JP2007098263A - Dehumidifier - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a dehumidifier enhancing a drying efficiency by flowing a large amount of air without reduction of a moisture absorption efficiency and a cooling efficiency and enhancing a handling property by reducing restriction of an installation place. <P>SOLUTION: The dehumidifier is provided with a rotor 12 for absorbing a moisture from fed air; a circulation route 29 for circulation regeneration air to a part of the rotor 12; a heater 14 for releasing a moisture content from the rotor 12; and a condenser 13 for condensing the moisture content released by the rotor 12. The circulation route 29 is formed such that the regeneration air is circulated through a circulation casing 18 for storing a circulation fan 17, a heater case 16 storing the heater 14 and opened with a fan-like heating opening 15 opposed to the rotor 12, a chamber 19 of a fan-like cross section opposed to the heating opening 15 while clamping the rotor 12 and an internal passage 62 of the condenser 13 in the order. A first duct 27 for connecting the chamber 19 and the internal passage 62 is arranged above the rotor 12 and a second duct 28 for connecting the internal passage 62 and the circulation casing 18 is arranged below the rotor 12. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a dehumidifier that dries moisture by absorbing moisture with a rotor carrying a hygroscopic agent and collecting the absorbed moisture as condensed water.

  As a dehumidifier that collects moisture absorbed by the conventional rotor as condensed water, the moisture absorbed by the rotor is heated by a heater and released to high-temperature regeneration air, and the high-humidity regeneration air containing the released moisture is condensed. There is a configuration in which condensed water is recovered by cooling in a vessel, and regenerated air from which moisture has been removed is returned to the heater and circulated. In this regenerative air circulation type configuration, high-humidity regenerative air is not discharged to the outside of the apparatus, and condensation heat obtained when water is recovered from the regenerated air can be used, so that drying of clothes and the like can be performed quickly. There are advantages. In order to increase the drying efficiency, it is important to increase the amount of air supplied to the object to be dried and supply it as dry air having a high temperature and low humidity as much as possible.

  As a dehumidifier used for such a drying application, the air blown by the fan is first supplied to the condenser, and the high-humidity regeneration air is cooled to give condensation heat to a high temperature, and then to the rotor. There is one that supplies moisture to remove moisture and gives heat of adsorption to make it dry at high temperature and low humidity (see, for example, Patent Document 1).

  In addition, the air blown by the fan is first supplied to the rotor to remove moisture and give heat of adsorption to give high temperature and low humidity, and then supplied to the condenser to cool the high-humidity regeneration air to condense heat. Is supplied to the object to be dried at a higher temperature (for example, see Patent Document 2).

  In addition, the air blown by the fan is diverted to the rotor and the condenser, and the air diverted to the rotor side removes the moisture and gives heat of adsorption to make it dry at high temperature and humidity, and supplies it to the object to be dried. In some cases, the air shunted into the air is heated to a high temperature by cooling the high-humidity regenerative air and supplied to the object to be dried (see, for example, Patent Document 3).

Also, air is sucked from different directions, one is supplied to the condenser, condensation heat is applied from the high-humidity regeneration air to a high temperature, and the other is supplied to the rotor to remove the moisture and give heat of adsorption. There is a type in which both high-temperature and low-humidity air that has been heated to high temperature in a condenser and air that has been heated and low-humidified in a rotor are blown to an object to be dried by a fan (for example, see Patent Document 4).
JP 2000-126498 A (page 3, FIG. 2) Japanese Unexamined Patent Publication No. 2000-126498 (page 3, FIG. 3) JP 2000-126498 A (2nd page, FIG. 1) JP 2002-361026 A (3rd page, FIG. 1)

  As described above, various types of dehumidifiers used for drying are proposed. Since the dehumidifier illustrated in Patent Document 1 can be disposed by stacking the condenser and the rotor in the air supply direction, the device configuration can be reduced in size. However, in this configuration, there is a problem that the moisture absorption efficiency of the rotor is lowered because air whose temperature has been increased due to the heat of condensation provided in the condenser is supplied to the rotor.

  Moreover, since the dehumidifier illustrated by patent document 2 can also arrange | position and arrange | position a rotor and a condenser with respect to an air supply direction, it can make an apparatus structure small. However, this configuration has a problem in that the cooling efficiency of the condenser is reduced because air whose temperature has been increased by the heat of adsorption in the rotor is supplied to the condenser.

  Moreover, since the dehumidifier illustrated by patent document 3 distributes and supplies air to each of a rotor and a condenser, it can suppress the fall of moisture absorption efficiency and cooling efficiency. However, in this configuration, it is necessary to form an air passage for diverting the air discharged from the fan to the rotor and the condenser inside the device, which increases the size of the device configuration and increases the ventilation resistance of the air passage. There was a problem that a large amount of air could not be blown and the drying efficiency was low.

  Moreover, since the dehumidifier illustrated by patent document 4 supplies air to a rotor and a condenser from a respectively separate path | route, it can suppress the fall of moisture absorption efficiency and cooling efficiency, and ventilation resistance is by sucking in from another path | route. There is an advantage that a large air volume can be secured by suppressing the above. However, in this configuration, two intake ports are required to take in air from different directions, so a suction space for smoothly sucking air is required on both sides of the main body where the two intake ports are open, There was a problem that the installation location was limited and the usability was bad.

  As described above, each of the conventional configurations has advantages and disadvantages, and a configuration that satisfies all functions such as moisture absorption efficiency, cooling efficiency, drying efficiency, and usability has not been proposed.

  The present invention solves the above-described conventional problems, does not reduce the moisture absorption efficiency of the rotor and the cooling efficiency of the condenser, and reduces the in-machine resistance to increase the drying efficiency by supplying a large amount of air. The purpose is to provide a highly functional dehumidifier that can improve the usability by reducing the restrictions of the system.

  In order to achieve the above object, the first problem-solving means taken by the present invention is to suck in air from the air inlet (3) into the housing (1) having the air inlet (3) and the air outlet (7) open. The fan (20) exhausted from the exhaust port (7), the disk-shaped rotor (12) that absorbs moisture from the air sucked into the fan (20), and the drive means (56) for rotating the rotor (12) ), A circulation path (29) formed so as to circulate regeneration air through a part of the rotor (12), a circulation fan (17) that circulates regeneration air through the circulation path (29), and the circulation path In (29), the heater (14) for releasing moisture from the rotor (12) and the moisture released from the rotor (12) disposed in parallel with the rotor (12) with respect to the wind direction of the fan (20) Including playback A condenser (13) for cooling and condensing air with air supplied by the fan (20), and a tank (4) for storing condensed water collected by the condenser (13), wherein the circulation path (29), a circulation casing (18) for accommodating the circulation fan (17), a heater for accommodating the heater (14) and opening a fan-shaped heating opening (15) facing the rotor (12). A case (16), a fan-shaped chamber (19) opposed to the heating opening (15) across the rotor (12), and an internal passage (62) through which regeneration air passes in the condenser (13). A regenerative air is circulated in order, and a first duct (27) connecting the chamber (19) and the internal passage (62) is disposed above the rotor (12) and the internal passage ( 2) and the at the second duct connecting a circulation casing (18) (28) which is disposed below the rotor (12).

  In the second problem solving means, the first duct (27) is formed to have a downward slope toward one or both of the chamber (19) and the internal passage (62).

  The third problem solving means is that the second duct (28) is provided with a drain port (30) for guiding the condensed water generated in the circulation path (29) to the tank (4).

  The fourth problem solving means is provided with a stopper (31) for closing the drain port (30) when the tank (4) is not attached.

  The fifth problem solving means is that the drain hole (33) is opened at the lowermost part of the circulation casing (18), and the drain hole (33) is connected to the second duct (28).

  The sixth problem solving means includes a communication pipe (32) that communicates the chamber (19) and the second duct (28).

  The seventh problem solving means is that the heater case (16) is disposed above the circulation casing (18).

  The eighth problem-solving means is provided with a heat shield member (45) for shielding heat from the heater (14) on the regeneration air discharge side of the circulation casing (18).

  In the ninth problem solving means, the surface of the circulation casing (18) facing the rotor (12) is formed of a metal plate.

  In the tenth problem solving means, the circulation casing (18) is arranged on the rear side of the heater (14) in the rotation direction of the rotor (12).

  The eleventh problem solving means is that a connection port (38) with the first duct (27) is opened on a surface other than the surface facing the heating opening (15) of the chamber (19).

  The twelfth problem solving means is that a heat shield plate (39) for shielding the radiant heat of the heater (14) is disposed in the chamber (19) so as to face the heating opening (15). is there.

  In the thirteenth problem solving means, the heat shield plate (39) is formed of a mirror metal plate that reflects the radiant heat of the heater (14) in the direction of the rotor (12).

  In the fourteenth problem-solving means, at least one of the chamber (19), the circulation casing (18), and the first duct (27) is formed of a heat-resistant resin such as polyethylene terephthalate or polyphenylene sulfide. Is.

  The operation of the first problem solving means is as follows. That is, air is sucked into the housing (1) from the intake port (3) by the operation of the fan (20). The sucked air is divided into a rotor (12) and a condenser (13) arranged on the suction side of the fan (20) and flows in parallel. Thereby, ventilation resistance decreases and a large amount of air is supplied into the housing (1). The air diverted to the rotor (12) side is supplied to the rotor (12) without receiving heat of condensation. Accordingly, there is no decrease in the moisture absorption efficiency in the rotor (12), and the supplied air is removed from the moisture and given heat of adsorption to become high temperature and low humidity. On the other hand, the air diverted to the condenser (13) side is supplied to the condenser (13) without receiving adsorption heat. Therefore, there is no reduction in cooling efficiency in the condenser (13), and the supply air cools the high-humidity regeneration air and takes away the heat of condensation, resulting in a high temperature. The high-temperature and low-humidity air absorbed by the rotor (12) and the high-temperature air deprived of condensation heat by the condenser (13) are both sucked into the fan (20), stirred and discharged from the exhaust port (7). This exhaust air is a mixed air of air that has been sufficiently absorbed without a decrease in moisture absorption efficiency in the rotor (12) and air that has sufficiently deprived the heat of condensation without a decrease in cooling efficiency in the condenser (13). It will have a high dryness. On the other hand, the rotor (12) that has absorbed moisture moves to the circulation path (29) by the driving means (56) and is heated by the heater (14) to release moisture. The released moisture is contained in the high-temperature regenerated air heated by the heater (14) in the heater case (16). The high-humidity regeneration air containing moisture is received by the chamber (19) and then flows into the condenser (13) through the first duct (27) disposed above the rotor (12). . The regenerated air that has flowed into the condenser (13) flows through the internal passage (62), is cooled by the air supplied by the fan (20), and the moisture is saturated. Moisture saturated from the regenerated air is collected in the tank (4) as condensed water. The regenerated air from which moisture has been collected by the condenser (13) is sucked into the circulation fan (17) through the second duct (28), returns to the heater case (16), and circulates in the circulation path (29). The first duct (27) forming a part of the circulation path (29) is disposed above the rotor (12) so as not to block the ventilation path of the fan (20) to the rotor (12). . The second duct (28) is arranged below the rotor (12) so as not to block the ventilation path of the fan (20) to the rotor (12). Therefore, the air supplied by the fan (20) is supplied to the rotor (12) without being shielded by the duct. Thereby, the ventilation resistance in the ventilation path to a rotor (12) is suppressed low. The rotor (12) is continuously rotated by the drive means (56), and continuously absorbs moisture from the air supplied by the fan (20) and releases moisture in the circulation path (29). As a result, the above-mentioned high dryness air is continuously generated. This highly dry air flows in parallel through the rotor (12) and the condenser (13), and does not receive the airflow resistance of the first duct (27) and the second duct (28), and thus enters the rotor (12). Since it is supplied smoothly, the in-machine resistance is kept low and the air volume is sufficiently secured. When this high dryness and large amount of exhausted air is supplied to an object to be dried such as clothing, extremely high drying efficiency is obtained, and the object to be dried is dried in a short time. Further, since the intake port (3) is opened on one side of the housing (1), the restriction of the suction space in installation is reduced and the usability is improved.

  The second problem solving means operates by forming the first duct (27) with a descending slope, thereby allowing water droplets condensed in the first duct (27) to follow the descending slope along the chamber (19) or It guides to the internal passage (62) and suppresses the retention of water droplets in the first duct (27).

  Further, the action of the third problem solving means is to collect the condensed water generated in the circulation path (29) in the second duct (28) and drain it from one drain outlet (30) to the tank (4). Therefore, the occurrence of water leakage is suppressed.

  The fourth problem solving means is to prevent the dripping port (30) from dripping by closing the drain port (30) with the stopper (31) when the tank (4) is not installed. is there.

  Further, the action of the fifth problem solving means is that condensed water condensed inside the circulation casing (18) is dropped into the second duct (28) through the drain hole (33), and the condensed water stays in the circulation casing (18). It suppresses.

  In addition, the action of the sixth problem solving means is to condense condensed water condensing inside the chamber (19) to the second duct (28) through the communication pipe (32), thereby suppressing condensate water retention in the chamber (19). To do.

  Further, the seventh problem solving means operates by disposing the heater case (16) above the circulation casing (18) to the condensed water heater case (16) in the circulation casing (18). It suppresses the inflow.

  Further, the eighth problem solving means has the effect that the heat insulation member (45) is attached to the regenerative air discharge side of the circulation casing (18), thereby thermally deforming the circulation casing (18) due to the heat radiation of the heater (14). It suppresses.

  Further, the ninth problem solving means is that the circulation casing (18) is thermally deformed by heat radiation from the rotor (12) by forming the opposed surface of the circulation casing (18) to the rotor (12) with a metal plate. It suppresses.

  Further, the action of the tenth problem solving means is to suppress condensation in the circulation casing (18) by disposing the circulation casing (18) on the rear stage side of the heater (14) in the rotation direction of the rotor (12). To do.

  Further, the action of the eleventh problem solving means is that the first surface is different from the surface facing the heating opening (15) of the chamber (19) irradiated with the radiant heat of the heater (14) through the rotor (12). By opening the connection port (38) with the duct (27), deformation of the first duct (27) due to radiant heat is suppressed.

  Further, the action of the twelfth problem solving means is that the radiant heat of the heater (14) is shielded by the heat shield plate (39) disposed in the chamber (19) so as to face the heating opening (15). Heating suppresses the thermal deformation of the chamber (19).

  The action of the thirteenth problem solving means is that the radiant heat irradiated in the chamber (19) is reflected to the rotor (12) side by the mirror-like heat shield plate (39), and is emitted from the rotor (12). It further promotes moisture release.

  In addition, the action of the fourteenth problem solving means is to form at least one of the chamber (19), the circulation casing (18) and the first duct (27) with a heat-resistant resin, thereby preventing thermal deformation during abnormal operation. It is to suppress.

  The dehumidifier according to claim 1 of the present invention has the following effects by adopting such a configuration. That is, by supplying the air supplied from the air inlet (3) to each of the rotor (12) and the condenser (13) and flowing in parallel, it is possible to reduce the ventilation resistance and supply a large amount of air. Further, the first duct (27) is disposed above the rotor (12) and the second duct (28) is disposed below the rotor (12), thereby eliminating the ventilation resistance of the duct in the air passage of the fan (20). The air supply amount to (12) can be further increased. Moreover, the fall of moisture absorption efficiency can be suppressed by supplying the air attracted | sucked from the inlet (3) to a rotor (12), without giving condensation heat. Moreover, the fall of cooling efficiency can be suppressed by supplying the air attracted | sucked from the inlet port (3) to a condenser (13), without giving adsorption heat. In addition, a sufficient air volume is ensured by reducing the draft resistance, and air with a high degree of dryness without lowering the moisture absorption efficiency and cooling efficiency is supplied to the object to be dried from the exhaust port (7), thereby greatly improving the drying efficiency. Can be improved. In addition, since the intake port (3) can be opened only on one side of the housing (1), restrictions on the installation location can be reduced and usability can be improved.

  In the dehumidifier according to claim 2 of the present invention, by forming the first duct (27) with a downward gradient, water droplets condensed in the first duct (27) are placed along the downward gradient in the chamber (19 ) Or the internal passage (62), and there is an effect of suppressing water droplet retention in the first duct (27).

  Further, the dehumidifier according to claim 3 of the present invention collects the condensed water generated in the circulation path (29) in the second duct (28) and from one place of the drain port (30) to the tank (4). By draining, there is an effect of suppressing the occurrence of water leakage.

  In the dehumidifier according to claim 4 of the present invention, when the tank (4) is not mounted, the drain (30) is closed by the stopper (31) to prevent dripping from the drain (30). There is an effect.

  In the dehumidifier according to claim 5 of the present invention, the condensed water condensed inside the circulation casing (18) is dropped into the second duct (28) through the drain hole (33) to condense in the circulation casing (18). There is an effect of suppressing water retention.

  In the dehumidifier according to claim 6 of the present invention, the condensed water condensed in the chamber (19) is dropped into the second duct (28) through the communication pipe (32), and the condensed water stays in the chamber (19). There is an effect of suppressing.

  In the dehumidifier according to claim 7 of the present invention, the heater case (16) which has condensed in the circulation casing (18) is provided by arranging the heater case (16) above the circulation casing (18). ).

  In the dehumidifier according to claim 8 of the present invention, the heat shield member (45) is attached to the regenerative air discharge side of the circulation casing (18), whereby the circulation casing (18) is radiated by the heat radiation of the heater (14). There is an effect of suppressing thermal deformation.

  In the dehumidifier according to claim 9 of the present invention, the surface facing the rotor (12) of the circulation casing (18) is formed of a metal plate, so that the circulation casing (18) of the circulation casing (18) by heat radiation from the rotor (12) is formed. There is an effect of suppressing thermal deformation.

  In the dehumidifier according to claim 10 of the present invention, the circulation casing (18) is disposed on the rear stage side of the heater (14) in the rotation direction of the rotor (12), so that dew condensation in the circulation casing (18) is achieved. There is an effect of suppressing.

  The dehumidifier according to claim 11 of the present invention is a surface different from the surface facing the heating opening (15) of the chamber (19) irradiated with the radiant heat of the heater (14) through the rotor (12). By opening the connection port (38) with the first duct (27), there is an effect of suppressing deformation of the first duct (27) due to radiant heat.

  In the dehumidifier according to claim 12 of the present invention, the radiant heat of the heater (14) is provided by the heat shield plate (39) disposed in the chamber (19) so as to face the heating opening (15). The effect of suppressing the thermal deformation of the chamber (19) by shielding the heat.

  In the dehumidifier according to claim 13 of the present invention, the radiant heat irradiated in the chamber (19) is reflected by the mirror-like heat shield plate (39) toward the rotor (12), and the rotor (12). This has the effect of further promoting the release of moisture from the water.

  In the dehumidifier according to claim 14 of the present invention, at least one of the chamber (19), the circulation casing (18), and the first duct (27) is formed of a heat resistant resin, so that the heat during abnormal operation can be obtained. There is an effect of suppressing deformation.

  Hereinafter, embodiments of the present invention will be described with reference to FIGS.

(Embodiment 1)
1 is a perspective view of a dehumidifier according to Embodiment 1 of the present invention, and FIG. 2 is an exploded perspective view of the dehumidifier. 1 and 2, the housing 1 that forms the outline of the dehumidifier has an oval horizontal cross-sectional shape, and an intake port 3 is opened on the long side of the housing 1. A filter 2 is detachably attached to the intake port 3, and foreign matter such as dust contained in the air sucked from the intake port 3 is captured by the filter 2 to prevent the foreign matter from flowing into the housing 1. Suppressed. Further, since the intake port 3 is opened only on one side of the long side of the housing 1, a suction space for sucking air into the housing 1 may be provided only on one side of the housing 1 where the intake port 3 is opened. As a result, restrictions on installation are eased and usability is improved.

  In addition, a storage portion for storing a tank 4 for draining condensed water is formed at the bottom of the housing 1, and the tank 4 is stored in the storage portion so as to be detachable from the opposite side of the intake port 3. A gripping portion is formed on the drawing surface of the tank 4, and the tank 4 is configured so that it can be easily collected and withdrawn by gripping the gripping portion. Therefore, it is possible to easily perform the collection / removal operation of the tank 4 from the short side direction of the housing 1 with a short drawing distance, and the workability at the time of draining or mounting is improved.

  In addition, an operation unit 5 for operating the dehumidifier, a handle 6 that is gripped when carrying the dehumidifier, and an exhaust port 7 for discharging dry air are provided on the upper surface of the housing 1. The operation unit 5, the handle 6, and the exhaust port 7 are formed in a rectangular shape along the long side direction of the housing 1. Above the exhaust port 7, a wind direction changing means 8 for automatically changing the wind direction of the dry air discharged from the exhaust port 7 is disposed, and the wind direction changing means 8 is discharged from the exhaust port 7. A louver 9 for deflecting air and a drive motor 10 for engaging the shaft of the louver 9 to rotate the louver 9 are provided. Accordingly, the dry air discharged from the exhaust port 7 by the wind direction changing means 8 can be discharged at a wide angle, and can be exhausted widely from the exhaust port 7 opening in a rectangular shape along the longitudinal direction of the housing 1. For this reason, when this exhausted air is used for drying clothes, for example, the drying angle and the width of the discharge increase the wind on the object to be dried over a wide range, thereby improving the drying efficiency.

  In addition, a partition wall 11 that partitions the inside in the short side direction is formed in the housing 1, and a disk-shaped rotor 12 and a rectangular condenser 13 are accommodated side by side in the partition wall 11. Has been. Further, a fan-shaped heater case 16 including a heater 14 and having an opening 15 for heating is attached to the partition wall 11 on the side of the intake port 3 so as to be close to the rotor 12. A circulation casing 18 that houses a circulation fan 17 is disposed below. Further, a fan-shaped cross-section chamber 19 facing the heating opening 15 of the heater case 16 via the rotor 12 is attached to the partition wall 11 on the exhaust port 7 side. 1 is provided with a fan 20 for sending air. Since the rotor 12 and the condenser 13 are arranged in the horizontal direction in the longitudinal direction in the housing 1 in this way, it is possible to arrange the components in the housing 1 with high density, and the device can be downsized. At the same time, since the height of the housing 1 is also reduced, for example, it is possible to carry out transportation work such as raising and lowering stairs in an easy posture, and usability is improved.

  The fan 20 includes a fan casing 23 that forms a suction port 21 that opens to the long side of the housing 1 so as to face the partition wall 11, and a blower port 22 that opens upward so as to face the exhaust port 7. The blade 24 accommodated in the blade 23 and the motor 25 connected to the blade 24 are provided. The blade 24 is rotated by driving the motor 25, the air is sucked from the suction port 21, and the air is discharged from the blower port 22. Is. Therefore, when the fan 20 is operated, air is sucked into the housing 1 from the air inlet 3, and the sucked air is divided into the rotor 12 and the condenser 13 arranged in parallel in the horizontal direction on the long side of the housing 1. After each of them flows in parallel in the short side direction of the housing 1, a blowing operation is performed in which both are sucked into the fan 20 from the suction port 21, stirred by the blades 24, and discharged from the exhaust port 7. Thus, the air sucked from the intake port 3 is divided into each of the rotor 12 and the condenser 13 and flows in parallel in the short side direction of the housing 1, so that the air passage area can be increased and the air passage distance is shortened. As a result, the resistance to in-machine ventilation is reduced and a large amount of air is supplied into the housing 1.

  Further, since the suction port 21 of the fan 20 is opened in the long side direction of the housing 1 so as to face the suction port 3, a wide suction area of the suction port 3 and the suction port 21 can be secured, and the suction port 3. Thus, air can be smoothly introduced into the suction port 21 linearly. Further, since the air outlet 22 of the fan 20 is also disposed so as to face the exhaust port 7, the air discharged from the air outlet 22 is smoothly sent to the exhaust port 7. In this way, air can be smoothly guided from the air inlet 3 to the air inlet 21, and air can be smoothly sent from the air outlet 22 to the air outlet 7. Therefore, the ventilation resistance of the fan 20 is suppressed, and the amount of air flow increases. become.

  3 and 4 are cross-sectional views of the dehumidifier cut along the long side direction. As shown in the figure, a disk-shaped rotor 12 and a rectangular condenser 13 are arranged in parallel in the long side direction in the housing 1, and a tank 4 for storing condensed water condensed by the condenser 13 below the rotor. Is arranged. As will be described later, the condenser 13 has an external passage through which air supplied by the fan 20 passes and an internal passage through which regenerated air circulated by the circulation fan 17 is formed. The passage is formed in a vertical direction, and the inlet portion 25 of the internal passage is disposed on the upper surface side and the outlet portion 26 is disposed on the lower surface side. Therefore, the regenerated air circulated by the circulation fan 17 flows downward in the internal passage in the condenser 13.

  The internal passage of the condenser 13 communicates with the chamber 19 via a first duct 27 having an upper inlet 25 formed above the rotor 12, and a lower outlet 26 is formed below the rotor 12. The second duct 28 communicates with the suction port of the circulation fan 17 formed in the circulation casing 18. Therefore, the regenerated air discharged from the circulation casing 18 flows into the heater case 16 connected to the circulation casing 18 as indicated by an arrow, and passes through the rotor 12 from the fan-shaped heating opening 15 opened in the heater case 16. A circulation path 29 is formed which is received by the chamber 19, enters the internal passage of the condenser 13 from the chamber 19 through the first duct 27, and flows to the circulation fan 17 from the internal passage through the second duct 28. Will be.

  Further, as shown in the figure, the first duct 27 is disposed above the rotor 12, and the second duct 28 is disposed below the rotor 12. Therefore, the region portion of the rotor 12 through which the supply air from the fan 20 passes is not shielded by the connection duct and is widely opened in the air supply direction. For this reason, the passage resistance in the rotor 12 supply path of the fan 20 becomes low, and the supply air volume to the rotor 12 increases.

  Further, the first duct 27 has a downward gradient toward the condenser 13, and water droplets condensed in the first duct 27 move toward the internal passage side of the condenser 13 along the downward gradient. For this reason, water droplet retention in the first duct 27 is suppressed. Further, a drain port 30 is provided near the lowest point of the second duct 28, and a stopper 31 is attached to the drain port 30 so as to engage with the tank 4. The stopper 31 operates to close the drain port 30 when the tank 4 is not mounted and to open the drain port 30 when the tank 4 is mounted.

  A communication pipe 32 that communicates with the lowest point of the chamber 19 and a drain hole 33 that communicates with the lowest point of the circulation casing 18 are connected to the upper surface side of the second duct 28. Accordingly, water droplets condensed in the chamber 19 are dropped into the second duct 28 through the communication pipe 32, and water droplets condensed in the circulation casing 18 are dropped into the second duct 28 through the drain hole 33. Further, the water droplets condensed in the first duct 27 move to the internal passage of the condenser 13 as described above and drop into the second duct 28 located below together with the condensed water condensed in the internal passage of the condenser 13. . Therefore, all the water droplets and condensed water generated in the circulation path 29 are collected in the second duct 28, and the water droplet retention in the circulation path 29 is completely suppressed.

  Further, since the condensed water collected in the second duct 28 is all drained to the tank 4 through the drain port 30, it is difficult to cause water leakage from other than the drain port 30. Since the stopper 31 closes the drain port 30 when the tank 4 is not mounted, dripping from the drain port 30 can be prevented. Furthermore, the discharge part of the circulation casing 18 faces upward and is connected to the heater case 16, and the inflow of water droplets condensed in the circulation casing 18 to the heater case 16 can be easily suppressed.

  FIG. 5 is an exploded perspective view of the main internal components of the dehumidifier. As shown in the figure, the partition wall 11 has a circular opening 34 and a rectangular opening 35, and the circular opening 34 includes a rotation shaft 36 of the rotor 12 and a fan-shaped cross section by a fan-shaped peripheral wall 37. A chamber 19 is formed. The chamber 19 is joined to the partition wall 11 by screws at the outer periphery of the circular opening 34, and a connection port 38 to the first duct 27 corresponding to the regeneration air outlet side of the chamber 19 is opened on the upper surface. Yes. Further, a heat shield plate 39 is disposed inside the chamber 19 so as to cover the fan-shaped portion facing the rotor 12, and this heat shield plate 39 is further downstream of the circumferential wall 37 of the chamber 19 in the rotor 12 rotation direction. It extends so that the radius part located in the side may also be covered. The heat shield plate 39 is formed by pressing or bending a metal plate such as aluminum or stainless steel having high reflectivity and rust prevention. The rotor 12 is accommodated in the circular opening 34 so that the rotary shaft 36 integrally formed with the chamber 19 is inserted, and the condenser 13 is accommodated in the rectangular opening 35. Therefore, the relative positional relationship between the rotor 12 and the condenser 13 is defined at a predetermined position by the partition wall 11, and the air supplied by the fan 20 is properly divided into the rotor 12 and the condenser 13. In addition, since the inner diameter of the circular opening 34 is formed smaller than the outer shape of the rotor 12, the amount of air that bypasses the rotor 12 through the outer periphery of the rotor 12 is reduced, and the decrease in moisture absorption efficiency is suppressed. Become.

  In a state where the rotor 12 is accommodated in the circular opening 34, the heater case 16 having a sectoral cross section is attached from the opposite side of the chamber 19. The heater case 16 is fixed to the rotation shaft 36 of the rotor 12 and the outer peripheral side of the circular opening 34 by screwing the chamber 19. Accordingly, the rotor 12 is rotatably held by the chamber 19 and the heater case 16 at the center and the outer periphery thereof, and even if the partition wall 11 is warped, the rotating operation of the rotor 12 is not affected. Moreover, the space | interval of the heater case 16 and the chamber 19 will always be appropriately hold | maintained in the perimeter by the above-mentioned structure, and this space | interval is wide in the range of 0.3-1.5 mm with respect to the thickness of the rotor 12. FIG. It is preferable to set. The reason for this is that if this distance is less than 0.3 mm with respect to the thickness of the rotor 12, the rotating operation of the rotor 12 cannot be performed smoothly. This is because air leakage from the gap between the rotor 12 and the heater case 16 and the gap between the rotor 12 and the chamber 19 increases and the dehumidification efficiency is greatly reduced. Thus, the drivability of the rotor 12 tends to decrease as the distance between the heater case 16 and the chamber 19 decreases. Conversely, as the distance between the heater case 16 and the chamber 19 increases, air leakage increases and the dehumidification efficiency increases. Tend to decrease. Therefore, in order to satisfy the drivability and the dehumidifying efficiency of the rotor 12, it is preferable that the distance between the heater case 16 and the chamber 19 is wide in the range of 0.3 to 1.5 mm with respect to the thickness of the rotor 12. It is most desirable to form a wide area in the range of 0.5 to 1.2 mm with respect to the thickness of the rotor 12.

  Further, the fan-shaped heating opening 15 that opens to the rotor 12 facing surface of the heater case 16 is disposed so as to face the fan-shaped cross section of the chamber 19, and radiates heat of the heater 14 accommodated in the heater case 16. The rotor 12 is configured to irradiate directly. The radiant heat irradiated from the heating opening 15 reaches the inside of the chamber 19 through the rotor 12. The radiant heat irradiated into the chamber 19 is shielded by a heat shield plate 39 disposed inside the chamber 19 so as to face the heating opening 15. Therefore, the thermal deformation of the chamber 19 due to the radiant heat is suppressed. The heat shield plate 39 is formed by processing a mirror surface metal plate such as aluminum or stainless steel having high reflectivity. As a result, the radiant heat applied to the heat shield plate 39 is reflected in the direction of the rotor 12, and moisture release from the rotor 12 is promoted. Further, the heat shield plate 39 is extended so as to cover the radial portion of the peripheral wall surface 37 located on the rear side in the rotation direction of the rotor 12 of the chamber 19. Therefore, even if the rotor 12 whose surface temperature has risen due to the irradiation of radiation heat from the heating opening 15 comes close to the peripheral wall surface 37 located on the rear side in the rotational direction in accordance with the rotational operation, the heat shielding plate 39 dissipates heat from the rotor 12. Is blocked and thermal deformation of the peripheral wall surface 37 is suppressed. Further, the connection port 38 to the first duct 27 is opened on the upper surface side of the chamber 19 so as not to face the heating opening 15 irradiated with radiant heat. Therefore, the radiant heat irradiated from the heating opening 15 does not directly enter the first duct 27, and thermal deformation of the first duct 27 is suppressed.

  A circulation casing 18 that houses a circulation fan 17 is disposed below the heater case 16. The circulation casing 18 includes a metal part 40 formed by pressing or bending a corrosion-resistant metal plate such as aluminum or stainless steel, and a resin part 41 containing the circulation fan 17 and opening the drain hole 35. The circulation fan 17 is connected to a motor 42 attached to the resin portion 41. Therefore, when the motor 42 is driven, the circulation fan 17 rotates, and air is sucked from the suction port 43 opened in the metal part 40 and blown from the discharge port connected to the heater case 16 is executed. In the vicinity of the discharge port 44, a heat shield member 45 formed by pressing or bending a corrosion-resistant metal plate such as aluminum or stainless steel is attached. Thermal deformation of the resin portion 41 due to heat dissipation or heat transfer from the heater case 16 is suppressed.

  The circulation casing 18 is disposed so that the metal part 40 faces the rotor 12 and is close to the rear position of the heater case 16 in the rotation direction of the rotor 12 indicated by an arrow. Therefore, heat radiation from the rotor 12 heated by the heater 14 is transmitted into the circulation casing 18 through the metal portion 40, and the occurrence of dew condensation inside the circulation casing 18 is suppressed. Further, since the heat radiation from the rotor 12 to the resin part 41 is also shielded by the metal part 40, thermal deformation of the resin part 41 is also suppressed.

  As described above, the circulation casing 18, the chamber 19, and the first duct 27 are disposed at positions that are relatively susceptible to the influence of heat radiation from the heater 14. Therefore, when they are formed of a resin material, they are heat resistant. It is preferable to use a material having high properties. For example, when the circulation casing 18, the chamber 19, and the first duct 27 are formed using a heat-resistant resin such as polyethylene terephthalate or polyphenylene sulfide, the rotation operation failure of the rotor 12, the fan 20 and the circulation fan 17 is blown. Even when the temperature of each part becomes excessively high when an abnormality such as a malfunction occurs, the thermal deformation of the resin is suppressed.

  FIG. 6 is an exploded perspective view showing a detailed configuration of the rotor 12. The rotor 12 has a hygroscopic agent on a donut-shaped disk body in which inorganic fibers such as ceramic fibers and glass fibers, or flat paper made by mixing these inorganic fibers and pulp and corrugated paper are wound. As 46, for example, inorganic adsorption type hygroscopic agents such as silica gel and zeolite, organic polymer electrolytes, that is, hygroscopic agents such as ion exchange resins, and absorbent hygroscopic agents such as lithium chloride are supported in combination of one type or two or more types. The hygroscopic element 47 is provided. The hygroscopic element 47 has a plurality of ribs 53 that are radially bridged from an outer ring 50 to an inner ring 52 that engages with a central hole 51 of the hygroscopic element 47 and a ring-shaped frame A49 having a gear 48 around the outer periphery. The frame B54 is sandwiched and stored from both shaft sides. A plurality of frames A49 and B54 are screwed on the outer periphery, and a bearing portion 55 is fitted into the center hole 51 of the moisture absorbing element 47 from the opposite side of the frame B54, and the inner ring 52 and the bearing portion 55 of the frame B54 are screwed. Thus, the hygroscopic element 47 is protected.

  The rotor 12 configured as described above has a frame A49 on the heater case 16 side and a frame B54 on the chamber 19 side so that the ribs 53 cross-linked to the frame B54 are not directly deformed by being directly heated by the heater 14 when the rotor 12 rotates. Are arranged in the casing 1 in the facing direction. The driving means 56 for rotating the rotor 12 includes a gear 57 that meshes with the gear 48 of the frame A49, and a drive motor 58 that rotates the gear 57, and the drive motor in a state where the gear 57 is meshed with the gear 48. By rotating 58, the driving force is transmitted to the gear 48 of the frame A49 via the gear 57, and the rotational operation of the moisture absorbing element 47 fixedly held by the frame A49 and the frame B54 is smoothly executed. Yes. The rotational speed of the rotor 12 is normally set in a range of 10 to 40 revolutions per hour.

  A first shielding wall 59 is integrally formed on the frame A49 so as to cover the concave part of the gear 48 along the outer periphery, and the second part is also formed on the gear 57 so as to cover the concave part engaged with the outer periphery. The shielding wall 60 is integrally formed. The first shielding wall 59 provided around the frame A49 suppresses air supplied to the rotor 12 by the fan 20 from passing through the concave portion of the gear 48 and bypassing the rotor 12. The second shielding wall 60 provided around the outer periphery of the 57 also suppresses the air supplied to the rotor 12 by the fan 20 from bypassing the rotor 12 through the concave portion of the gear 57. As described above, the first shielding wall 59 and the second shielding wall 60 act so as to reduce the amount of air that bypasses the rotor 12 through the concave portions of the gear 48 and the gear 57, so that the moisture absorption efficiency of the rotor 12 is improved. It will be.

  In addition, the rib 53 formed on the frame B54 comes into contact with the high-humidity regenerated air in the circulation path 29 when the rotor 12 rotates, so in order to prevent the rotation failure of the rotor 12 due to the rust of the rib 53, aluminum or It is preferable to form the frame B54 by pressing or bending a metal plate having corrosion resistance such as stainless steel. Moreover, it is preferable that this metal plate uses the board thickness of the range of 0.1-0.3 mm. The reason for this is that if the thickness of the frame B54 is less than 0.1 mm, the strength of the ribs 53 formed integrally with the frame B54 decreases, and the moisture absorbing element 47 cannot be sufficiently held. When the thickness is 0.3 mm or more, the gap between the end of the rib 53 and the surface of the moisture absorption element 47 becomes large, and air leakage corresponding to the gap occurs in the gap between the frame B54 and the chamber 19 and the dehumidification efficiency decreases. It is because it will do. Thus, as the thickness of the frame B54 becomes thinner, the strength of the rib 53 tends to decrease. Conversely, as the thickness of the frame B54 increases, the amount of air leakage increases and the dehumidification efficiency tends to decrease. Therefore, in order to satisfy the strength of the rib 53 and the dehumidifying efficiency, the thickness of the frame B54 is preferably in the range of 0.1 to 0.3 mm, and more preferably in the range of 0.15 to 0.25 mm. Is most desirable.

  FIG. 7 is a schematic exploded perspective view showing a detailed configuration of the condenser 13. The condenser 13 includes, for example, a heat transfer plate 61a in which uneven portions are formed in a predetermined pattern on a sheet having a thickness of 0.05 to 0.5 mm, and an uneven portion different from the heat transfer plate 61a in a similar thin sheet. It is composed of a stacked heat exchanger in which a plurality of heat transfer plates 61b on which a pattern is formed are alternately stacked. The plate thickness of the heat transfer plate 61a and the heat transfer plate 61b is preferably 0.05 mm or more from the viewpoint of moldability, strength, and shape maintainability of the concavo-convex portion described later, and is 0 from the viewpoint of ensuring heat transfer. 0.5 mm or less is preferable. An internal passage through which the regenerated air flows by alternately flowing the regenerated air circulated by the circulation fan 17 and the air supplied by the fan 20 into the gaps between the heat transfer plates 61a and 61b stacked in a plurality of layers. 62 and external passages 63 through which the air supplied by the fan 20 flows are formed every other stage, and the regenerated air flowing through the internal passages 62 and the air flowing through the external passages 63 pass through the heat transfer plates 61a and 61b, respectively. Heat exchange. Accordingly, the heat exchange hindrance factor is only the heat resistance of the heat transfer plate 61a and the heat transfer plate 61b, so that highly efficient heat exchange is performed and the cooling efficiency in the condenser 13 is improved. The heat transfer plate 61a and the heat transfer plate 61b are actually stacked in a total of about 20 to 60, but for simplicity, two of each of the heat transfer plate 61a and the heat transfer plate 61b are shown exploded in the stacking direction. ing.

  The heat transfer plate 61a and the heat transfer plate 61b have a planar shape having two pairs of opposite sides, the long side and the short side, and are arranged so that the opposite sides on the long side are in a vertical parallel state. The short side located on the lower side is formed in a right trapezoidal plane shape that is inclined by about 10 ° with respect to the horizontal direction as will be described later. The heat transfer plate 61a is provided with hollow convex spacing ribs 64a having a width of about 4 mm along the opposite sides of the long side, and the heat transfer plate 61b is also provided on the opposite side of the short side. Similarly to the heat transfer plate 61a, hollow convex spacing ribs 64b having a width of about 4 mm are provided. The spacing ribs 64a of the heat transfer plate 61a are formed with a convex height of about 3 mm, and the projecting surfaces of the spacing ribs 64a abut on the heat transfer plate 61b in the laminated state, so that the passage spacing of the internal passages 62 is increased. Is defined and held at a predetermined dimension, ie, about 3 mm. On the other hand, the spacing rib 64b of the heat transfer plate 61b is formed to have a convex height of about 2 mm, and the projecting surface of the spacing rib 64b abuts on the heat transfer plate 61a in the laminated state, thereby The passage spacing is defined and maintained at a predetermined dimension, ie about 2 mm.

  Further, the spacing rib 64a is formed by further projecting the corners 65 at both ends overlapping the spacing ribs 64b projecting from the heat transfer plate 61b in a stacked state by the height of the spacing ribs 64b, that is, about 2 mm. 65 is fitted into the back hollow concave portion of the spacing rib 64b so that the entire projecting surface is in contact with the heat transfer plate 61b. Similarly, the spacing rib 64b also has a corner 66 at both ends that overlaps the spacing rib 64a projecting from the heat transfer plate 61a in a stacked state, and further projects by the height of the spacing rib 64a, that is, about 3 mm. 66 is fitted into the hollow concave portion on the back surface of the spacing rib 64a so that the entire projecting surface is in contact with the heat transfer plate 61a. Thus, the interval ribs 64a and the interval ribs 64b are formed so that the entire projecting surfaces thereof are in contact with the adjacent heat transfer plate 61b and the heat transfer plate 61a. All the intervals are held at a proper predetermined size, that is, about 3 mm, and the passage intervals of the external passages 63 are also all held at a proper predetermined size, that is, about 2 mm.

  As described above, the stacking interval on the internal passage 62 side is set to about 3 mm by the rib height of the spacing rib 64a projecting from the heat transfer plate 61a, and the rib height of the spacing rib 64b projecting from the heat transfer plate 61b. Accordingly, since the stacking interval on the side of the external passage 63 is set to about 2 mm, the passage interval of the internal passage 62 is about 1 mm wider than the passage interval of the external passage 63. Thus, when the passage interval of the internal passage 62 is set wider than the passage interval of the external passage 63, the water droplets are smoothly dropped by suppressing the bridging phenomenon of the water droplets condensed in the internal passage 62, and The increase in ventilation resistance can be suppressed, and the external passage 63 side is formed densely without providing an extra passage interval, so that the condenser 13 can be downsized and the cooling efficiency can be improved. Here, when the air flowing through the external passage 63 is used in an environment containing a large amount of foreign matter, for example, if the interval between the external passages 63 is about 2 mm, the foreign matter accumulates in the gap between the passages, and the ventilation resistance. Increases, and also hinders heat exchange. In such a case, the height of the gap rib 64b is set higher than the rib height of the gap rib 64a, for example, about 4 mm, and the passage interval of the external passage 63 is widened to suppress the accumulation of foreign matters. it can. As described above, the rib heights of the spacing rib 64a and the spacing rib 64b are preferably adjusted appropriately according to the state of the air flowing through the respective passages, for example, the water droplet generation state and the foreign matter containing state.

  Further, a hollow convex induction rib 67a having a width of about 2 mm is continuously formed in the same direction as the spacing rib 64a in the horizontal center portion of the heat transfer plate 61a, and the spacing rib is disposed in the vertical direction of the heat transfer plate 61b. Two hollow convex guide ribs 67b having a width of about 2 mm projecting in the opposite direction of 64b are formed continuously. The guide rib 67b is formed so as to be positioned at the center portion of the spacing rib 61a and the guide rib 67a in the stacked state. Therefore, in the laminated state, the guide rib 67a and the guide rib 67b are formed so as to protrude continuously in the internal passage 62 so that the rib spacing is substantially equal from both sides, and in the direction of blowing the regeneration air. Therefore, water droplets condensed on the internal passage 62 are quickly dropped along the guide rib 67a and the guide rib 67b, and the water droplet staying in the internal passage 62 is further suppressed. The rib heights of the guide rib 67a and the guide rib 67b can be appropriately set as long as they are equal to or less than the interval rib 64a, but are preferably set based on the interval holding state and the water droplet dropping state of the internal passage 62. For example, if the rib height of the guide rib 67a is set to about 3 mm, which is the same as the distance rib 64a, and the rib height of the guide rib 67b is set to about 1 mm lower than the guide rib 67a, the passage distance of the internal passage 62 is the center. The cross section of the internal passage 62 is also widened to reduce the ventilation resistance, and water droplets condensed in the passage can be smoothly dropped without bridging.

  The heat transfer plate 61b is provided with a plurality of hollow convex rectifying ribs 68 having a width of about 1 mm at substantially equal intervals in the horizontal direction and projecting in the same direction as the spacing ribs 64b. The surface is formed to be discontinuous in the hollow portion of the guide rib 67b projecting from the opposite surface of the heat transfer plate 61b. Therefore, the rectifying rib 68 protrudes into the external passage 63 from the heat transfer plate 61b side in the heat transfer plate laminated state, and is formed discontinuously with respect to the air blowing direction supplied by the fan 20. The air supplied to the external passage 63 flows uniformly along the flow straightening ribs 68, and the air pressure is leveled at the discontinuous portions of the flow straightening ribs 68 to equalize the wind speed distribution, so that highly efficient heat exchange with the regenerated air is performed. It will be. The rib height of the rectifying rib 68 can be appropriately set as long as it is equal to or less than the spacing rib 64b. For example, when the rectifying rib 68 is set to the same height as the spacing rib 64b, that is, about 2 mm, the external passage 63 is set. The air velocity distribution of the air flowing through the air passage can be made uniform, and the external space 63 can also have a function of maintaining the passage interval.

  As described above, the condenser 13 is configured such that the heat transfer plate 61a and the heat transfer plate 61b are integrally formed with the interval ribs 64a and the interval ribs 64b, the guide ribs 67a and the guide ribs 67b, the rectifying ribs 68 and the like. The stacking interval between the 61a and the heat transfer plate 61b is appropriately maintained, and the increase in the ventilation resistance of the internal passage 62 and the external passage 63 is suppressed. Further, an internal passage 62 is disposed on the opposite side of the short side of the heat transfer plate 61a and the heat transfer plate 61b formed in a right trapezoidal shape, and an external passage 63 is provided on the opposite side of the long side substantially orthogonal to the internal passage 62. Therefore, the passage cross-sectional area of the external passage 63 is formed wider than the passage cross-sectional area of the internal passage 62, and the ventilation resistance of the external passage 63 is lower than the ventilation resistance of the internal passage 62, so that it is lower than the regeneration air. A lot of air can be easily supplied to the external passage 63. Therefore, the regenerated air can be cooled with more air, and high cooling efficiency can be ensured.

  Further, since the internal passage 62 is disposed in the vertical direction so that the regenerative air flows downward, water droplets condensed on the internal passage 62 are quickly dropped by the weight of the self-weight and the regenerative air flowing downward. Passage blockage due to water droplet retention in 62 is suppressed. Further, since the external passage 63 is disposed in the horizontal direction so as to be orthogonal to the internal passage 62, the air supplied by the fan 20 flows through the rotor 12 and the external passage 63 in a substantially parallel state in the horizontal direction. The ventilation resistance of 20 decreases, and the air volume of the fan 20 increases. Further, the water droplets dropped to the outlet of the internal passage 62 sequentially move to the lowest point along the inclined surfaces of the heat transfer plate 61a and the heat transfer plate 61b formed in a right trapezoidal shape, and become large particles at the lowest point. And drop quickly by its own weight. Therefore, the passage blockage at the outlet portion of the internal passage 62 is also suppressed. The inclination angle of the lower side of the internal passage 62 is preferably formed in the range of 5 to 20 °. The reason for this is that if the inclination angle is less than 5 °, the inclination is too gentle and the water droplets dripped up to the outlet of the internal passage 62 do not move smoothly to the lowest point, but stay at the passage outlet portion and the passage resistance increases. In addition, if the inclination angle is 20 ° or more, the inclination is too steep and the ratio of the heat transfer area in the volume necessary to store the condenser 13 decreases, and the cooling efficiency decreases. It is. Thus, as the inclination angle of the lower side of the heat transfer plate 61a and the heat transfer plate 61b becomes gentler, the water droplet separation property tends to decrease, and conversely, the cooling efficiency tends to decrease as the inclination angle becomes steep. Therefore, in order to satisfy both the water droplet separation property and the cooling efficiency, the inclination angle of the lower side of the heat transfer plate 61a and the heat transfer plate 61b is preferably in the range of 5 to 20 °, and more preferably about 10 °. It is most desirable to do.

  Moreover, the condenser 13 can adjust the arrangement | sequence of the internal channel | path 62 and the external channel | path 63 according to an apparatus structure with the laminated pattern of the heat exchanger plate 61a and the heat exchanger plate 61b. For example, assuming that the interval ribs 64a and the interval ribs 64b are sequentially stacked on the projecting surface side, the same number of the heat transfer plates 61b and the heat transfer plates 61a are alternately stacked, starting from the heat transfer plate 61a as shown in FIG. Then, the internal passages 62 are arranged on both end sides in the stacking direction. When the condenser 13 is configured with such an arrangement pattern and the apparatus is configured such that air flows on the outer periphery of the condenser 13 in the stacking direction, the regenerated air and the condenser 13 that flow through the internal passages 62 arranged at both ends in the stacking direction. The heat exchange with the air flowing on the outer periphery of the heat transfer plate 61 is performed, and all of the heat transfer plate 61a and the heat transfer plate 61b can be used as the heat transfer surface. Conversely, when the same number of heat transfer plates 61a and heat transfer plates 61b are alternately stacked for the first time from the heat transfer plate 61b, the external passages 63 are arranged on both ends in the stacking direction. When the condenser 13 is configured with such an arrangement pattern and a fixing portion or the like that holds the heat transfer plate lamination state is disposed on the outer periphery of the condenser 13 in the lamination direction, the external passages 63 arranged at both ends in the lamination direction The fixed portion disposed in the inner space and the regeneration air flowing through the internal passage 62 arranged on the inner side thereof are thermally insulated, and thermal deformation of the fixed portion due to the high-temperature regeneration air can be suppressed. In this way, the arrangement pattern of the internal passage 62 and the external passage 63 can be set to an optimum arrangement each time according to the device configuration.

  FIG. 8 is an exploded perspective view showing a fixed holding state of the condenser 13. As shown in FIG. 7, the condenser 13 is configured by alternately stacking a predetermined number of heat transfer plates 61a and heat transfer plates 61b, that is, a total of 40 plates. The stacking completion dimension A at this time is a value obtained by multiplying the rib height dimension 3 mm of the spacing ribs 64 a formed on the heat transfer plate 61 a by the number of the heat transfer plates 61 a, that is, 60 mm, and is formed on the heat transfer plate 61 b. The value obtained by multiplying the rib height dimension of 2 mm of the spacing rib 64b by the number of the heat transfer plates 61b, that is, 40 mm, and the thickness of the heat transfer plates 61a and 61b, for example, 0.25 mm, are multiplied by the total number of heat transfer plates. The value, that is, the total value of 10 mm, that is, 110 mm. The case body 69 that stores and fixes and holds the condenser 13 is formed with a storage portion 70 having a width dimension B smaller than the stacking completion dimension A, for example, a width dimension of 105 mm. When the condenser 13 in the heat transfer plate laminated state is inserted into the storage part 70 as indicated by the white arrow, the condenser 13 is brought into contact with a locking part 71 provided on the inner surface of the case body 69 in the storage direction of the condenser 13. The storage is completed upon contact. Since the width dimension B of the storage portion 70 is 5 mm smaller than the stacking completion dimension A in this storage completed state, the pressing force for 5 mm is applied to each of the heat transfer plate 61a and the heat transfer plate 61b in the stacking direction from the stacking direction. Will join. Due to this pressing force, the contact force between the projecting surface of the spacing rib 64a formed on the heat transfer plate 61a and the heat transfer plate 61b in contact with the projecting surface is increased, and the airtightness of the internal passage 62 is improved. The contact force between the projecting surface of the spacing rib 64b formed on the heat transfer plate 61b and the heat transfer plate 61a in contact with the projecting surface is increased, and the airtightness of the external passage 63 is improved.

  Thus, the condenser 13 is accommodated in the heat transfer plate lamination state in the accommodation portion 70 having the width B smaller than the heat transfer plate lamination completion dimension A, and each of the heat transfer plate 61a and the heat transfer plate 61b is laminated in the lamination direction. By pushing from above, the airtightness of the internal passage 62 and the external passage 63 is improved. The difference between the stacking completion dimension A and the width dimension B is 5 mm in the above-described configuration, but this difference is preferably set within a range of 1 to 12 mm. The reason for this is that if the distance is less than 1 mm, the pressing force applied from the stacking direction to each of the heat transfer plate 61a and the heat transfer plate 61b is insufficient in the storage completion state in the storage unit 70, and the internal passage 62 and the external passage 63 This is because the airtightness is reduced. Conversely, if the thickness exceeds 12 mm, the storing operation in the storing unit 70 becomes difficult, and the pressing force applied to each of the heat transfer plate 61a and the heat transfer plate 61b from the stacking direction is excessive. This is because the distance between the internal passage 62 and the external passage 63 cannot be properly maintained. As described above, the airtightness of the internal passage 62 and the external passage 63 tends to decrease as the difference between the stacking completion dimension A and the width dimension B decreases, and conversely, the passage interval between the internal passage 62 and the external passage 63 increases as the difference increases. Is difficult to maintain. Therefore, in order to appropriately secure the airtightness and the passage interval of the internal passage 62 and the external passage 63, the difference between the lamination completion dimension A and the width dimension B is preferably in the range of 1 to 12 mm, and more preferably 2 to 8 mm. It is most desirable to be in the range.

  The heat transfer plate 61a and the heat transfer plate 61b are formed on a flat sheet by vacuum forming, pressure forming, ultra-high pressure forming, press forming, etc., the spacing rib 64a and the spacing rib 64b, the guiding rib 67a and the guiding rib 67b, and the rectifying rib. It is formed by integrally forming uneven portions such as 68, and cutting the sheet on which the uneven portions are formed by pressing a punching die into a shape equal to the outer peripheral shape of each of the heat transfer plate 61a and the heat transfer plate 61b. The It is preferable to use a sheet having a thickness in the range of 0.05 to 0.5 mm as a material for the heat transfer plate 61a and the heat transfer plate 61b. The reason for this is that when the thickness is less than 0.05 mm, breakage such as tearing is likely to occur due to expansion and contraction during molding of the concavo-convex portion or reduction of the strength of the sheet after molding, and the molded heat transfer plate 61a and heat transfer plate 61b. This is because the shape is difficult to maintain due to weakness, and when the thickness exceeds 0.5 mm, the heat transfer is greatly reduced due to an increase in thermal resistance. Thus, as the thickness of the sheet decreases, the formability, strength, and shape maintainability tend to decrease. Conversely, as the thickness of the sheet increases, heat conductivity tends to decrease. Therefore, in order to satisfy all of formability, strength, shape maintenance property and heat transfer property, the thickness of the sheet as the material of the heat transfer plate 61a and the heat transfer plate 61b is in the range of 0.05 to 0.5 mm. Is more preferable, and the range of 0.1 to 0.3 mm is most desirable.

  In addition, as a sheet as a material of the heat transfer plate 61a and the heat transfer plate 61b, for example, a thermoplastic resin material such as polypropylene, polystyrene, polycarbonate, polyethylene terephthalate, acrylonitrile / butadiene / styrene, or high impact polystyrene is used. It is preferable to use it. When such a thermoplastic material is used, the sheet becomes sufficiently soft in the heating process at the time of molding, and can be smoothly stuck to the molding die to easily form the uneven portion. Moreover, as a sheet | seat used as the raw material of the heat-transfer plate 61a and the heat-transfer plate 61b, thin sheet metal, such as aluminum and stainless steel, can also be used, for example. In this case, since high-temperature and high-humidity regeneration air passes through the internal passage 62 side, a metal material having heat resistance and corrosion resistance and rust resistance under high humidity is suitable, and a corrosion-resistant metal thin plate such as aluminum or stainless steel. It is preferable to form a concavo-convex portion by pressing or drawing to the heat transfer plate. When such a metal material is used, the strength of the heat transfer plate is improved, the shape can be easily maintained, and the heat conductivity is several tens of times higher than that of the resin material. The cooling efficiency per sheet can be greatly improved. Therefore, when the condenser 13 is made of a metal material having the same area as the resin material, the dehumidifying performance can be improved by increasing the cooling efficiency. When the cooling efficiency equivalent to that of the resin material is maintained, the condenser 13 is improved. Can be greatly reduced in size.

  FIG. 9 is an exploded perspective view showing a detailed configuration of the heater case 16. The heater case 16 covers a fan-shaped opening surface 74 of a fan-shaped box 73 having a cross-sectional fan shape having a regenerative air inflow portion 72 opened on a side surface with a fan-shaped plate-shaped cover body 75 having a heating opening portion 15 opened. The fan is shaped like a sector-shaped hollow. In addition, a flat flange portion 76 is extended on the periphery of the fan-shaped opening surface 74 of the box 73 so as to match the outer shape of the lid 75, and the radius of the lid 75 is directed toward the box 73. The bent portion 77 is formed by bending the sharp corner. The box 73 and the lid 75 are substantially fixed by inserting the radius of the flange portion 76 provided around the box 73 into the bent portion 77 formed in the radius of the lid 75. . In this substantially fixed state, the box 73 is joined and fixed to the lid 75 by screwing several points of the fan-shaped central portion and the flange portion 76 extending in the outer peripheral direction. In other words, the screwing portion 78 provided on the outer peripheral side of the box 73 and the lid 75 and the screwing portion 79 provided in the fan-shaped central portion of the box 73 and the lid 75 are joined and fixed by screwing. As described above, the box 73 and the lid 75 are screwed in an insertion state in which the box 73 and the lid 75 are substantially fixed to each other, so that workability in the assembly process is improved. Further, in the completed state where the screwing process is completed, the box 73 and the lid body are joined and fixed at the screwing portion 78 provided in the fan-shaped outer peripheral portion and the screwing portion 79 provided in the fan-shaped central portion. The entire surfaces in the radial direction and the outer peripheral direction of 75 abut against each other and air leakage is suppressed. Thus, the airtightness of the heater case 16 is ensured with a simple configuration in which the fan-shaped opening surface 74 of the box 73 formed in a fan-shaped box is covered with the fan-shaped plate-shaped lid 75.

  The heater case 16 is disposed in the housing 1 so that the lid 75 is in close contact with the rotor 12 in a direction facing the rotor 12. Here, the screwing portion 78 and the screwing portion 79 for fixing the box 73 and the lid 75 are located on the outer peripheral side of the rotor 12 and the rotating shaft 36 portion of the rotor 12, and the heater case 16 itself is placed on the opposite surface of the rotor 12. In this state, there is no threaded portion for joining the two. Accordingly, the heating opening 15 is secured in a wide range on the surface of the heater case 16 facing the rotor 12, and the entire ventilation surface of the rotor 12 is opposed to the moisture absorption region through which the air supplied by the fan 20 passes and the heating opening 15. It can be effectively used as a moisture release region. The heater case 16 is disposed so as to face the chamber 19 with the rotor 12 interposed therebetween, and is located on the same circumference as the threaded portion 78 that joins the box 73 and the lid 75 on the outer peripheral side. The rotor 19 is screwed to the chamber 19 at the rotating shaft 36 of the rotor 12 that is joined to the screwed portion 79 that joins the outer peripheral side of the rotor 12, the box 73 and the lid 75 at the fan-shaped central portion. At this time, if the box 73, the lid 75, and the rotary shaft 36 are fastened together and fixed at the threaded portion 79, the number of assembly steps can be reduced.

  A fan-shaped projecting surface 80 projecting in the direction of the rotor 12 is formed on the periphery of the heating opening 15 of the lid 75. The projecting surface 80 is disposed so as to face the peripheral wall surface 37 that forms the fan-shaped cross section of the chamber 19 when the heater case 16 is attached, and the distance between the projecting surface 80 and the peripheral wall surface 37 is the same as the heater case 16 and the chamber. Nineteen intervals will be defined. Therefore, as described above, by setting the distance between the projecting surface 80 and the peripheral wall surface 37 to be a predetermined value, that is, within a range of 0.3 to 1.5 mm with respect to the thickness of the rotor 12, smooth rotation operation of the rotor 12 is achieved. In addition to ensuring, it is possible to improve the dehumidification efficiency by suppressing air leakage from the gaps between the rotor 12 and the projecting surface 80 and between the rotor 12 and the peripheral wall surface 37. As described above, when the distance between the projecting surface 80 and the peripheral wall surface 37 is less than 0.3 mm with respect to the thickness of the rotor 12, the rotation operation of the rotor 12 cannot be performed smoothly. On the other hand, if the distance is 1.5 mm or more, air leakage from the gap between the rotor 12 and the projecting surface 80 and the gap between the rotor 12 and the peripheral wall surface 37 increases, and the dehumidification efficiency decreases. Thus, the drivability of the rotor 12 tends to decrease as the distance between the projecting surface 80 and the peripheral wall surface 37 becomes narrower. Conversely, as the distance between the projecting surface 80 and the peripheral wall surface 37 increases, the amount of air leakage increases and dehumidification occurs. Efficiency tends to decrease. Therefore, in order to satisfy the drivability and the dehumidifying efficiency of the rotor 12, it is preferable that the gap between the projecting surface 80 and the peripheral wall surface 37 is formed wide in the range of 0.3 to 1.5 mm with respect to the thickness of the rotor 12. Further, it is most desirable to form the rotor 12 widely in the range of 0.5 to 1.0 mm with respect to the thickness of the rotor 12.

  Nichrome wire is used for the heater 14, and the heater 14 is fixed and held by a heater frame 81 installed in the heater case 16. The heater frame 81 is provided with a heater housing portion 82 having a pentagonal cross section for housing the heater 14 in an insulated state from the heater case 16 in a hollow state, and a plurality of the heater frames 81 are installed in the heater housing portion 82 in the radial direction and the circumferential direction. The insulated support plate 83 supports the heater 14 made of nichrome wire so as to be close to the heating opening 15. As a result, insulation of the heater 14 is ensured and radiant heat is stably supplied from the heating opening 15 to the rotor 12. Further, the pentagonal bottom surface portion of the heater accommodating portion 82 is formed by a mirror-like reflecting plate 85 made of a highly reflective metal plate, for example, aluminum or stainless steel. The reflection plate 85 reflects the radiant heat of the heater 14 irradiated to the bottom of the heater accommodating portion 82 toward the rotor 12, thereby promoting moisture release from the rotor 12.

  A branch air passage 84 is formed around the heater frame 81 in the heater case 16 to allow the regenerated air flowing into the heater case 16 from the inflow portion 72 to pass therethrough as indicated by an arrow. The regenerative air supplied to the branch air passage 84 recovers the radiant heat of the heater 14 irradiated in the heater case 16 and raises the temperature, while passing through the gap between the heating opening 15 and the heater frame 81 and the rotor. 12 is supplied. As a result, the amount of heat that should leak to the outside of the heater case 16 is recovered by the regenerated air supplied to the branch air passage 84 and is reused for moisture release from the rotor 12, thereby reducing the energy loss of the heater 14. A part of the regenerated air flowing through the branch air passage 84 is supplied into the heater accommodating portion 82 from the ventilation holes 86 opened on the bottom and side surfaces of the heater accommodating portion 82. The regenerative air supplied into the heater accommodating portion 82 takes away the heat staying in the heater accommodating portion 82 and is supplied from the heating opening 15 to the rotor 12. Accordingly, the amount of heat that should stay in the heater accommodating portion 82 is recovered by the regeneration air supplied from the ventilation holes 86 and used for moisture release from the rotor 12, so that the energy loss of the heater 14 is reduced and the heater accommodating portion 82 is reduced. The temperature rise inside is also suppressed.

  FIG. 10 is a simplified horizontal sectional view showing the operation of the dehumidifier. When the operation of the dehumidifier is instructed through an operation unit (not shown), the fan 20, the circulation fan 17, the drive motor 58, and the heater 14 are driven. First, air is sucked into the housing 1 from the air inlet 3 by driving the fan 20. At this time, dust in the air is removed by the filter 2 attached to the air inlet 3. The air sucked into the housing 1 is supplied to a rotor 12 and a condenser 13 that are juxtaposed in the horizontal direction on the windward side of the fan 20 in the long side direction of the housing 1. Since this air is divided into the rotor 12 and the condenser 13 and flows in parallel in the direction of the short side of the housing 1, the ventilation resistance is dispersed in parallel and the ventilation distance is shortened, and the in-machine resistance against the fan 20 is reduced. As a result, the air flow rate of the fan 20 increases. The air diverted to the rotor 12 side is supplied to the rotor 12 without receiving heat of condensation. Accordingly, there is no decrease in the moisture absorption efficiency in the rotor 12, and the supplied air is removed from the humidity and given heat of adsorption to become high temperature and low humidity. On the other hand, the air diverted to the condenser 13 side is supplied to the external passage 63 of the condenser 13 without receiving adsorption heat. Accordingly, there is no reduction in cooling efficiency in the condenser 13, and the supply air cools the regenerated air flowing through the internal passage 62 to remove condensation heat and reach a high temperature. The high-temperature and low-humidity air absorbed by the rotor 12 and the high-temperature air deprived of condensation heat by the condenser 13 are both sucked into the fan 20, stirred, and discharged from the exhaust port 7. This exhausted air is a mixed air of air that has been sufficiently absorbed without lowering the moisture absorption efficiency in the rotor 12 and air that has sufficiently deprived the heat of condensation without lowering the cooling efficiency in the condenser 13, and has high dryness. Have. Further, as described above, since the air volume is sufficiently secured by the reduction of the in-machine resistance with respect to the fan 20 as described above, this high dryness and large air volume exhaust air is supplied from the exhaust port 7 to the drying object such as clothing. Then, extremely high drying efficiency can be obtained.

  On the other hand, the rotor 12 that has absorbed moisture moves to the circulation path 29 by driving the drive motor 58 and is heated by the heater 14 to release moisture. Here, the heater 14 irradiates the rotor 12 with radiant heat from the windward side with respect to the wind direction of the air supplied to the rotor 12 by the fan 20. Therefore, radiant heat is applied to the upstream portion 87 of the rotor 12 located on the windward side of the fan 20. The upstream portion 87 of the rotor 12 is a portion that first comes into contact with the air supplied by the fan 20 and is a portion that absorbs a large amount of moisture from the air and retains a large amount of moisture. Since the radiant heat of the heater 14 is irradiated to the upstream portion 87 of the rotor 12 that holds a large amount of moisture, the amount of moisture released from the rotor 12 due to direct irradiation of the radiant heat increases, and the radiant heat is effective in releasing moisture. Will be used. The moisture released from the rotor 12 is contained in the high-temperature regenerated air heated by the heat generated by the heater 14 in the heater case 16. The high-humidity regeneration air containing moisture is received by the chamber 19 and then flows into the internal passage 62 of the condenser 13 and is cooled by the air supplied by the fan 20 to saturate the moisture. The regenerated air from which moisture has been removed by the condenser 13 is sucked into the circulation fan 17 and returns to the heater case 16 to circulate through the circulation path 29.

  Here, the heater case 16 and the chamber 19 are each provided with a predetermined gap between the heater 12 and the rotor 12 in order to facilitate smooth rotation of the rotor 12. Therefore, the circulation path 29 communicates with the air blowing path of the fan 20 through this gap, and an air transition between the regenerated air and the air blown by the fan 20 occurs. For example, when the wind speed of the regenerated air passing through the rotor 12 is slower than the wind speed of the air supplied to the rotor 12 by the fan 20, that is, when the air pressure loss of the rotor 12 on the circulation path 29 side is low, the heater case 16 and the rotor 12 Air enters the circulation path 29 from the outside at the gap 88, and flows out from the inside of the circulation path 29 to the outside at the gap 89 between the chamber 19 and the rotor 12. In this case, all the heat of the heater 14 is supplied to the rotor 12 without leaking outside the circulation path 29. Further, when the wind speed of the regeneration air passing through the rotor 12 is higher than the wind speed of the air supplied to the rotor 12 by the fan 20, that is, when the air pressure loss of the rotor 12 on the circulation path 29 side is high, the heater case 16 and the rotor 12 Air flows out from the circulation path 29 in the gap 88, and air flows into the circulation path 29 from the outside in the gap 89 between the chamber 19 and the rotor 12. In this case, a part of the heat of the heater 14 is once leaked to the outside of the circulation path 29 as the air flows out. This leaked heat is before and after the rotation of the heater case 16 of the rotor 12 as indicated by the dotted line. Is supplied to a portion close to the rotor 12, flows into the chamber 19 from the gap 89 between the chamber 19 and the rotor 12 on the downstream side of the rotor 12, and is collected in the circulation path 29. As described above, even if air circulation between the circulation path 29 and the outside occurs before and after the rotor 12, most of the heat amount of the heater 14 is utilized for moisture release from the rotor 12 to reduce energy loss. Thereby, extremely high dehumidification efficiency is obtained.

  As described above, the dehumidifying apparatus of the present embodiment has the following effects by adopting such a configuration.

  That is, the air supplied from the intake port 3 is divided into each of the rotor 12 and the condenser 13 and flows in parallel, thereby reducing the ventilation resistance and supplying a large amount of air.

  Further, the first duct 27 is disposed above the rotor 12 and the second duct 28 is disposed below the rotor 12, thereby eliminating the ventilation resistance of the duct in the air blowing path of the fan 20 and further increasing the amount of air supplied to the rotor 12. Can be increased.

  Moreover, the fall of moisture absorption efficiency can be suppressed by supplying the air attracted | sucked from the inlet 3 to the rotor 12 without giving condensation heat.

  Further, by supplying the air sucked from the intake port 3 to the condenser 13 without applying adsorption heat, it is possible to suppress a decrease in cooling efficiency.

  In addition, a sufficient air volume is ensured by reducing the ventilation resistance, and the drying efficiency is drastically improved by supplying air with high dryness from the exhaust port 7 to the object to be dried without lowering the moisture absorption efficiency and the cooling efficiency. can do.

  In addition, since the intake port 3 can be opened only on one side of the housing 1, restrictions on the installation location are reduced, and usability can be improved.

  In addition, by forming the first duct 27 with a downward slope, water droplets condensed in the first duct 27 are guided along the downward slope to the chamber 19 or the internal passage 62, and the water droplets stay in the first duct 27. Can be suppressed.

  Further, the condensed water generated in the circulation path 29 is collected in the second duct 28 and drained from one place of the drain port 30 to the tank 4, so that the occurrence of water leakage can be suppressed.

  Moreover, when the tank 4 is not attached, the drain port 30 is closed by the stopper 31, and dripping from the drain port 30 can be prevented.

  Moreover, the condensed water condensed inside the circulation casing 18 can be dripped to the 2nd duct 28 through the drain hole 33, and the condensation water retention in the circulation casing 18 can be suppressed.

  Further, the condensed water condensed in the chamber 19 can be dropped onto the second duct 28 through the communication pipe 32, and the condensed water staying in the chamber 19 can be suppressed.

  In addition, by disposing the heater case 16 above the circulation casing 18, it is possible to suppress the inflow of condensed water condensed in the circulation casing 18 into the heater case 16.

  In addition, by providing the heat shield member 45 on the regeneration air discharge side of the circulation casing 18, thermal deformation of the circulation casing 18 due to heat radiation of the heater 14 can be suppressed.

  Further, by forming the surface of the circulation casing 18 facing the rotor 12 with a metal plate, thermal deformation of the circulation casing 18 due to heat radiation from the rotor 12 can be suppressed.

  Further, by disposing the circulation casing 18 on the rear stage side of the heater 14 in the rotation direction of the rotor 12, dew condensation in the circulation casing 18 can be suppressed.

  Further, by opening a connection port 38 to the first duct 27 on a surface different from the surface facing the heating opening 15 of the chamber 19 to which the radiant heat of the heater 14 is irradiated through the rotor 12, the first duct due to the radiant heat is provided. 27 deformation can be suppressed.

  In addition, the heat shield plate 39 disposed in the chamber 19 so as to face the heating opening 15 can shield the radiant heat of the heater 14 and suppress thermal deformation of the chamber 19.

  Further, the radiant heat irradiated into the chamber 19 can be reflected to the rotor 12 side by the mirror-like heat shield plate 39 to further promote moisture release from the rotor 12.

  Further, by forming at least one of the chamber 19, the circulation casing 18, and the first duct 27 with a heat resistant resin, thermal deformation during abnormal operation can be suppressed.

  The contents described above are only described for one mode for carrying out the invention, and the present invention is not limited to the above embodiment.

  For example, although the horizontal cross-sectional shape of the housing 1 is substantially elliptical, it may be a rectangular shape or a hexagonal shape as long as it has at least one pair of long side and short side.

  Further, although the first shielding wall 59 that covers the concave portion of the gear 48 is formed integrally with the frame A49, it may be formed integrally with the frame B54.

  Further, although the first duct 27 is formed in a downward gradient toward the condenser 13 side, it may be formed in a downward gradient toward the chamber 19 side or both sides of the condenser 13 and the chamber 19.

  In addition, the heat transfer plate is inserted into the case body 69 having a width dimension smaller than the heat transfer plate stacking completion dimension in a stacked state to press each of the heat transfer plate 61a and the heat transfer plate 61b. It is good also as a structure which fits and presses an elastic body to a heat exchanger plate.

  Further, although nichrome wire is used as the heater 14, any heater that can radiate radiant heat to any degree may be used, and a halogen heater, a carbon heater, a sheathed heater, a ceramic heater, or the like may be used.

  As described above, the dehumidifier according to the present invention has no decrease in the moisture absorption efficiency of the rotor and the cooling efficiency of the condenser, and reduces the in-machine resistance to increase the drying efficiency by supplying a large amount of air, thereby restricting the installation location. In applications where high-performance dehumidifying operation is desired, such as dehumidifiers, dryers, clothes dryers, clothes dryers, bathroom dryers, air conditioners or solvent recovery devices Suitable for

1 is a perspective view of a dehumidifier according to Embodiment 1 of the present invention. Same as above, exploded perspective view of dehumidifier Same as above, a cross-sectional view of the long side of the dehumidifier cut in the vertical direction on the suction surface side Same as above, a cross-sectional view of the long side of the dehumidifier cut in the vertical direction on the suction reverse side The exploded perspective view of the main internal parts of the dehumidifier The exploded perspective view of the rotor mounted on the dehumidifier Same exploded perspective view of the condenser mounted on the dehumidifier The exploded perspective view showing the fixed holding state of the condenser mounted on the dehumidifier The exploded perspective view of the heater case mounted on the dehumidifier Same horizontal cross section showing operation of dehumidifier

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Housing 3 Intake port 4 Tank 7 Exhaust port 12 Rotor 13 Condenser 14 Heater 15 Heating opening 16 Heater case 17 Circulating fan 18 Circulating casing 19 Chamber 20 Fan 27 First duct 28 Second duct 29 Circulating path 30 Drain port 31 Stopper 32 Communication pipe 33 Drain hole 38 Connection port 39 Heat shield plate 45 Heat shield member 56 Drive means 62 Internal passage

Claims (14)

In a housing (1) having an intake port (3) and an exhaust port (7) opened, a fan (20) that intakes air from the intake port (3) and exhausts air from the exhaust port (7), and the fan (20 ), A disk-shaped rotor (12) that absorbs moisture from the air sucked in, a drive means (56) for rotating the rotor (12), and a regenerative air to be circulated through a part of the rotor (12). A circulation path (29), a circulation fan (17) that circulates regeneration air in the circulation path (29), a heater (14) that releases moisture from the rotor (12) in the circulation path (29), Regenerative air, which is disposed in parallel with the rotor (12) with respect to the wind direction of the fan (20) and contains moisture released by the rotor (12), is cooled and condensed by the air supplied by the fan (20). Clump And a tank (4) for storing the condensed water recovered by the condenser (13), and the circulation path (29) is provided in a circulation casing (18) containing the circulation fan (17). ), A heater case (16) that houses the heater (14) and opens a fan-shaped heating opening (15) facing the rotor (12), and the heating opening across the rotor (12) A regenerative air is circulated in the order of a fan-shaped chamber (19) opposed to (15) and an internal passage (62) through which the regenerative air passes in the condenser (13), and the chamber (19) and the A first duct (27) connecting the internal passage (62) is disposed above the rotor (12), and a second duct (28) connecting the internal passage (62) and the circulation casing (18). It was arranged below the rotor (12), dehumidifiers. The dehumidifier according to claim 1, wherein the first duct (27) is formed to have a downward slope toward one or both of the chamber (19) and the internal passage (62). The dehumidifier according to claim 1 or 2, wherein a drainage port (30) for guiding the condensed water generated in the circulation path (29) to the tank (4) is formed in the second duct (28). The dehumidifier according to claim 3, further comprising a stopper (31) for closing the drain port (30) when the tank (4) is not attached. The dehumidifier according to any one of claims 1 to 4, wherein a drain hole (33) is opened at a lowermost part of the circulation casing (18), and the drain hole (33) is connected to the second duct (28). The dehumidifier according to any one of claims 1 to 5, further comprising a communication pipe (32) communicating the chamber (19) and the second duct (28). The dehumidifier according to any one of claims 1 to 6, wherein the heater case (16) is disposed above the circulation casing (18). The dehumidifier according to any one of claims 1 to 7, wherein a heat shield member (45) for shielding heat from the heater (14) is attached to the regeneration air discharge side of the circulation casing (18). The dehumidifier according to any one of claims 1 to 8, wherein a surface of the circulation casing (18) facing the rotor (12) is formed of a metal plate. The dehumidifier according to any one of claims 1 to 9, wherein the circulation casing (18) is disposed on the rear side of the heater (14) in the rotation direction of the rotor (12). The dehumidifier according to any one of claims 1 to 10, wherein a connection port (38) to the first duct (27) is opened on a surface other than the surface facing the heating opening (15) of the chamber (19). The heat shield (39) according to any one of claims 1 to 11, wherein a heat shield (39) for shielding the radiant heat of the heater (14) is disposed in the chamber (19) so as to face the heating opening (15). Dehumidifier. The dehumidifier according to claim 12, wherein the heat shield plate (39) is formed of a mirror metal plate that reflects the radiant heat of the heater (14) toward the rotor (12). The chamber (19), the circulation casing (18), or the first duct (27) is formed of a heat resistant resin such as polyethylene terephthalate or polyphenylene sulfide, for example. Dehumidifier as described.

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