KR20050084736A - The dehumidification device using desiccant - Google Patents

Abstract

The present invention relates to a humidification and dehumidification apparatus using desiccant, which is a dehumidification process of removing moisture by absorbing or adsorbing moisture from ambient air at a low temperature, and dehumidification at a high temperature. A desiccant, which is a regeneration process of evaporating and removing moisture adsorbed by using dry air, is formed as an energization heating element, and an electrode necessary for energization is installed in the energization heating element so that electricity is supplied when the desiccant is regenerated. The direct heating method of the heating element to remove moisture adsorbed to the desiccant, there is an excellent effect that can significantly reduce the heat loss compared to the indirect heating method of the conventional desiccant.

In addition, by heating the desiccant through the direct heating method as described above, it is possible to significantly reduce the regeneration time of the desiccant according to the conventional, and at the same time, the switched regeneration when switching the position between the regeneration unit and the adsorption unit There is also an excellent effect of maximizing the water content (water adsorption amount) per unit area such that water in the air passing through the side can be completely removed.

Furthermore, by dividing the desiccant into several areas according to the adsorption capacity during the compression molding of the desiccant, it is possible to change the regeneration area of the desiccant by changing the area of the desiccant adsorption part and the regeneration part under partial load. It also works.

Description

Humidification and dehumidifier using desiccant {The dehumidification device using desiccant}

The present invention relates to a dry dehumidifier, and more particularly, to a dehumidification process of removing moisture by absorbing or adsorbing moisture from ambient air at a low temperature, and drying air dehumidified at a high temperature. The desiccant, which is a regeneration process of evaporating and removing the adsorbed moisture, is formed as an energizing heating element, and an electrode necessary for energizing is installed in the energizing heating element to generate heat through the energizing heating element when the desiccant is regenerated. It relates to a humidification and dehumidification apparatus using desiccants, such as to remove moisture adsorbed to the desiccant.

Generally, in a humidification and dehumidification apparatus using desiccant, the desiccant refers to a substance having a strong affinity for moisture and capable of directly absorbing moisture from ambient air. Affinity is regenerated repeatedly by applying heat to the desiccant to evaporate the adsorbed moisture.

At this time, the moisture adsorption of the desiccant is dependent on the moisture partial pressure in the wet air and the vapor pressure difference of the desiccant surface. In particular, the moisture content of the desiccant is a function of the relative humidity of the ambient air and the concentration and temperature of the restraint, When exposed to air at relative humidity, the desiccant reaches equilibrium with low moisture content, and exposure to high relative humidity air results in high moisture content. That is, the desiccant sucks moisture when the vapor pressure of the desiccant surface is lower than the partial pressure of ambient air, and the desiccant discharges moisture when the vapor pressure of the desiccant surface is higher than the partial pressure of air.

Moreover, the moisture absorbed in the desiccant is dehumidified by heating of a regenerative heat source according to the required humidity of the treated air to be removed to exhaust air.

Humidification and dehumidification apparatus using the desiccant of this action, as shown in Figure 1, the filter 10 for filtering the dust mixed in the outside air; A blower (12) for blowing air filtered by the filter (10) to the desiccant (20); It is formed in the shape of a disc, the adsorption portion (23a) for adsorbing the moisture of the air blown by the blower 12 through the blocking film 22, and the moisture adsorbed using the heated dehumidification (dry) air A desiccant 20 partitioned into a regeneration unit 24a to be used; A treated air blower (30) which blows the dehumidified air into which the moisture is removed through the adsorption unit (23a) of the desiccant (20); A heater 32 for heating the dehumidified air flowing from the room before passing through the regeneration unit 24a of the desiccant 20 to a high temperature of about 120 ° C to 140 ° C; It is composed of a regeneration air blower 34 for discharging the air (high temperature and high humidity) evaporated moisture adsorbed to the regeneration unit 24a of the desiccant 20 to the outside.

At this time, the desiccant 20 is rotated on the outer circumferential surface of the desiccant 20 at a low speed by a rotational force of the driving motor 26 so that the suction unit 23a and the regeneration unit 24a of the desiccant 20 are rotated. The drive belt 27 is installed to convert each position of the predetermined angle, the drive belt 27 is rotated by the drive motor 26.

In addition, the desiccant 20 partitioned into the adsorption unit 23a and the regeneration unit 24a through the blocking film 22 is a component that plays the most important role in adsorbing the moisture of air, and alternately the corrugated paper of the ceramic fiber alternately. A cylindrical rotor wound up, coated with a silica gel (Sillcagel) inside, the surface of the adsorption portion of the desiccant 20 is formed by a plurality of fine holes 25 of about 20 × 10 ^-7 mm Water molecules in the air passing through 23a are easily adsorbed.

Furthermore, in the case of the desiccant 20, the area ratio between the regeneration unit 24a and the adsorption unit 23a by the blocking film 22 is about 1: 1, which is a blocking film formed on the desiccant 20. 22) the forming angle is 180 °.

Referring to the operating state of the humidification and dehumidification apparatus using the desiccant 20 as follows.

First, the dust mixed with the outside air is filtered using the filter 10, and then the air filtered by the desiccant 20 is blown through the blower 12, at which time the blown to the desiccant 20 When the compressed air passes through the adsorption unit 23a of the desiccant 20 partitioned into the adsorption unit 23a and the regeneration unit 24a through the blocking film 22, a large number of formed air is about 20 × 10 ^−7. As the water molecules in the air are adsorbed to the fine holes 25 mm, the dehumidified air is changed into dehumidified air, and the changed dehumidified air is treated air installed behind the adsorption portion 23a of the desiccant 20. The air is blown into the room through the blower 30. At this time, before the air is blown into the room, the air is blown into the room by adjusting the temperature and humidity to achieve a comfortable state required by the room through an evaporative cooler (not shown). The dehumidified air makes the room a pleasant state.

Meanwhile, the dehumidifying air blown into the room to make the room comfortable is flowed through the flow path (not shown) to the regeneration unit 24a of the desiccant 20. At this time, the dehumidifying air of the desiccant 20 Prior to passing through the regeneration unit 24a, the desiccant 20 rotates at a predetermined angle (about 180 °) as the drive belt 27 is rotated by the drive motor 26 at predetermined time intervals. Dehumidified air flowed from the room through the heater 32 to evaporate moisture adsorbed to the regeneration unit side 24 in a state where the unit 23a is switched to the regeneration unit side 24. After heating to about ℃, it passes through the regeneration unit side 24 of the desiccant 20.

When the dehumidified air heated as described above passes through the regeneration unit side 24 of the desiccant 20, hot dehumidified air evaporates moisture adsorbed to the regeneration unit side 24, and the high temperature dehumidified air The regeneration unit side 24 of the desiccant 20 is changed into a dry state while the water is completely evaporated.

Then, the heated dehumidified air (high temperature and high humidity air) evaporated while passing through the regeneration unit side 24 of the desiccant 20 as described above is discharged to the outside through the regeneration air blower 34 to the desiccant 20. The operation state of the humidification and dehumidification apparatus using) is terminated.

However, in the humidification and dehumidification apparatus using the desiccant 20, the method of regenerating the desiccant 20 by evaporating the moisture of the adsorption part 23a switched to the regeneration part side 24 is described above. As described above, the dehumidified air flowing from the room through the heater 32 is heated to about 120 ° C. to 140 ° C., and then passed to the regeneration unit side 24 of the desiccant 20 using the heated dehumidified air. Since an indirect heating method such as evaporating moisture adsorbed to the regeneration unit side 24 is used, it is more heat than the direct heating method of directly heating the regeneration unit side 24 of the desiccant 20 through the heater 32. There is a big problem that the loss is very large.

In addition, when using the indirect heating method to heat the dehumidification air before passing through the regeneration unit side 24 as described above, and to heat the regeneration unit side 24 of the desiccant 20 using the heated dehumidification air. There was also a big problem such that the regeneration unit side 24 of the desiccant 20 was heated to be regenerated in a dry state for a very long time.

Furthermore, as the desiccant 20 rotates at a predetermined time or continuously according to the rotation of the drive belt 27 by the drive motor 26, the suction unit 23a and the regeneration unit 24a of the desiccant 20 are rotated. When the position of the liver is switched, the regeneration unit 24 according to the indirect heating method takes a long time, and the position between the regeneration unit 24a and the adsorption unit 23a is not changed completely. There was also a big problem that the water content per unit area for removing moisture in the air passing through the switched regeneration section 24 was significantly lowered.

The present invention devised to solve the above problems, the dehumidification process of removing moisture by absorbing or adsorbing moisture from the ambient air at a low temperature, and dry air dehumidified at a high temperature The desiccant, which is a regeneration process of evaporating and removing the adsorbed moisture, is formed as an energization heating element, and an electrode necessary for energization is installed in the energization heating element to configure the desiccant. The purpose of the present invention is to directly reduce the heat loss compared to the indirect heating method of the conventional desiccant, such as to remove moisture adsorbed to the desiccant through the direct heating method.

In addition, by heating the desiccant through the direct heating method as described above, it is possible to significantly reduce the regeneration time of the desiccant according to the conventional, and at the same time, the switched regeneration when switching the position between the regeneration unit and the adsorption unit Another purpose is to maximize the water content (water adsorption amount) per unit area, such as water in the air passing through the side can be completely removed.

Furthermore, by dividing the desiccant into several regions according to the adsorption capacity during the compression molding of the desiccant, the regeneration area of the desiccant can be varied by changing the area of the desiccant adsorption and regeneration portions under partial load. There is another purpose.

The object of the present invention is desiccant, which includes a dehumidification process of removing moisture by absorbing or adsorbing moisture from ambient air, and a regeneration process of evaporating and removing the adsorbed moisture. The desiccant of the present invention is configured to form a desiccant as an energizing heating element and to remove moisture adsorbed to the desiccant through direct heating of the energizing heating element during the regeneration of the desiccant by installing an electrode necessary for energization in the energizing heating element. It can be solved by the humidification and dehumidification apparatus used, it will be described in detail with reference to the accompanying drawings.

Figure 3 shows a schematic structural diagram and detail of the humidification and dehumidification apparatus using the desiccant of the present invention, Figure 4 shows a structural diagram of the desiccant press-molded by the energizing heating element of the present invention.

Humidification and dehumidification apparatus using the desiccant 120 of the present invention, the filter 10 for filtering the dust mixed in the outside air;

A blower (12) for blowing air filtered by the filter (10) to a desiccant (120);

The pressurized material (Material) that is generated when energized in the form of a single plate, the adsorption portion (123a) for adsorbing the moisture of the air blown from the blower 12 through the blocking film 122, and the adsorbed moisture A desiccant 120 partitioned into a regeneration unit 124a for evaporating;

Each of the adsorption unit 123a and the regeneration unit is configured to conduct electricity to the desiccant 120 so as to heat the portion corresponding to the regeneration unit side 124 of the desiccant 120 through evaporation to evaporate the adsorbed moisture. A plurality of electrodes 129 provided at both ends of 124a;

A treatment air blower 30 for blowing the dehumidified air into which the moisture is removed through the adsorption part 123a of the desiccant 120;

The regeneration unit 124a of the desiccant 120 is characterized by consisting of a regeneration air blower 34 for discharging the air (high temperature and high humidity) evaporated to the outside.

At this time, the desiccant 120 is characterized in that the conducting heating element (A) is a heat-generating action when the power is applied.

In addition, the desiccant 120 is characterized in that divided into several areas by varying the degree of compression in accordance with the adsorption capacity during the compression molding.

In addition, the desiccant 120 further includes one or more temperature sensors 128 to measure the temperature of the regeneration unit side 124 to determine the switching time of the adsorption unit 123a and the regeneration unit 124a. Characterized in that provided.

Hereinafter, a humidification and dehumidification apparatus using the desiccant of the present invention will be described in detail.

Humidification and dehumidification apparatus using the desiccant of the present invention, the heat loss is significantly reduced compared to the indirect heating method of the conventional desiccant 20, and greatly shortens the regeneration time of the desiccant 20, in particular Moisture content per unit area such that moisture in the air passing through the switched regeneration unit 24 can be completely removed when the position is switched between the regeneration unit 24a and the adsorption unit 23a of the desiccant 20. In order to maximize the (moisture adsorption amount), the desiccant 120 in which the dehumidification process and the regeneration process are performed is formed as the energizing heating element A, and the electrode 129 required for energizing the energizing heating element ( Installed in A) to remove moisture adsorbed to the desiccant 120 through the direct heating method of the energizing heating element A during regeneration of the desiccant 120, the present invention will be described in detail. The same reference numerals will be applied to the same configurations as those of the present invention and the conventional art described above.

In describing the humidifying and dehumidifying apparatus using the desiccant 120 of the present invention, since the description of the desiccant 120 has been described in detail in the related art, the detailed description of the present invention will be omitted in order to avoid duplicate descriptions. Let's do it.

Humidification and dehumidification apparatus using the desiccant of the present invention, as shown in Figure 3, the filter 10 for filtering the dust mixed with the outside air; A blower (12) for blowing air filtered by the filter (10) to a desiccant (120); The pressurized material (Material) that is generated when energized in the form of a single plate, the adsorption portion (123a) for adsorbing the moisture of the air blown from the blower 12 through the blocking film 122, and the adsorbed moisture A desiccant 120 partitioned into a regeneration unit 124a for evaporating; Each of the adsorption unit 123a and the regeneration unit is configured to conduct electricity to the desiccant 120 so as to heat the portion corresponding to the regeneration unit side 124 of the desiccant 120 through evaporation to evaporate the adsorbed moisture. A plurality of electrodes 129 provided at both ends of 124a; A treatment air blower 30 for blowing the dehumidified air into which the moisture is removed through the adsorption part 123a of the desiccant 120; It is composed of a regeneration air blower 34 for discharging the air (high temperature and high humidity) evaporated moisture adsorbed to the regeneration unit 124a of the desiccant 120 to the outside.

At this time, the desiccant 120 is rotated on the outer circumferential surface of the desiccant 120 at a low speed through the rotational force of the drive motor 126, similarly to the driving motor 26 and the driving belt 27 described in the prior art. The driving belt 127 is installed to convert each position of the adsorption unit 123a and the regeneration unit 124a of the desiccant 120 to a predetermined angle, and the driving belt 127 is a driving motor ( 126).

In addition, the desiccant 120 partitioned into the adsorption part 123a and the regeneration part 124a through the blocking film 122 is formed by pressing and forming a current-carrying heating element A having a heat generating action when energized in a disc shape. In the case of the energizing heating element A, the resistance heating element is heated while electricity is supplied to the resistance heating element (heat plate) through the electrode 129 which is necessary for energizing, and the desiccant is generated by the heating of the heated resistance heating element. Moisture adsorbed on the regeneration unit side 124 of the 120 is evaporated, and the moisture-containing capacity and the amount of heat generated at the time of energization are proportional to the compressive force during the compression molding of the energized heating element A. FIG.

In addition, a plurality of minute holes (not shown) are formed on a surface of the desiccant 120 formed by compression molding the energizing heating element A, so that water in the air passing through the adsorption part 123a of the desiccant 120 is formed. The molecules are configured to be easily adsorbed.

Furthermore, in the case of the desiccant 120, the area ratio between the regeneration unit 124a and the adsorption unit 123a by the blocking film 122 is about 1: 1, which is a blocking film formed on the desiccant 120. The formation angle of 122) is 180 degrees.

In addition, one or more temperature sensors 128 are installed in the desiccant 120, which measures the temperature of the regeneration unit side 124 of the desiccant 120 to detect the adsorption unit 123a and the regeneration unit 124a. ) Is to determine the time of switching, and by measuring the temperature of the regeneration unit side 124 of the desiccant 120 through the temperature sensor 128, the adsorption unit 123a and the regeneration unit 124a by the measured temperature. When it is determined by the control unit (not shown) between the switching point, as described above, the drive belt 127 wound on the outer peripheral surface of the desiccant 120 is rotated by the rotational force of the drive motor 126, the drive As the desiccant 120 rotates according to the rotation of the belt 127, the respective positions of the adsorption part 123a and the regeneration part 124a of the desiccant 120 are switched at a predetermined angle of about 180 °.

Figure 5 shows another embodiment of the desiccant according to the present invention, Figure 6 is a state showing the change state of the water adsorption capacity according to the degree of compression when forming the desiccant according to the present invention, which is FIGS. As shown in Fig. 6, the desiccant is configured by dividing the desiccant into several regions by varying the degree of crimping according to the adsorption capacity during the compression molding.

In the case of the desiccant 220, the adsorption part 223a, 223b and the regeneration part 224a, 224b of the state of having a high water content and a small state according to the adsorption capacity at the time of compression molding are divided into 4 regions (4). And the adsorption unit 223a and the regeneration unit 224a in the state of high water content are partitioned in diagonal directions, respectively, and the adsorption unit 223b and the regeneration unit 224b in the state of low water content. ) Is also divided in a diagonal direction to each other similarly to the adsorption unit 223a and the regeneration unit 224a in the state of high water content.

At this time, the desiccant 220 is formed by compression-molding the energizing heating element A having a heat generating action when energizing, similarly to the desiccant (see FIG. 4) 120 structure of the present invention. .

In addition, the desiccant 220 may further measure one or more temperature sensors 228 so as to determine the switching time of the adsorption unit 223a and the regeneration unit 224a by measuring the temperature of the regeneration unit side 224. It is provided.

Referring to the operating state of the humidification and dehumidification apparatus using the desiccant as follows.

7 is an operational state diagram of the humidification and dehumidification apparatus using the desiccant of the present invention.

First, in the case of the humidification and dehumidification apparatus using the desiccant of the present invention, the dehumidification process of the desiccant 120 and the cycle of the regeneration process, but first as the dehumidification process of the desiccant 120, as shown in FIG. Likewise, by filtering the dust mixed in the outside air using the filter 10, and then blows the filtered air to the desiccant 120 through the blower 12, at this time blowing to the desiccant 120 As shown in FIG. 7 (a), the deacon 120 is divided into the adsorption unit 123a and the regeneration unit 124a through the blocking film 122, that is, the energized heating element A. When passing through the adsorption part 123a of the desiccant 120 press-molded into a disc shape, water molecules in the air are adsorbed to a plurality of minute holes formed on the surface, and the desiccant 120 is referred to based on the blocking film 122. The adsorption part 123a has a state containing moisture in the air, The dehumidified air is changed as described above, the dehumidified air is blown into the room through the processing air blower 30 installed behind the adsorption unit 123a of the desiccant 120, at which time it is blown into the room. By adjusting the temperature and humidity to achieve a comfortable state required indoors through an evaporative cooler (not shown) and then blowing it into the room, the indoors are made comfortable by the dehumidified air.

Next, as a regeneration process of the desiccant 120, the dehumidifying air is blown into the room in a state in which water is removed through the adsorption unit 123a of the desiccant 120 to make the room comfortable. (Not shown) flows to the regeneration unit side 124 of the desiccant 120, at which time the dehumidification air before passing through the regeneration unit side 124 of the desiccant 120. It measures the temperature of the regeneration unit 124a before the position is switched by the temperature sensor 128 installed in the and the switching time between the adsorption unit 123a and the regeneration unit 124a by the measured temperature. The control unit determines.

At this time, if it is determined that the switching between the adsorption unit 123a and the regeneration unit 124a through the temperature measured by the controller, the drive motor connected to the drive belt 127 wound on the outer peripheral surface of the desiccant 120 The desiccant 120 is also rotated by rotating the driving belt 127 by rotating the driving belt 127 wound around the outer circumferential surface of the desiccant 120 by rotating the rotating motor 126. As shown in FIG. 7B, the respective positions of the adsorption part 123a and the regeneration part 124a of the desiccant 120 are switched by about 180 °.

As such, the moisture of the adsorption part 123a switched to the regeneration part side 124 while the adsorption part 123a is switched to the regeneration part side 124 according to the rotation of the desiccant 120, that is, the adsorption part ( In order to remove the moisture adsorbed to the 123a, through the electrodes 129 provided at both ends of the adsorption unit 123a switched from the control unit to the regeneration unit side 124 to the energization heating element (A) of the desiccant 120. When the electricity is supplied (conducted), the heating element (A) is heated by electricity supplied from the electrode 129 to generate a heat action to generate heat, and through the heat generation action of the conduction heating element (A) While directly adsorbing the adsorption part 123a to which the moisture is adsorbed, moisture adsorbed to the adsorption part 123a, that is, moisture of the adsorption part 123a switched to the regeneration part side 124 is evaporated, and the heater The regeneration unit side 124 of the desiccant 120 heated by the direct heating method of Minutes is to be changed to dry completely removed.

Then, the dehumidified air flows from the room to the desiccant 120 side passes through the regeneration unit side 124 from which water is completely removed as described above, and is provided with a regeneration air blower installed behind the regeneration unit side 124 of the desiccant 120. Through 34).

On the other hand, in the case of the regeneration unit 124a switched to the suction side of the desiccant 120 through the switching process, the water of the filtered air blown to the desiccant 120 side through the filter 10 and the blower 12 After turning off the energization of the electrode 129 installed in the regeneration unit 124a switched to the suction unit side through the control unit so as to adsorb the water, the same dehumidification process as the dehumidification process of the desiccant 120 described above is performed. The filtered air is passed through the regeneration unit 124a switched to the suction side of the desiccant 120, that is, the suction side.

By repeatedly repeating the dehumidification process and the regeneration process of the desiccant 120, the interior can be made comfortable.

The humidifying and dehumidifying apparatus using the desiccant of the present invention includes a dehumidification process of removing moisture by absorbing or adsorbing moisture from ambient air at a low temperature, and drying air dehumidified at a high temperature. The desiccant, which is a regeneration process of evaporating and removing the adsorbed moisture, is formed as an energization heating element, and an electrode necessary for energization is installed in the energization heating element so that the electrification heating element is directly generated during the regeneration of desiccant. By removing the water adsorbed to the desiccant through the heating method, there is an excellent effect that can significantly reduce the heat loss compared to the indirect heating method of the conventional desiccant.

In addition, by heating the desiccant through the direct heating method as described above, it is possible to significantly reduce the regeneration time of the desiccant according to the conventional, and at the same time, the switched regeneration when switching the position between the regeneration unit and the adsorption unit There is also an excellent effect of maximizing the water content (water adsorption amount) per unit area such that water in the air passing through the side can be completely removed.

Furthermore, by dividing the desiccant into several areas according to the adsorption capacity during the compression molding of the desiccant, it is possible to change the regeneration area of the desiccant by changing the area of the desiccant adsorption part and the regeneration part under partial load. It also works.

1 is a schematic structural diagram of a humidification and dehumidification apparatus using a conventional desiccant.

Figure 2 is a state diagram showing the distribution of water content during a predetermined time rotation or continuous rotation of a conventional desiccant.

Figure 3 is a schematic structural diagram and detail of the humidification and dehumidification apparatus using the desiccant of the present invention.

4 is a structural diagram of a desiccant press-molded with the energizing heating element of the present invention.

5 is another embodiment of a desiccant in accordance with the present invention.

Figure 6 is a state diagram of the water adsorption capacity according to the degree of compression during molding of the desiccant according to the present invention.

7 is an operational state diagram of the humidification and dehumidification device using the desiccant of the present invention.

Explanation of symbols on main parts of drawing

10. Filter 12. Blower

20, 120, 220. Desiccants 22, 122, 222.

23, 123, 223. Suction unit side 24, 124, 224. Regeneration unit side

23a, 123a. Adsorption part 24a, 124a. Playback

223a. Molding compression large adsorption section 223b. Molding compression small suction part

224a. Molding compression large regeneration section 224b. Molding Crimp Small Regeneration

26, 126, 226. Drive motor 27, 127, 227. Drive belt

30. Process air blower 32. Heater

34. Regenerative air blower 128, 228. Temperature sensor

129. Electrode A. Electric heating element

Claims (4)

A filter for filtering the dust mixed with the outside air; A blower for blowing air filtered by the filter to a desiccant; The pressurized material (Material) that is generated during energization in the form of a single plate, the adsorption unit for adsorbing the moisture of the air blown from the blower through the blocking film, the desiccant partitioned into a regeneration unit for evaporating the adsorbed moisture and ; A plurality of electrodes installed at both ends of each of the adsorption unit and the regeneration unit so as to conduct electricity to the desiccant so as to heat a portion corresponding to the regeneration unit side of the desiccant through evaporation to evaporate the adsorbed moisture; A treated air blower for blowing the dehumidified air into which the moisture is removed through the adsorption unit of the desiccant; Humidification and dehumidification apparatus using a desiccant, characterized in that the reconstituted air blower for discharging the air (high temperature and high humidity) evaporated moisture adsorbed to the regeneration unit of the desiccant to the outside. The humidifier and dehumidifier of claim 1, wherein the desiccant is an energized heating element that generates an exothermic action when energized. The humidifying and dehumidifying apparatus using desiccant according to claim 1, wherein the desiccant is divided into several regions by varying the degree of compression according to the adsorption capacity during the compression molding. The humidifier using a desiccant according to claim 1, wherein the desiccant further comprises at least one temperature sensor to measure the temperature of the regeneration unit to determine the switching time of the adsorption unit and the regeneration unit. Dehumidifier.