to the heat radiating unit 9. The heat radiating unit 9 cools the refrigerant by radiating the heat of the refrigerant into the air passing through the heat radiating unit 9. The refrigerant that has passed through the heat radiating section 9 is sent to the expanding section 11. The expansion unit 11 decompresses the refrigerant cooled by the heat radiation unit 9 to generate a low-temperature low-pressure refrigerant. The refrigerant that has passed through the expansion unit 11 is sent to the cooling unit 8. The cooling unit 8 is cooled by supplying a low-temperature and low-pressure refrigerant from the expansion unit 11. The refrigerant that has passed through the cooling unit 8 is sent to the compression unit 12. In the refrigeration cycle F2, the refrigerant circulates in the order of the compression unit 12, the heat radiation unit 9, the expansion unit 11, and the cooling unit 8, so that the temperature rise of the cooling unit 8 is suppressed. In the refrigeration cycle F2, since the refrigerant whose temperature and pressure have been increased by the compression unit 12 is sent to the heat radiation unit 9, the temperature of the heat radiation unit 9 rises.

The cooling unit 8 exchanges heat to cool the air. The cooling unit 8 includes an evaporator. The cooling unit 8 has a shape extending along the vertical direction. The cooling unit 8 faces the moisture absorbing unit 7b. The cooling unit 8 is arranged on the fourth direction D4 side of the moisture absorbing unit 7b. The cooling unit 8 of the first embodiment corresponds to an example of the “first heat exchange unit”.

The cooling unit 8 cools the air to condense water vapor in the air. As a result, air is dehumidified and water is produced.

In the first embodiment, high-humidity air is discharged from the moisture-releasing portion 7a. The air discharged from the moisture releasing section 7a is supplied to the cooling section 8. Then, the cooling unit 8 generates dew condensation from the air discharged from the moisture discharging unit 7a to dehumidify.

The heat radiating unit 9 cools the cooling unit 8 by cooling the refrigerant in the refrigerating cycle F2. That is, the heat radiation unit 9 cools the cooling unit 8 via a refrigerant (for example, Freon gas). The heat radiating unit 9 includes a capacitor. The heat radiating portion 9 is arranged on the third direction D3 side of the moisture absorbing portion 7b. The heat radiating unit 9 is arranged on the second direction D2 side of the heater 6. The heat radiating section 9 is arranged on the fourth direction D4 side of the first blowing section 17. The heat dissipation unit 9 corresponds to an example of the "second heat exchange unit".

The water collecting unit 10 collects the water generated by the cooling unit 8. The water collecting unit 10 is arranged below the cooling unit 8. The water generated by the cooling unit 8 drops on the water collecting unit 10.

The water collecting unit 10 is formed in a funnel shape, for example, and guides the supplied water to the drainage tank 4. As a result, water is stored in the drainage tank 4.

The dehumidifier 100 further includes a storage unit 13 and a control unit 14.

The storage unit 13 includes a main storage device (for example, a semiconductor memory) such as a ROM (Read Only Memory) and a RAM (Random Access Memory), and may further include an auxiliary storage device (for example, a hard disk drive). The main storage device and / or the auxiliary storage device stores various computer programs executed by the control unit 14.

The control unit 14 includes a processor such as a CPU (Central Processing Unit) and an MPU (Micro Processing Unit). The control unit 14 controls each element of the dehumidifier 100.

Next, the cooling unit 8 and the heat radiating unit 9 will be described in detail with reference to FIGS. 2 to 4. The cooling unit 8 that exchanges heat and the heat radiating unit 9 that exchanges heat may have the same shape. In the present embodiment, the "heat exchange unit" will be described by taking the cooling unit 8 as an example. FIG. 3 is an enlarged view showing the cooling unit 8. FIG. 4 is a diagram showing an IV-IV cross section shown in FIG.

As shown in FIG. 3, the cooling unit 8 includes a first support unit 81, a second support unit 82, a plurality of heat transfer plates 83, a first distribution unit 84, and a second distribution unit 85.

The first support unit 81 supports a plurality of first distribution units 84. Specifically, the first support portion 81 supports the end portions of the plurality of first distribution portions 84 on the side of the first direction D1. Specifically, the first support portion 81 has a plurality of first openings 81a. An end portion of the first distribution unit 84 in the first direction D1 is inserted into each of the plurality of first openings 81a.

The first support portion 81 has a U-shape. The first support portion 81 has thermal conductivity. The first support portion 81 is formed of, for example, metal. The first support portion 81 is arranged apart from the second support portion 82. The first support portion 81 faces the second support portion 82 in a state of being separated from the second support portion 82.

The second support unit 82 supports a plurality of first distribution units 84. Specifically, the first support portion 81 supports the end portions of the plurality of first distribution portions 84 on the side of the second direction D2. Specifically, the second support portion 82 has a plurality of second openings 82a. An end portion of the first distribution unit 84 in the first direction D1 is inserted into each of the plurality of second openings 82a.

The second support portion 82 has a U-shape. The second support portion 82 has thermal conductivity. The second support portion 82 is formed of, for example, metal. The second support portion 82 is arranged apart from the first support portion 81. The second support portion 82 faces the first support portion 81 in a state of being separated from the first support portion 81. The second distribution unit 85 corresponds to the path connecting the compression unit 12 and the heat dissipation unit 9. Further, the second distribution unit 85 corresponds to a path connecting the expansion unit 11 and the cooling unit 8.

Air circulates in the first distribution unit 84. The first distribution unit 84 has a tubular shape. Specifically, the first distribution unit 84 is a square cylinder. The first distribution unit 84 has a first end portion 842 in the first direction D1 and a second end portion 843 in the second direction D2. An opening is formed in the first end portion 842. An opening is formed in the second end portion 843. As shown in FIGS. 2 and 3, the high-humidity air discharged from the moisture-releasing portion 7a flows into the inside of the first distribution portion 84 from the first end portion 842. Next, the high humidity air moves inside the first distribution unit 84 in the direction of the second direction D2. Next, the high humidity air flows out from the second end 843. That is, the cooling unit 8 cools the high humidity air flowing inside the first distribution unit 84.

Further, the first distribution unit 84 has thermal conductivity. The first distribution unit 84 is formed of, for example, a metal. In this embodiment, the plurality of first distribution units 84 are arranged at equal intervals. In the present embodiment, the three first distribution units 84 are supported by the first support unit 81 and the second support unit 82. Further, the first distribution unit 84 intersects with the second distribution unit 85.

Refrigerant is distributed in the second distribution unit 85. Specifically, the cooled refrigerant flows through the second distribution unit 85. Therefore, the cooling unit 8 can cool the air around the second distribution unit 85 while cooling the high humidity air flowing inside the first distribution unit 84. That is, one cooling unit 8 can serve as both a cooling unit used in the desiccant type dehumidifier and a cooling unit used in the compressor type dehumidifier. As a result, it is possible to suppress an increase in the size of the casing 1 of the dehumidifier 100 while combining the desiccant type dehumidifying function and the compressor type dehumidifying function. In other words, the dehumidifier 100 can be miniaturized.

As shown in FIG. 4, the second distribution unit 85 penetrates the first distribution unit 84. Therefore, a part of the second distribution unit 85 is located inside the first distribution unit 84. That is, the air moving inside the first distribution unit 84 passes around the second distribution unit 85. Then, the refrigerant moving inside the second distribution unit 85 cools the air around the second distribution unit 85. As a result, the air moving inside the first distribution unit 84 can be cooled more efficiently.

The plurality of heat transfer plates 83 transfer heat. The plurality of heat transfer plates 83 have thermal conductivity. The plurality of heat transfer plates 83 are formed of, for example, metal. In this embodiment, the plurality of heat transfer plates 83 are arranged at equal intervals. In this embodiment, 10 heat transfer plates 83 are arranged between the first support portion 81 and the second support portion 82. The heat transfer plate 83 is arranged along the direction in which the first distribution unit 84 extends. That is, the heat transfer plate 83 is arranged along the first direction D1 or the second direction D2.

Further, the second distribution unit 85 penetrates the heat transfer plate 83. Therefore, the plurality of heat transfer plates 83 are supported by the second distribution unit 85. The plurality of heat transfer plates 83 supported by the second distribution unit 85 transfer the heat of the refrigerant moving inside the second distribution unit 85 to the air. That is, the heat transfer plate 83 further cools the air around the cooling unit 8. As a result, the air around the cooling unit 8 can be efficiently cooled.

Further, as shown in FIG. 4, the first distribution unit 84 has a main body unit 841. The main body portion 841 has a plurality of through holes 845 and a guide portion 846.

The main body portion 841 is a tubular body. A guide portion 846 is arranged on the inner wall 847 of the main body portion 841.

The plurality of through holes 845 communicate the inside and the outside of the main body 841. A second distribution section 85 is inserted through each of the plurality of through holes 845. In this embodiment, 12 through holes 845 are arranged in the main body portion 841.

The guide unit 846 guides water droplets adhering to the inner wall 847. That is, the guide portion 846 can guide the water droplets adhering to the inner wall 847 from the first end portion 842 to the second end portion 843. Specifically, the guide unit 846 guides the water droplets adhering to the inner wall 847 to the water collection unit 10 (see FIG. 2). Therefore, the water droplets are guided to the water collecting portion 10 and the water is discharged to the drainage tank 4. As a result, it is possible to suppress a decrease in the dehumidifying capacity of the dehumidifier 100.

The guide portion 846 projects from the inner wall 847. Therefore, the surface area on the inner wall 847 side of the main body 841 becomes large. As a result, a large amount of dew condensation can be attached to the inner wall 847.

Subsequently, the distribution channel F1 formed inside the casing 1 will be described with reference to FIGS. 2 to 4.

As shown in FIGS. 2 to 4, the second blower unit 5 blows air to generate a distribution path F1. The flow path F1 is a flow path through which air moves.

As shown in FIG. 2, the distribution route F1 includes a first route F11, a second route F12, a third route F13, a fourth route F14, a fifth route F15, and a sixth route F16.

The first path F11 is a flow path through which air flows. The first path F11 is located on the side of each of the cooling unit 8 and the heat radiating unit 9 in the first direction D1, and on the side of each of the heater 6 and the moisture releasing unit 7a in the third direction D3. The first path F11 communicates with the first suction port 3a and extends from the first suction port 3a in the third direction D3. The connection region F1a of the first path F11 is located on the side of the third direction D3 with respect to the heater 6.

The second path F12 is a flow path through which air flows. The second path F12 is connected to the connection region F1a of the first path F11 and extends from the connection region F1a toward the heat dissipation portion 9. The connection region F2a on the heat radiating portion 9 side of the second path F12 is located in the third direction D3 of the heater 6. The first path F11 and the second path F12 may be omitted.

The third path F13 is a flow path through which air flows. The third path F13 is connected to the connection region F2a of the second path F12 and extends from the connection region F2a in the fourth direction D4. The third path F13 passes on the side of the first direction D1 of the heater 6 and the moisture releasing portion 7a. The connection region F3a of the third path F13 is located on the side of the first direction D1 of the cooling unit 8.

The fourth path F14 is a flow path through which air flows. The fourth path F14 is connected to the connection region F3a of the third path F13, and extends from the connection region F3a toward the second direction D2. The fourth path F14 is formed in the cooling unit 8. The fourth path F14 corresponds to the first distribution unit 84.

The fifth path F15 is a flow path through which air flows. The fifth path F15 is connected to the connection region F4a of the fourth path F14 and extends from the connection region F4a in the third direction D3. The fifth path F15 passes through the heat radiating unit 9.

The sixth path F16 is a flow path through which air flows. The sixth route F16 is connected to the intermediate region F5a of the fifth route F15, and extends from the intermediate region F5a in the first direction D1. The sixth path F16 is formed in the heat radiating portion 9. The sixth path F16 leads to the second blower unit 5. The sixth path F16 corresponds to the first distribution unit 84.

A discharge path FZ is further formed inside the casing 1. The discharge path FZ is formed from the first blower portion 17 to the outlet 2.

The air that has flowed into the inside of the casing 1 through the first suction port 3a circulates in the distribution path F1.

In the distribution path F1, air flows in the order of the second blower section 5, the heater 6, the moisture release section 7a, the cooling section 8, and the heat dissipation section 9.

As shown in FIG. 4, when the first blower unit 17 blows air, air passes through the cooling unit 8 from the fourth direction D4 to the third direction D3. The air that has passed through the cooling unit 8 is cooled. Then, after flowing through the discharge path FZ, it is discharged from the outlet 2 to the outside of the casing 1.

The dehumidifier 100 further includes a plurality of wall portions 15. Each of the plurality of wall portions 15 forms a distribution path F1 by partitioning the inside of the casing 1.

The plurality of wall portions 15 include the first wall portion 15a to the sixth wall portion 15f. The plurality of wall portions 15 are plate-shaped members.

The first wall portion 15a is arranged between the first path F11 and the third path F13. The first wall portion 15a separates the first path F11 and the third path F13 from each other by partitioning the space located on the fourth direction D4 side of the moisture discharging portion 7a from the inside of the casing 1 to the left and right. The first wall portion 15a is arranged on the side of the cooling portion 8 in the first direction D1. In the first embodiment, a pair of first wall portions 15a are provided. A third path F13 exists between the pair of first wall portions 15a.

The second wall portion 15b is arranged between the first path F11 and the third path F13. The second wall portion 15b separates the first path F11 and the third path F13 from each other by partitioning the space located on the side of the moisture discharging portion 7a on the third direction D3 from the inside of the casing 1 to the left and right. The second wall portion 15b is arranged on the side of the heat radiating portion 9 in the first direction D1. In the first embodiment, a pair of second wall portions 15b are provided. A third path F13 exists between the pair of second wall portions 15b. Further, there is a heater 6 between the pair of second wall portions 15b.

The third wall portion 15c is arranged on the side of the second wall portion 15b in the third direction D3. A second path F12 exists between the third wall portion 15c and the second wall portion 15b. The third wall portion 15c is arranged on the side of the heater 6 in the third direction D3. The third wall portion 15c forms the second path F12 by partitioning the space inside the casing 1 located on the side of the heater 6 in the third direction D3 back and forth. The second path F12 exists on the side of the third wall portion 15c in the fourth direction D4.

The fourth wall portion 15d is arranged between the heater 6 and the heat radiating portion 9. Further, the fourth wall portion 15d is arranged between the moisture releasing portion 7a and the moisture absorbing portion 7b. The fourth wall portion 15d is connected to the lower part of the third wall portion 15c. The fourth wall portion 15d vertically partitions the space located below the heater 6 in the space inside the casing 1. Above the fourth wall portion 15d, there are a first path F11, a second path F12, and a third path F13. Below the fourth wall portion 15d, there is a fifth path F15.

The fifth wall portion 15e is arranged on the fourth direction D4 side of the cooling portion 8. The fifth wall portion 15e is formed so as to cover the cooling portion 8 from the back. The fifth wall portion 15e may be a part of the casing 1. Further, the fifth wall portion 15e may be a member different from the casing 1. A gap S is formed between the fifth wall portion 15e and the fourth wall portion 15d. The fourth path F14 exists in the gap S.

The sixth wall portion 15f is arranged on the third direction D3 side of the cooling portion 8. The sixth wall portion 15f faces the fifth wall portion 15e via the cooling portion 8. A fourth path F14 exists between the sixth wall portion 15f and the fifth wall portion 15e. The lower end fa of the sixth wall portion 15f is located on the first direction D1 side of the lower end of the cooling portion 8. The fourth path F14 is connected to the fifth path F15 on the second direction D2 side of the sixth wall portion 15f.

As described above, as described with reference to FIGS. 2 to 4, in the distribution path F1, the second air blower unit 5, the heater 6, the moisture release unit 7a, and the cooling unit 8 are included in the second air blower unit 5, The heater 6, the moisture releasing portion 7a, and the cooling portion 8 are arranged in this order. Therefore, the air supplied to the distribution path F1 from the outside of the casing 1 flows in the order of the second blower unit 5, the heater 6, the moisture release unit 7a, and the cooling unit 8. The air flowing through the distribution path F1 is dehumidified by dew condensation of moisture in the air by the cooling unit 8. As a result, the amount of dehumidified air can be improved, so that the air can be effectively dried.

Further, as shown in FIG. 2, in the distribution path F1, the second blower section 5, the heater 6, the moisture release section 7a, the cooling section 8, and the heat dissipation section 9 are included in the second blower section 5 and the heater 6. , The moisture releasing section 7a, the cooling section 8, and the heat radiating section 9 are arranged in this order. The cooling unit 8 cools the air after the moisture discharging unit 7a releases the moisture and the air around the cooling unit 8. The heat radiating unit 9 releases the heat of the refrigerant, and the released heat heats the air flowing through the sixth path F16. That is, the air supplied from the outside of the casing 1 to the distribution path F1 flows in the order of the second blower section 5, the heater 6, the moisture release section 7a, the cooling section 8, and the heat dissipation section 9, and then the second blower section. Return to 5. Therefore, the heater 6 further heats the air heated by the heat generated by the heat radiating unit 9. As a result, the air can be effectively heated.

For example, as shown in FIGS. 2 to 4, the air outside the casing 1 flows into the inside of the casing 1 through the first suction port 3a, and then the second blower portion 5, the heater 6, and the moisture release portion 7a. , The cooling unit 8 and the heat radiating unit 9 flow in this order, and are discharged from the outlet 2 to the outside of the casing 1. Further, the air outside the casing 1 flows into the inside of the casing 1 through the first suction port 3a, and then the second blower section 5, the heater 6, the moisture release section 7a, the cooling section 8, and the heat dissipation section 9 It flows in order and returns to the second blower unit 5.

Specifically, the air that has flowed into the casing 1 through the first suction port 3a by the second blower portion 5 is heated by the heater 6. The air heated by the heater 6 is supplied to the moisture discharging portion 7a. Then, the air heated by the heater 6 vaporizes the moisture contained in the zeolite 71 located in the moisture releasing portion 7a. As a result, high humidity air is generated. High-humidity air is discharged from the moisture-releasing portion 7a.

The high-humidity air discharged from the moisture-releasing unit 7a is cooled by the cooling unit 8. As a result, condensation is formed. The water generated by dew condensation is discharged to the drainage tank 4 via the water collecting section 10.

The air discharged from the cooling unit 8 is supplied to the heat radiating unit 9. After being supplied to the heat radiating section 9, it is discharged to the second blowing section 5. The air discharged to the second blower unit 5 is sent to the heater 6 again.

As described above, as described with reference to FIG. 2, the air cooled by the cooling unit 8 is supplied to the heat radiating unit 9. Therefore, since the heat radiating unit 9 can be cooled by the air cooled by the cooling unit 8, the temperature rise of the heat radiating unit 9 can be suppressed. As a result, in the refrigerating cycle F2, the refrigerant can be effectively cooled by the heat radiating unit 9, so that the cooling efficiency of the cooling unit 8 by the refrigerating cycle F2 can be improved.

Further, by improving the cooling efficiency of the cooling unit 8 by the refrigerating cycle F2, the cooled state of the cooling unit 8 can be effectively secured. When the cold state of the cooling unit 8 is secured, the cooling capacity of the air by the cooling unit 8 can be improved. Therefore, the cooling unit 8 can effectively condense water vapor in the air to generate more water. As a result, it is possible to suppress a decrease in the dehumidifying capacity of the dehumidifier 100.

Further, when the temperature around the dehumidifier 100 is sufficiently high, the air can be cooled to the extent that dew condensation occurs by the cooling unit 8 even when the heater 6 is OFF. That is, when the season is summer, the heater 6 may be turned off for dehumidification. In this case, from the viewpoint of power saving, the dehumidifier 100 may be operated with the heater 6 turned off. Further, when the season is winter, the temperature around the dehumidifier 100 is sufficiently low, so that the compression unit 12 may be turned off to dehumidify. Further, when the clothes are dried, the heater 6 and the compression unit 12 may be turned on to dehumidify.

[Embodiment 2]
Next, the dehumidifier 100 according to the second embodiment of the present invention will be described with reference to FIGS. 1 to 4. The dehumidifier 100 according to the second embodiment is different from the dehumidifier 100 according to the first embodiment in that the heat dissipation unit 9 is a “first heat exchange unit”. Hereinafter, the second embodiment will mainly explain the differences from the first embodiment.

The dehumidifier 100 of the second embodiment includes a casing 1, a cover member 2a, a drainage tank 4, an operation unit C, a dehumidification unit 110, and a first blower unit 17.

The casing 1 is formed with an outlet 2 and a pair of first suction ports 3a. The outlet 2 is formed on the front surface of the casing 1 and discharges the air inside the casing 1 to the outside of the casing 1. The cover member 2a defines the direction in which the air discharged from the outlet 2 flows in the direction corresponding to the rotation angle of the cover member 2a. The first suction port 3a is formed on the back surface of the casing 1 and allows air outside the casing 1 to flow into the inside of the casing 1. The drainage tank 4 stores the water generated by the dehumidifier 100. The operation unit C receives an instruction from the outside. The dehumidifying unit 110 dehumidifies the air. The first blower unit 17 blows air.

The dehumidifying unit 110 includes a second blower unit 5, a heater 6, a dehumidifying rotor 7, a cooling unit 8, a heat radiating unit 9, a water collecting unit 10, an expansion unit 11, a compression unit 12, and a storage unit 13. And the control unit 14. The heat dissipation unit 9 of the second embodiment corresponds to an example of the "first heat exchange unit".

The second blower unit 5 blows air to the heater 6. The heater 6 heats the air by generating heat. The dehumidifying rotor 7 includes a zeolite 71, a rotor 72, a rotating shaft 73, a moisture releasing portion 7a, and a moisture absorbing portion 7b. The moisture releasing section 7a humidifies the air by releasing moisture. The moisture absorbing portion 7b dehumidifies the air by absorbing moisture. By rotating together with the rotor 72, the zeolite 71 alternately repeats a state of being located in the moisture releasing portion 7a and a state of being located in the moisture absorbing portion 7b. The compression unit 12 pumps the refrigerant. The expansion unit 11 depressurizes the refrigerant. The cooling unit 8 exchanges heat to cool the air. The heat radiating unit 9 cools the cooling unit 8 by cooling the refrigerant. The water collecting unit 10 collects the water generated by the cooling unit 8.

A refrigeration cycle F2 is formed inside the casing 1. The refrigeration cycle F2 is a cycle in which a circulation path is formed in which the compression section 12, the heat dissipation section 9, the expansion section 11, and the cooling section 8 are connected in a ring shape, and the refrigerant is circulated through the circulation path by the compression section 12.

The storage unit 13 includes a main storage device (for example, a semiconductor memory) such as a ROM and a RAM, and may further include an auxiliary storage device (for example, a hard disk drive). The main storage device and / or the auxiliary storage device stores various computer programs executed by the control unit 14.

The control unit 14 includes a processor such as a CPU and an MPU. The control unit 14 controls each element of the dehumidifier 100.

As shown in FIGS. 2 to 4, the dehumidifier 100 further includes a plurality of wall portions 15. Each of the plurality of wall portions 15 forms a distribution path F1 by partitioning the inside of the casing 1. The first blower unit 17 and the second blower unit 5 blow air so that the air moves in the distribution path F1.

As shown in FIG. 2, the distribution route F1 includes a first route F11, a second route F12, a third route F13, a fourth route F14, a fifth route F15, and a sixth route F16.

The first path F11 is located above each of the cooling unit 8 and the heat radiating unit 9 and to the side of each of the heater 6 and the moisture releasing unit 7a. The second path F12 is connected to the first path F11 and extends to the heater 6 side. The third path F13 is connected to the second path F12 and passes through the heater 6 and the moisture releasing portion 7a. The fourth path F14 is connected to the third path F13 and is formed in the cooling unit 8. The fifth path F15 is connected to the fourth path F14 and passes through the moisture absorbing portion 7b and the heat radiating portion 9. The sixth path F16 is connected to the fifth path F15 and is formed in the heat radiating portion 9.

In the distribution path F1 of the second embodiment, air flows in the order of the second blower section 5, the heater 6, the moisture release section 7a, the cooling section 8, and the heat dissipation section 9.

As described above, as described with reference to FIGS. 2 to 4, in the distribution path F1, the second blower unit 5, the heater 6, the moisture release unit 7a, the cooling unit 8, and the heat dissipation unit 9 are the first. 2 The blower unit 5, the heater 6, the moisture release unit 7a, the cooling unit 8, and the heat dissipation unit 9 are arranged in this order. The heat dissipation unit 9 of the second embodiment corresponds to an example of the "first heat exchange unit". That is, the air supplied from the outside of the casing 1 to the distribution path F1 flows in the order of the second blower section 5, the heater 6, the moisture release section 7a, and the heat dissipation section 9, and then returns to the second blower section 5. Therefore, the heater 6 further heats the air heated by the heat generated by the heat radiating unit 9. As a result, the air can be effectively heated.

[Embodiment 3]
Next, the dehumidifier 100 according to the third embodiment of the present invention will be described with reference to FIGS. 1, 2, and 5. In the dehumidifier 100 according to the third embodiment, the shape of the "heat exchanger" is different from that of the "heat exchanger" of the first and second embodiments. Hereinafter, the differences from the first and second embodiments will be mainly described.

FIG. 5 is a diagram showing a cooling unit 8 of the third embodiment. In the present embodiment, the "heat exchange unit" will be described by taking the cooling unit 8 as an example. The cooling unit 8 that exchanges heat and the heat radiating unit 9 that exchanges heat may have the same shape.

As shown in FIG. 5, the cooling unit 8 has a plurality of first distribution units 84 and a plurality of second distribution units 85.

Air circulates in the first distribution unit 84. The first distribution unit 84 has a tubular shape. Specifically, the first distribution unit 84 is a square cylinder. The first distribution unit 84 has a first end portion 842 in the first direction D1 and a second end portion 843 in the second direction D2. An opening is formed in the first end portion 842. An opening is formed in the second end portion 843.

The first distribution unit 84 includes a first heat transfer plate 83a, a second heat transfer plate 84a, a pair of third heat transfer plates 84b, and a pair of fourth heat transfer plates 83b.

The first heat transfer plate 83a transfers heat. The first heat transfer plate 83a has thermal conductivity. The first heat transfer plate 83a is formed of, for example, metal. The first heat transfer plate 83a has a flat plate shape.

The first heat transfer plate 83a faces the second heat transfer plate 84a. The first heat transfer plate 83a is arranged on the side of the fifth direction D5 with respect to the position where the second heat transfer plate 84a is arranged. The first heat transfer plate 83a extends along the first direction D1 or the second direction D2.

The first heat transfer plate 83a has a plurality of through holes 835. A second distribution section 85 is inserted through each of the plurality of through holes 835. In this embodiment, 12 through holes 835 are arranged in the first heat transfer plate 83a.

The pair of fourth heat transfer plates 83b come into contact with the second heat transfer plates 84a of the adjacent first distribution unit 84 to transfer heat. The pair of fourth heat transfer plates 83b have thermal conductivity. The pair of fourth heat transfer plates 83b are formed of, for example, metal. The pair of fourth heat transfer plates 83b has a flat plate shape.

The pair of fourth heat transfer plates 83b extends from the first heat transfer plate 83a. Specifically, one of the pair of fourth heat transfer plates 83b extends along the sixth direction D6 from the end of the first heat transfer plate 83a in the first direction D1. The other of the pair of fourth heat transfer plates 83b extends along the sixth direction D6 from the end of the first heat transfer plate 83a in the second direction D2. The pair of fourth heat transfer plates 83b are arranged between the second heat transfer plate 84a and the first heat transfer plate 83a of the adjacent first distribution unit 84. The pair of fourth heat transfer plates 83b extend along the third direction D3 or the fourth direction D4.

The second heat transfer plate 84a transfers heat. The second heat transfer plate 84a has thermal conductivity. The second heat transfer plate 84a is formed of, for example, metal. The second heat transfer plate 84a has a flat plate shape.

The second heat transfer plate 84a faces the first heat transfer plate 83a. The second heat transfer plate 84a is arranged on the side of the sixth direction D6 with respect to the position where the first heat transfer plate 83a is arranged. The second heat transfer plate 84a extends along the first direction D1 or the second direction D2.

The second heat transfer plate 84a has a plurality of through holes 845. A second distribution section 85 is inserted through each of the plurality of through holes 845. In this embodiment, 12 through holes 845 are arranged in the second heat transfer plate 84a. The positions of the plurality of through holes 845 correspond to the positions of the plurality of through holes 835.

The pair of third heat transfer plates 84b come into contact with the first heat transfer plates 83a of the adjacent first distribution unit 84 and transfer heat. The pair of third heat transfer plates 84b have thermal conductivity. The pair of third heat transfer plates 84b are formed of, for example, metal. The pair of third heat transfer plates 84b has a flat plate shape.

The pair of third heat transfer plates 84b extends from the second heat transfer plate 84a. The pair of third heat transfer plates 84b extend along the first direction D1 or the second direction D2. One of the pair of third heat transfer plates 84b extends along the sixth direction D6 from the end of the second heat transfer plate 84a in the third direction D3. The other of the pair of third heat transfer plates 84b extends along the sixth direction D6 from the end of the second heat transfer plate 84a in the fourth direction D4. The pair of third heat transfer plates 84b are arranged between the first heat transfer plate 83a and the second heat transfer plate 84a.

As shown in FIG. 5, the second distribution section 85 of the present embodiment penetrates the first heat transfer plate 83a and the second heat transfer plate 84a. Therefore, the heat of the refrigerant flowing inside the second distribution section 85 is transferred to the first heat transfer plate 83a and the second heat transfer plate 84a. As a result, while cooling the air moving in the first distribution unit 84, the air around the first distribution unit 84 can also be cooled.

The embodiments of the present invention have been described above with reference to the drawings. However, the present invention is not limited to the above embodiment, and can be implemented in various embodiments without departing from the gist thereof. In addition, various inventions can be formed by appropriately combining the plurality of components disclosed in each of the above embodiments. For example, some components may be removed from all the components shown in the embodiments. Furthermore, components over different embodiments may be combined as appropriate. In order to make it easier to understand, the drawings are schematically shown with each component as the main component, and the thickness, length, number, spacing, etc. of each of the illustrated components are actual for the convenience of drawing creation. Is different. Further, the speed, material, shape, dimensions, etc. of each component shown in the above embodiment are merely examples, and are not particularly limited, and various changes can be made within a range that does not substantially deviate from the configuration of the present invention. It is possible.

(1) The dehumidifier 100 of the first embodiment and the dehumidifier 100 of the second embodiment have a heater 6, but the present invention is not limited to this. For example, the heater 6 may be removed from the dehumidifier 100. When the heater 6 is removed, the heat radiating unit 9 heats the air. Then, the air heated by the heat radiating unit 9 is guided to the moisture discharging unit 7a. By using the heat radiating unit 9 instead of the heater 6, the electric power for operating the heater 6 becomes unnecessary. Therefore, the running cost of the dehumidifier 100 can be reduced. Further, since the air is always heated by the heat generated in the refrigerating cycle F2 or the heat generated in the heat radiating unit 9 and the heated air is supplied to the dehumidifying unit 7a, the dehumidifying unit 7a is used. It can be efficiently dehumidified.

(2) In the first embodiment, one guide portion 846 is arranged on the inner wall 847 of the main body portion 841, but the present invention is not limited to this. A plurality of guide portions 846 may be arranged on the inner wall 847 of the main body portion 841. The plurality of guide portions 846 guide the water droplets adhering to the inner wall 847 to the second end portion 843. The water droplets guided to the plurality of guide units 846 are discharged to the drainage tank 4 via the water collection unit 10. Further, the plurality of guide portions 846 extend along the first direction D1 or the second direction D2.

(3) The length of the first distribution unit 84 of the cooling unit 8 of the first to third embodiments can be changed according to the length of the casing 1 in the direction along the first direction D1. For example, the longer the first distribution unit 84, the longer it takes for air to pass through the cooling unit 8. That is, the air can be effectively cooled by the cooling unit 8.

(4) The air moving in the distribution path F1 of the first to third embodiments did not pass through the moisture absorbing portion 7b, but is not limited to this. In the distribution path F1, air may flow in the order of the second blower section 5, the heater 6, the moisture release section 7a, the cooling section 8, the moisture absorption section 7b, and the heat dissipation section 9. Therefore, the air flowing through the distribution path F1 is further dehumidified by the moisture absorbing portion 7b. As a result, the amount of dehumidified air can be improved.

The present invention provides a dehumidifier and has industrial applicability.

5: 2nd blower (blower)
6: Heater (heating part)
7a: Moisture release part 7b: Moisture absorption part 8: Cooling part (first heat exchange part)
9: Heat dissipation part (1st heat exchange part, 2nd heat exchange part)
83: Heat transfer plate 83a: 1st heat transfer plate 84: 1st distribution unit 84a: 2nd heat transfer plate 84b: 3rd heat transfer plate 85: 2nd distribution unit 100: Dehumidifier 110: Dehumidifier unit 846: Guide unit 847: Inner wall F1: Distribution channel

Claims (7)

Equipped with a dehumidifying part that dehumidifies the air
The dehumidifying unit includes a first heat exchange unit that exchanges heat.
The first heat exchange unit is
The first distribution section where the air flows and
A dehumidifier having a second distribution section through which the refrigerant flows. The first distribution section intersects with the second distribution section,
The dehumidifier according to claim 1, wherein the second distribution unit penetrates the first distribution unit. The first heat exchange unit further includes a heat transfer plate that transfers heat.
The heat transfer plate is arranged along the direction in which the first distribution unit extends.
The dehumidifier according to claim 2, wherein the second distribution unit penetrates the heat transfer plate. The first distribution department is
The first heat transfer plate that transfers heat and
The second heat transfer plate facing the first heat transfer plate and
It has a pair of third heat transfer plates arranged between the first heat transfer plate and the second heat transfer plate.
The dehumidifier according to claim 2, wherein the second distribution unit penetrates the first heat transfer plate and the second heat transfer plate. The dehumidifier according to claim 3 or 4, wherein the first distribution unit has a guide unit for guiding water droplets adhering to the inner wall. The dehumidifying part is
The heating unit that heats the air and
An air blower that blows the air to the heating part,
A moisture-releasing part that releases moisture,
It is equipped with a distribution channel through which the air moves.
In the flow path, the first heat exchange section, the heating section, the blower section, and the moisture release section have the blower section, the heating section, the moisture release section, and the first heat exchange section. Arranged in the order of
The dehumidifier according to any one of claims 1 to 5, wherein the first distribution unit constitutes a part of the distribution channel. The dehumidifying unit further includes a second heat exchange unit that exchanges heat.
The first heat exchange section cools the air after the moisture release section releases the moisture and the air around the first heat exchange section.
The second heat exchange unit releases the heat of the refrigerant, and the released heat heats the air flowing through the first distribution unit.
In the flow path, the first heat exchange section, the heating section, the blower section, the moisture release section, and the second heat exchange section have the blower section, the heating section, and the moisture release section. The dehumidifier according to claim 6, wherein the first heat exchange unit and the second heat exchange unit are arranged in this order.

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