JP2004275924A - Dehumidifier - Google Patents

Abstract

An object of the present invention is to maintain optimal conditions for absorbing moisture of a moisture absorbent.
Kind Code: A1 A sensor 201 for detecting a degree of moisture absorption of a hygroscopic material 1 comprising a circulating system A including a hygroscopic material 1, a dehumidifying fan 3, a regeneration heater 5, a regeneration fan 6, and a heat exchanger 7. , 204 and at least one of the temperature of the regeneration heater 5, the rotation speed of the regeneration fan 6, the rotation speed of the dehumidification fan 3, and the moving speed of the moisture absorption material 1 according to the level of the moisture absorption of the moisture absorption material 1. The above object is achieved by changing.
[Selection diagram] Fig. 1

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention removes moisture from a hygroscopic material by passing heated air through a hygroscopic portion to remove moisture from the hygroscopic material and regenerate the moisture while returning the room air to the room by a fan and returning the indoor air to the room. The present invention relates to a dehumidifier in which water is separated from a moisture-absorbed air by a heat exchanger, collected and stored.
[0002]
[Prior art]
This type of dehumidifier includes a moisture absorber that moves repeatedly, a dehumidification fan that passes indoor air through the moisture absorber and then returns to the room to dehumidify the room, and heats air to pass moisture through the moisture absorber. A regeneration heater and a regeneration fan that repeats deprivation and regeneration in a circulation system, and a heat exchanger that separates moisture by exchanging heat with moisture-absorbing air that is passed through the desiccant and deprived of moisture and returned to the regeneration heater side. A device equipped with the device is known (for example, see Patent Document 1).
[0003]
This is lighter and smaller than a dehumidifier or air conditioner using a compressor, a condenser, or an evaporator. For this reason, it is easy to carry and can be used by moving to any place in the home. It is also useful for drying clothes in a closet, drying a bathroom, drying clothes in a bathroom, and the like.
[0004]
[Patent Document 1]
JP-A-11-300145 (0005, 0019 to 0024, FIG. 2)
[0005]
[Problems to be solved by the invention]
By the way, even with this type of small dehumidifier, it is conceivable to adjust the dehumidification function according to the humidity, discomfort index, and use. In order to enhance the dehumidifying function, it is conceivable to speed up the rotation of the hygroscopic material to reduce the amount of airflow per unit volume, and to increase the amount of airflow to the hygroscopic material. However, the hygroscopic material has a reduced hygroscopic capacity when the hygroscopicity approaches saturation, and cannot further absorb moisture when the hygroscopic material reaches a saturated state. Unless the temperature of the regeneration heater or the amount of air for the regeneration air is set in accordance with the degree of moisture absorption, the moisture absorbent cannot be sufficiently regenerated, and the efficiency of moisture absorption after regeneration is reduced. Therefore, it often happens that the designed or set dehumidifying function is not performed.
[0006]
Therefore, the present inventor considers that it is important to keep the moisture absorption conditions of the moisture absorbent to be optimal, and after conducting various experiments and repeating the examination, it was possible to detect the degree of moisture absorption of the moisture absorbent during movement. Based on this, it has been found that a predetermined dehumidification state can be obtained by keeping the moisture absorption conditions optimal.
[0007]
An object of the present invention is to provide a dehumidifier capable of maintaining optimal conditions for absorbing moisture of a moisture absorbent.
[0008]
[Means for Solving the Problems]
In order to achieve the above object, the dehumidifier of the present invention is a dehumidifier that repeatedly moves, a dehumidifying fan that returns indoors after passing indoor air through the moisture absorbent, and a dehumidifying fan that performs indoor dehumidification. A regenerative heater and a regenerative fan that repeats heating and passing through the hygroscopic material to deprive and regenerate dehumidifying water in a circulating system, and a hygroscopic air that is passed through the hygroscopic material to deprive dehumidifying water and return to the regeneration heater side. A heat exchanger for exchanging heat to separate dehumidified water, a sensor for detecting the degree of hygroscopicity of the hygroscopic material, and the temperature of the regeneration heater, the number of rotations of the regeneration fan, The method is characterized in that at least one of the rotation speed of the dehumidifying fan and the moving speed of the hygroscopic material is changed.
[0009]
In such a configuration, the combination of a moisture absorbing material, a dehumidifying fan, a regeneration heater, a regeneration fan, and a heat exchanger repeatedly dehumidifies the indoor air with the moisture absorbing material in the circulation system, and absorbs moisture from the indoor air to perform dehumidification. By repeatedly passing the heated air through the absorbent material, the dehumidifying water is deprived and the regeneration is achieved to ensure the moisture absorption function for the indoor air, and the dehumidification function is satisfied with a smaller and lighter than the compressor type. can do.
[0010]
At this time, the moisture absorption of the moisture absorbent is determined by the humidity of the moisture absorbed by the regenerated air heated from the room air, and the amount of heat required to remove the humidity, that is, the temperature of the regenerated heater with respect to the temperature of the regeneration heater. It can be known from the falling temperature. Further, the saturated moisture absorption amount per unit volume of the moisture absorbent is known. From these, at least one of the dehumidifying conditions of the temperature of the regeneration heater, the number of revolutions of the regeneration fan, the number of revolutions of the dehumidification fan, and the moving speed of the moisture absorbent is determined according to the level of the moisture absorption of the moisture absorbent detected by the sensor. By changing, the moisture absorbing material can be placed in a state suitable for absorbing moisture, and the dehumidifying function as set can be exhibited.
[0011]
In a further configuration, the change in the dehumidification condition is performed in response to a predetermined change in the moisture absorption.
Since a subtle change in dehumidification cannot be easily felt, it is not a problem to change the dehumidification condition when there is a predetermined change in the moisture absorption of the hygroscopic material, and the change operation need not be wasted. As a result, it is possible to prevent a frequent change operation from causing a failure or shortening the service life.
[0012]
The change of the dehumidification condition is performed in accordance with the variation of the average moisture absorption within a predetermined time.
[0013]
Thus, the change operation of the dehumidification condition is performed while observing the change in the degree of moisture absorption in a predetermined time unit. In this case, the change operation does not need to be performed wastefully. As a result, it is possible to prevent a frequent change operation from causing a failure or shortening the service life. In particular, the average value is used to check the moisture absorption in the specified time unit, so the improper or abnormal setting due to the irregular detection / absorption is used to maintain the constant dehumidification condition until the next predetermined time elapses. Can be avoided.
[0014]
The change of the dehumidification condition is performed according to the moisture absorption detected at the beginning of the operation, and thereafter, the change is performed according to the fluctuation of the moisture absorption.
[0015]
As a result, although there is not much change in the moisture absorption during the initial operation, the influence of the environmental humidity even during the operation stop and the moisture absorption state is not constant is determined based on the moisture absorption detected at the early operation. Is changed, the variation in the moisture absorption during the initial operation is dealt with, and thereafter, the variation is adjusted according to the variation in the moisture absorption, so that the conditions suitable for moisture absorption can be set both in the initial operation and thereafter.
[0016]
The change in the dehumidification condition is performed in response to the change in the moisture absorption, after performing for a predetermined time under a predetermined condition less than the change corresponding to the change, and then performed under the change condition corresponding to the change.
When there is a change in the degree of moisture absorption in which the operation of changing the dehumidification condition is to be performed, it is possible to avoid an abrupt change due to a sudden change to a predetermined condition corresponding to the change, thereby stabilizing the operation state.
[0017]
Further objects and features of the present invention will become apparent from the following detailed description and drawings. Each feature of the present invention can be employed alone or in combination in various combinations as much as possible.
[0018]
【Example】
Hereinafter, a dehumidifier according to the present invention will be described in detail with reference to FIGS. The following description shows specific examples of the present invention, and does not limit the content of the claims.
[0019]
As shown in FIG. 1 and FIG. 2 in the present embodiment, the dehumidifier of the present embodiment is configured such that the hygroscopic material 1 that moves repeatedly and the indoor air 2 are passed through the hygroscopic material 1 and then returned to the room to be indoors. A dehumidifying fan 3 for performing dehumidification, a regeneration heater 5 and a regeneration fan 6 for heating the regeneration air 4 to pass through the desiccant 1 to remove dehumidified water and to regenerate in the circulation system A; A heat exchanger 7 for exchanging heat with the regenerated air 4 for absorption on the way to return to the regeneration heater 5 to remove the dehumidification water and pass through the heat exchanger 7 to separate the dehumidification water; The water receiver 8 is provided in the main body 12, and the water in the water receiver 8 is sent to and stored in a water storage tank 9 that can be attached to and detached from the main body 12 by a water storage pump 11.
[0020]
In such a dehumidifier, the circulation system A repeats dehumidification of the room air 2 with the moisture absorbent 1 by a combination of the moisture absorbent 1, the dehumidifying fan 3, the regeneration heater 5, the regeneration fan 6, and the heat exchanger 7. . At this time, the dehumidifying water is deprived by passing the heated regenerated air 4 through the hygroscopic material 1 which repeats the dehumidification by absorbing moisture from the indoor air 2 to regenerate the dehumidified water, thereby guaranteeing the hygroscopic function for the indoor air 2. The dehumidified water 4a from which the dehumidified water has been taken away is separated by heat exchange in the heat exchanger 7 and returned to the regenerated air 4, and the separated water continues to be received in the water receiver 8. This makes it possible to satisfy the dehumidifying function with a smaller and lighter than the type using a compressor.
[0021]
In particular, in this embodiment, the temperature of the regeneration heater 5, the number of rotations of the regeneration fan 6, and the temperature of the dehumidification fan 3 are determined according to the moisture absorption sensor 201 that detects the degree of moisture absorption of the moisture absorbent 1 and the degree of moisture absorption of the moisture absorbent 1. At least one of the rotation speed and the moving speed of the hygroscopic material 1 is changed. Here, the degree of moisture absorption of the hygroscopic material 1 is determined by the humidity of the hygroscopic air 4a taken by the heated regeneration air 4 from the room air 2 and the amount of heat required to deprive the humidity, that is, of the regeneration heater 5. It can be known from the temperature drop of the hygroscopic air 4a with respect to the temperature. The saturated moisture absorption amount per unit volume of the moisture absorbent 1 is known. From these, the temperature of the regeneration heater 5, the number of rotations of the regeneration fan 6, the number of rotations of the dehumidification fan 3, and the moving speed of the moisture absorption material 1 are determined according to the level of the moisture absorption of the moisture absorption material 1 detected by the moisture absorption sensor 201. By changing at least one of the dehumidifying conditions, the hygroscopic material 1 can be placed in a state suitable for absorbing moisture, and the designed or set dehumidifying function can be exhibited.
[0022]
If the change of the dehumidification condition is performed in accordance with the predetermined change of the moisture absorption, it is difficult to realize a subtle change of the dehumidification. Is not a problem even if is changed, and the changing operation does not need to be performed wastefully. As a result, it is possible to prevent a frequent change operation from causing a failure or shortening the service life.
[0023]
Also, if the change of the dehumidification condition is made to correspond to the variation of the average moisture absorption within a predetermined time, the operation of changing the dehumidification condition is performed by looking at the variation of the moisture absorption in a predetermined time unit. The change operation does not needlessly be performed. As a result, it is possible to prevent a frequent change operation from causing a failure or shortening the service life. In particular, the average value is used to check the moisture absorption in the specified time unit, so the improper or abnormal setting due to the irregular detection / absorption is used to maintain the constant dehumidification condition until the next predetermined time elapses. Can be avoided.
[0024]
In addition, if the change of the dehumidification condition is performed according to the moisture absorption detected at the beginning of the operation, and thereafter, the change is performed according to the fluctuation of the moisture absorption, the operation is stopped even though there is not much change at the initial operation. The influence of environmental humidity is also present during the operation, and the fact that the moisture absorption state is not constant can be dealt with by changing the dehumidification conditions based on the moisture absorption detected at the beginning of the operation, to cope with variations in the moisture absorption during the initial operation. After that, since it responds by the variation of the moisture absorption, the condition suitable for moisture absorption can be set both in the initial operation and thereafter.
[0025]
Further, when the change of the dehumidifying condition is performed for a predetermined time under a predetermined condition smaller than the change corresponding to the change in the moisture absorption corresponding to the change of the moisture absorption, and then performed under the change condition corresponding to the change, the dehumidifying condition is changed. When there is a change in the degree of moisture absorption in which the change operation should be performed, it is possible to avoid a sudden change due to a sudden change to a predetermined condition corresponding to the change, thereby stabilizing the operation state.
[0026]
For such control, a control device 202 such as a microcomputer shown in FIG. 9 includes an operation panel 28 for setting ON / OFF of an operation, an operation mode and an operation condition in the input system, the moisture absorption sensor 201, It has a sensor 204, and has a dehumidifying fan 3, a regeneration heater 5, a regeneration fan 6, and a geared motor 71 for driving the hygroscopic material 1 in an output system. The input system further includes a humidity sensor 205 that detects the humidity of the indoor air 2 and a dehumidification sensor 206 that detects the humidity of the dehumidified indoor air 2 that has passed through the hygroscopic material 1. The control to achieve the specified dehumidification is also performed. The input system also has a water receiver sensor 131 for detecting the water storage state of the water receiver 8 and a water storage sensor 207 for detecting the water storage state of the water storage tank 9, and reaches a predetermined amount such that the water storage amount of the water receiver 8 is almost full. Each time the water storage pump 11 is driven to supply water to the water storage tank 9, and whenever the water storage tank 9 reaches a predetermined amount, for example, when the water storage tank 9 is almost full, drainage is urged or operation is stopped. The output system has a number of display lamps 208 for displaying special conditions such as operation on / off and drainage time, in addition to displaying the operation state on the operation panel 28. As shown in FIG. 1, the sensor 207 includes a combination of a float 207a in the water storage tank 9 and a reed switch 207b on the main body 12 for detecting the position of the float 207a. However, the sensors 131 and 207 may be of any type and structure as long as they can serve the purpose.
[0027]
The regeneration fan 6 is located between the heat exchanger 7 and the regeneration heater 5 in the circulation system A as shown in FIGS. 2 and 8, and is connected to a communication path 101 from the heat exchanger 7 to the regeneration fan 6. A concave portion 102 as shown in FIG. 8 is provided on the inner surface of the base 101 for receiving dew condensation collected at the lower portion, and the condensed water received in the concave portion 102 is collected in the water receiver 8.
[0028]
As a result, during the dehumidifying operation as described above, dew may condense on the inner surface of the communication path 101 from the heat exchanger 7 to the regeneration fan 6. Since the water is received in the concave portion 102 provided in the communication path 101, it is possible to prevent the water from accumulating in the flat lower portion of the communication path 101 and trying to spread in the longitudinal direction. Therefore, the inconvenience that dew water enters the regeneration fan 6 does not occur. In addition, since the dew water received in the concave portion 102 is collected in the water receiver 8, it is possible to prevent the dew water in the concave portion 102 from overflowing and to be in the same state as the conventional case without the concave portion 102. Such a concave portion 102 has an advantage that the function is not lost even when the dehumidifier is placed slightly inclined.
[0029]
Such a concave portion 102 is preferably provided at the lower part of the communication path 101, particularly at the lowest position, as shown in the figure. However, the lowermost portion changes depending on the cross-sectional shape of the communication path 101, the shape in the axial direction, the presence or absence of the inclination, and the like. In the illustrated example, a concave portion 102 is provided at the lowermost portion in the circumferential direction of the communication path 101 and near the upstream side of the reproduction fan 6. In such a position near the regeneration fan 6, even if dew condensation collected at the lower part of the communication path 101 tries to spread to the regeneration fan 6 side, it is received in the concave portion 102, and furthermore, the condensed water is further moved to the regeneration fan 6 side. Can be prevented from spreading. Therefore, no matter where the dew condensation water collects at the lower portion of the communication path 101, it is possible to cope with the expansion of the dew condensation water.
[0030]
If such a concave portion 102 is provided, for example, if it is formed in the duct 103 forming the communication path 101, the concave portion 102 can be provided without any special member, and the cost can be reduced accordingly. However, in this case, the duct 103 is a cylindrical member, and the die-cutting structure when the die is molded is complicated by the concave portion 102. Therefore, in the examples shown in FIGS. 1 to 8, the upstream half 102a is formed integrally with the duct 103, the remaining downstream half 102b is formed separately, and the half 102b is combined with the half 102a. Like that. In this way, the upstream half 102a integrally formed with the duct 103 has a form opened toward the downstream end of the duct 103, so that the portion forming the upstream half 102a of the mold is the axis of the duct 103. Can be simply stamped out in the downstream direction. Since the remaining downstream half 102b is a single piece, there is no problem of die cutting.
[0031]
Further, a condensed water storage chamber 104 as shown in FIGS. 2 to 4 and 8 is provided below the recess 102, and a recovery conduit 105 for guiding the condensed water from the storage chamber 104 to the water receiver 8 is provided. . Accordingly, the concave portion 102 has a flat surface size capable of receiving the dew condensation water that is going to reach the regeneration fan 6 side, and the concave portion 102 is not shallow due to the presence of the storage chamber 104 thereunder. Can be. At the same time, the condensed water storage chamber 104 under the condensed water can be made small and not bulky in a plan view to increase the amount of dew water stored in the recess 102. In addition, the dew condensation water in the storage chamber 104 can be guided to the water receiver 8 by an arbitrary route by the recovery pipe 105. However, the large amount of storage causes the recovery pipe 105 not to be bulky and to have a thinner bending degree. However, since the collection can be made in time, the degree of freedom of the piping is further increased and it is easy to provide.
[0032]
In order to provide such a deep storage chamber 104 below the concave part 102, a part of the storage chamber 104 is related to the fact that the concave part 102 is formed by being divided into an upstream half part 102a and a downstream half part 102b. Can also be divided into an upstream portion 104a and a downstream portion 104b, and easily divided into an upstream portion 102a and a downstream portion 102b of the recess 102 as shown in FIG. Thereby, it is possible to form the mold easily and at low cost as compared with the case where the die-cutting structure is complicated and integrally molded.
[0033]
The connection port 104c of the storage chamber 104 with the recovery pipe 105 is formed integrally with the downstream portion 104b, which is the side on which molding is easy, in a cylindrical shape, and the recovery pipe 105 is connected to this connection port 104c.
[0034]
Further, in the example shown in FIG. 8, the suction port 6c of the reproduction fan 6 is fitted inside the rear end of the communication path 101, and a step 111 is formed on the side of the recess 102 on the reproduction fan 6 side. The step portion 111 functions as a weir and collects at the lower part of the communication path 101 to block the dew condensation water that is going to spread to the regeneration fan 6 side. It is easier to prevent.
[0035]
However, the lower part of the communication path 101 is added to the concave part 102 in the circumferential direction and also in the longitudinal direction toward the concave part 102 so that dew condensation water collected at the lower part of the communication path 101 can be guided to the concave part 102. You can also.
[0036]
The heat exchanger 7 exchanges heat with the room air 2 sucked by the dehumidifying fan 3 as shown by broken lines in FIGS. For this reason, the heat exchanger 7 connects a plurality of heat exchange elements 7b having a plurality of branch air passages 7a, for example, in a parallel state in the middle as shown in FIGS. 1 and 2, and introduces the hygroscopic air 4a. Heat is exchanged with the room air 2 passing outside the branch air passage 7a. Although the heat exchange element 7b is a blow-molded product made of resin, heat exchange can be achieved because the wall thickness is thin. However, since it is heat exchange with the indoor air 2, there is a limit in cooling the moisture-absorbing air like an evaporator using a compressor due to its size and the like. Condensation water easily accumulates on the connecting path 101 leading to the condensed water. In addition, although the communication path 101 has the hygroscopic material 1 interposed in the heat exchanger 7, the regeneration heater 5 is grounded and is connected at a relatively close position in the circulation system A, so that the internal temperature increases. Can easily lead to condensation. However, it is possible to sufficiently cope with the above-described dew condensation water recovery structure and its operation.
[0037]
More specifically, a removable water storage tank 9 as shown in FIG. 1 for storing the dehumidified water or dew condensation water collected in the water receiver 8 as shown in FIG. A water storage pump 11 as shown in FIGS. 3 and 6 for sending water and dew condensation water to store water is provided. The circulating system A including the combination of the moisture absorbent 1, the dehumidifying fan 3, the regenerating heater 5, the regenerating fan 6, and the heat exchanger 7, the water receiver 8, and the water storage pump 11 are disposed on the main body 12 of the dehumidifier as shown in FIGS. The water storage tank 9 is provided so as to be detachable from the main body 12.
[0038]
As a result, while exhibiting a dehumidifying function in the circulation system A provided on the main body 12 side, dehumidified water separated from the regenerated air 4 that has absorbed moisture after regenerating the absorbent material 1 and dew condensation water in the communication path 101 are: Similarly, by receiving the water with the water receiver 8 provided on the main body 12 side, the water is supplied to the water storage tank 9 and stored by the water storage pump 11 without being spread over a wide area, thereby minimizing the required space of the main body 12 and avoiding the fullness. Thus, it is possible to prevent the inconvenience that the separated dehumidified water evaporates and escapes and humidifies the room instead of allowing the dehumidified water to separate for a long time. The water supply channel 26 as shown in FIGS. 3 and 6 from the water storage pump 11 to the water storage tank 9 may be configured in any manner and connected in any way, but flowing from the upper part of the water storage tank 9 causes a reverse flow. It is preferred because there is no However, if a check valve is provided in the middle of the water supply passage 26 or at a portion where the water supply passage 26 of the water storage tank 9 is detachably connected, the problem due to the backflow can be solved. Further, the condensed water accumulated in the concave portion 102 can be sent to the water receiver 8 and the water storage tank 9 by the water storage pump 11 or a dedicated pump (not shown).
[0039]
The water storage tank 9 is provided on the upper front side of the main body 12. In this manner, since the water storage tank 9 is located on the front side of the upper portion of the main body 12 as shown in FIG. 1, the water storage tank 9 receives and sends the dehumidified water collected in the water receiver 8 as described above. Can be made to appear from around the front of the user. In other words, dehumidifying water is generated by dehumidifying the indoor air 2, and the user can confirm that the dehumidified water is stored in the water storage tank 9, so that the user can feel the dehumidification and can be easily evaluated. Moreover, by making the shape and size of the water storage tank 9 provided in the main body 12 correspond to the surplus space due to the arrangement of the devices on the main body 12 side, the water storage tank 9 can be formed without wasteful space or unnatural dents or protrusions. Can be provided. At the same time, since the water storage tank 9 is located outside the main body 12 and at the side closest to the user and for easy attachment / detachment for draining and cleaning the water storage tank 9, The water storage tank 9 can be easily handled independently.
[0040]
However, even if the water storage tank 9 is colorless or colored, transparent, translucent, or opaque such as milky white, the internal water storage and the shadow of that level can be reflected on the external surface and can be confirmed from the outside, or even partially. It is sufficient if there is a water storage inspection unit that can confirm such water storage and its level. Such a water storage tank 9 and its parts are obtained by glass or synthetic resin, but are preferably made of synthetic resin in terms of lightness and breakability. The main body 12 is equipped with a variety of devices as described above, and may be entirely or partially made of metal from the viewpoint of durability and heat resistance, but is not limited to this, and is not limited thereto. Alternatively, the whole can be made of a synthetic resin. In addition, even if it is made of synthetic resin, heat resistance can be obtained as required by a heat-resistant resin material.
[0041]
Also, as shown in FIG. 1, below the water storage tank 9 of the main body 12, that is, under the grounding section where the water storage tank 9 is provided, in the example shown, under the step portion 15 as shown in FIG. , The heat exchanger 7, the rotating absorbent material 1 is located, the regeneration heater 5 and the regeneration fan 6 are located above and below the absorbent material 1, and the regeneration air 4 is supplied from the regeneration fan 6 to the regeneration heater 5, The circulation system A returns to the regeneration fan 6 after the moisture absorbent 1 and the heat exchanger 7 are sequentially reached. Behind the regeneration heater 5 and the regeneration fan 6, the dehumidifying fan 3 opens its intake port 3a toward the intake port 22 on the front surface of the main body 12 through the hygroscopic material 1, and connects the blow port 3d to the exhaust port 23 on the upper part of the main body 12. It is located so as to be connected to.
[0042]
The water receiver 8 has a lid 8a as shown in FIGS. 1 and 6, and the dehumidified water or dew condensation water separated from the hygroscopic air 4a by the heat exchanger 7 is received through a water passage 8b of the lid 8a. Further, the recovery conduit 105 from the recess 102 is also connected to the lid 8 a so that the dew condensation water from the recess 102 is received by the water receiver 8. As shown in FIGS. 3 and 6, the water storage pump 11 is provided in the middle of the base side of the water passage 26 extending from the bottom of the water receiver 8 to the water storage tank 9. Further, in the illustrated example, a filter 93 as shown in FIGS. 1 and 2 is provided inside the intake port 22. As shown in FIGS. 1 and 2, the hygroscopic material 1 is provided with a gear 1c in a case 1b containing and holding a hygroscopic agent 1a such as zeolite, and is directly connected to the geared motor 71 as shown in FIGS. The pinion gear 72 is engaged with the pinion gear 72 to rotate at a predetermined speed.
[0043]
With the arrangement of the internal devices 16 as described above, the moisture absorbent 1 rotates and repeatedly dehumidifies the indoor air 2 and regenerates it thereafter, so that the room air 2 for dehumidification and regeneration passes in the passing direction shown in FIG. It can be a flat one with a good thickness, and it is located on the lower side using the flat space of the water storage tank 9 provided on the front side of the upper part of the main body 12 together with the heat exchanger 7 located on the front side, Can be grounded without wasting space. The upper water storage tank 9, the lower heat exchanger 7 and the moisture absorbent 1, and the regenerative heater 5 and regenerative fan 6 located behind the recirculation tank 9 without wasteful dispersion. While the system A is compactly configured as shown in FIGS. 1 and 2 together with the main body 12 for accommodating the system A, as shown in FIG. The dehumidifying fan 3 having a sufficient size is provided without particularly increasing the size of the main body 12 to secure a sufficient air volume, a low-speed intake and a low-speed air blow that are quiet and do not allow a human to feel the wind, and are high. It can exhibit a dehumidifying function. However, for wide-area dehumidification, it is necessary that at least one of the intake air and the air blow satisfies a condition that extends to a required range of dehumidification.
[0044]
As shown in FIGS. 1 and 2, the inside of the main body 12 is partitioned by a partition wall 75 made of a synthetic resin into a rear portion containing the dehumidifying fan 3 and a front portion containing the circulation system A. The partition wall 75 has a dehumidifying motor 3e attached to the rear side of the main body, and forms an air inlet 3a therearound. The dehumidifying impeller 3b, which is directly connected to the dehumidifying motor 3e, is located on the rear side, and is covered with a synthetic resin cover wall 3c attached to the partition wall 75 to constitute the dehumidifying fan 3. In addition, a partition wall 77 made of a synthetic resin is provided on the front side of the main body 12 to partition the moisture absorbent 1 side and the heat exchanger 7 side as shown in FIGS. The partition wall 77 supports the hygroscopic material 1 at the center thereof so as to be rotatable by a shaft portion 77 a shown in FIG. 1, and the geared motor 71 is attached to rotate the hygroscopic material 1 on the partition wall 77.
[0045]
In addition to the dehumidifying motor 3e, the regeneration heater 5 and the regeneration fan 6 are located between the partition walls 75 and 77. The regeneration heater 5 is held in an inflow port 73a at the rear of the heating unit cover 73 as shown in FIG. 1 attached to the partition wall 77, and the heating unit cover 73 spreads in a trumpet shape up, down, left and right toward the front side. The outlet 73b formed in this manner is opposed to a range in which the moisture absorbent 1 is to be regenerated with a suitable gap. The above-mentioned wrapper shape of the heating unit cover 73 is such that after achieving efficient contact between the regeneration heater 5 and the regeneration air 4 and heating by the small inlet port 73a, the regeneration air 4 which has been sufficiently heated is heated. As much as possible, the regeneration air 4 from the regeneration fan 6 is blown to the rear area of the heating section cover 73 over a wider area of the moisture absorbent 1 so that efficient regeneration can be achieved. At the rear of the heating unit cover 73, a regeneration cover 74 as shown in FIG. 1, FIG. 2, FIG. 3, and FIG. It is attached to a partition wall 77 together with 73. As shown in FIG. 1, the regenerating cover 74 blows the regenerating air 4 to the regenerating heater 5 while covering the entire heating section cover 73, and prevents the heating section from affecting the surrounding area behind the heating section. It is also a heat cover.
[0046]
The regenerative fan 6 fits the suction port 6c of the casing 6b accommodating the impeller 6a to the rear end of the duct 103 of the communication path 101 formed integrally with the partition wall 77 as shown in FIGS. The outlet 6d of the casing 6b is connected to the air guide port 74a of the regeneration cover 74 as shown in FIGS.
[0047]
Here, the path from the regeneration fan 6 to the regeneration heater 5, for example, the regeneration cover 74 has an inclined portion 74d whose lower portion is directed to the lower portion 74c as shown in FIGS. Even if condensed water is generated or invades, it is guided to the lower portion 74c to prevent the condensed water from circulating through the circulating system A, reducing the dehumidifying efficiency or affecting other things. Can be prevented. When the amount of dew water is extremely small, the water can be dried and diverged on the way to or from the lower portion 74c. However, when the amount gradually increases, the water can be collected from the lower portion 74c to the water receiver 8 through a collection pipe 112 as shown in FIGS.
[0048]
In the circulatory system A, the low-level portion 74c due to the inclined shape of the concave portion 102 and the regenerating cover 74, and the collecting portion of the condensed water, other than necessary portions, do not provide a place where the condensed water accumulates or flows, It is possible to prevent the dew condensation water from flowing to an inadvertent portion or accumulating therein and affecting other portions.
[0049]
By the way, the regenerated air 4 after the heat exchange in the circulation system A exits from the heat exchanger 7 and returns again through the regeneration heater 5 and the regeneration fan 6, that is, the temperature inside and outside the circulation system A even in a part other than the heat exchanger 7. It is conceivable that dew condensation water is generated or accumulated due to a difference, an internal temperature difference, or for some reason. Therefore, it is preferable to provide a recovery pipe 112 extending from such a portion or a pool portion subsequent thereto to the water receiver 8 for recovery. The collecting path including such a pool portion and the collecting pipe 112 can be formed in any manner.
[0050]
As shown in FIG. 1, the partition wall 77 further opens a portion corresponding to the moisture absorbent 1 to the front side, and a ventilation opening 78 for ventilating the room air 2 sucked by the regeneration fan 6 to the moisture absorbent 1. A receiving chamber 79 as shown in FIG. 2 is formed on the front side of the moisture absorbent 1 so as to pass through the regeneration heater 5 and the moisture absorbent 1 and receive the moisture-absorbed air 4a after the regeneration of the moisture absorbent 1. The receiving chamber 79 has a rear end facing the hygroscopic material 1 with a suitable gap to receive the hygroscopic air 4a, and a front end provided with a connection port 80 with the inlet 7c of the heat exchanger 7 to receive the hygroscopic air. The air 4a is sent to the heat exchanger 7. The outlet 7d of the heat exchanger 7 shown in FIG. 1 is connected to the front end of a duct 103 forming a communication path 101 as shown in FIG. 1, and the moisture-absorbed air 4a is dehumidified by heat exchange with the room air 2 to be regenerated. The regenerated air 4 is sucked by the regenerating fan 6 and is again used for regenerating the hygroscopic material 1.
[0051]
On the rear upper surface of the main body 12, an operation panel 28 shown in FIG. 1 and an exhaust port 23 from the dehumidifying fan 3 are provided side by side. The air outlet 23 has a rectangular opening 23a formed on the upper surface of the main body 12 and an opening 23b formed on the rear surface of the main body 12 in a continuous state. A cover 65 is provided, and is driven by an actuator such as a motor (not shown) so as to be in the wind direction set on the operation panel 28. The wind direction is set, for example, in a substantially vertical fully closed state, each intermediate open state between the fully closed state and the fully open state shown in FIG. 2, and a continuous wind direction that continuously reciprocates between the fully closed state and the fully open state. There is a change state. In the fully closed state, only the opening 23b is opened rearward, and the air is blown backward. In the fully opened state, the entire area of the opening 23a is opened, and the air is blown right above. In each intermediate opening state, the air is blown in a direction along the opening angle of the wind direction setting lid 65.
[0052]
As shown in FIG. 2, the main body 12 is further provided with casters 33 on both left and right sides of a corner that is diagonally located with respect to the water storage tank 9 when viewed from the side of the main body 12. Accordingly, when the main body 12 is grounded by the pair of left and right casters 33 and pulled around, when the main body 12 is tilted backward to the side where the diagonal line is vertical, the center of gravity of the main body 12 including the water storage tank 9 is placed on the casters 33. Even if the position of the center of gravity is different at different times due to the difference in the amount of water stored in the water storage tank 9, the weight can be balanced back and forth by adjusting the tilting angle of the body 12 to the rear side without difficulty. It can be moved and is convenient when it is used in a different room, such as the same room, between rooms, or between a room and a bathroom. In the bathroom, it can be used not only for dehumidification and drying itself, but also for drying laundry.
[0053]
A seat leg 35 is provided at the bottom of the main body 12 as an example of a seat portion to be grounded in a use state, and the caster 33 is slightly lifted from the ground surface 36 to ground the main body 12 as shown in FIG. It is. Accordingly, when the main body 12 is grounded in the use state, the caster 33 is not grounded, and the grounding state of the main body 12 is not made unstable.
[0054]
Along with the provision of the casters 33, a pull 37 is provided on the back of the main body 12, as shown in FIGS. The puller 37 in the illustrated example has a pair of left and right pull rods 37a held so as to be able to be taken in and out of a sheath 39 provided vertically at the center of the back of the main body 12 in the left and right direction. It is composed of the attached grip 37b. Such a pull 37 can be easily and freely moved by sharing the support of the main body 12, the angle adjustment, and the wiring when the main body 12 is tilted rearward as described above and turned around. In addition, it is preferable to provide a hand-held handle pivotally supported so that it can be raised and lowered (not shown) at the upper part of the water storage tank 9.
[0055]
The gap between the heating unit cover 73 and the receiving chamber 79 and the hygroscopic material 1 is for preventing the hygroscopic material 1 from interfering with others even when the hygroscopic material 1 is driven to rotate. However, this gap also serves as a gap where the regeneration air 4 and the moisture-absorbing air 4a are mixed, which causes a reduction in dehumidification efficiency. Therefore, in the present embodiment, a PTC heater which is a semiconductor heater is employed as the regenerative heater 5, and the heating unit cover 73 and the receiving chamber 79 are utilized by utilizing the fact that the PTC heater does not reach a high temperature of about 200 ° C. at maximum, unlike the ribbon heater. And the case 1b of the hygroscopic material 1 are made of synthetic resin, and a minimum gap is ensured so that they do not come into contact with each other due to their thermal expansion and molding errors, and the mixing of the regeneration air 4 and the hygroscopic air 4a is minimized. So that it can be held down. In particular, the gap between the heating unit cover 73 and the case 1b is a hook-shaped gap in cross section, which is a so-called labyrinth, which further facilitates the prevention of mixing of the moisture-absorbed air and the regenerated air. A gap S1 between the receiving chamber 79 and the case 1b of the absorbent material 1 is formed straight between the rear end of the receiving chamber 79 and the holding member 121 attached to the case 1b. However, a labyrinth gap may be provided in this portion as well.
[0056]
Here, specific operation control will be described with reference to FIGS. FIG. 10 shows a control example in which the dehumidification condition is changed according to the humidity information of the regenerated air 4 heated by the regenerative heater 5 detected by the moisture absorption sensor 201. In the control of the present example, when the rotation speed of the reproduction fan 6 is N rpm and the reproduction heater 5 is Mw at the current humidity detected by the moisture absorption sensor 201, the current state is maintained unless there is a change in the current humidity outside an appropriate predetermined humidity range. I am trying to do it. If the humidity is below the appropriate predetermined humidity range, the hygroscopic material 1 has a low hygroscopicity and is not effectively used. Therefore, the rotation speed of the regenerating fan 6 is reduced to N-α rpm, and the hygroscopicity per unit volume is reduced. By increasing the effective use of the moisture absorbent 1, the driving energy is reduced, and the regeneration heater 5 is set to M-αw. I try to keep it down.
[0057]
When the humidity exceeds the appropriate predetermined humidity range, the hygroscopic material 1 has a high hygroscopicity and is effectively used. However, since the hygroscopic efficiency is low, the rotation speed of the reproducing fan 6 is set to N + β rpm. Raise the moisture absorption rate per unit volume to increase the moisture absorption efficiency of the moisture absorbent 1 so that sufficient dehumidification can be performed. At the same time, the regeneration heater 5 is set to M + βw, and the rotation of the moisture absorbent 1 is accelerated to make heating difficult. The power consumption is increased by the amount that makes it difficult to reproduce, so that sufficient reproduction can be performed.
[0058]
FIG. 11 shows a control example in which the dehumidifying condition is changed by the temperature information of the regenerated air 4 heated by the regenerative heater 5 detected by the temperature sensor 204. In the control of this example, if the rotation speed of the regeneration fan 6 is N rpm and the regeneration heater 5 is Mw at the current humidity detected by the temperature sensor 204, the current condition is maintained unless there is a change in the current temperature outside an appropriate predetermined temperature range. I am trying to do it. If the temperature exceeds the appropriate predetermined temperature range, the moisture absorption of the hygroscopic material 1 is low and it is not effectively used. Therefore, the rotation speed of the regeneration fan 6 is reduced to N-β rpm, and the moisture absorption per unit volume is reduced. By increasing the use of the hygroscopic material 1, the driving energy is reduced, and at the same time, the power consumption of the regeneration heater 5 is reduced by M-βw. I try to keep it down.
[0059]
If the temperature is lower than an appropriate predetermined temperature range, the hygroscopic material 1 has a high hygroscopicity and is effectively used. However, since the hygroscopic efficiency is low, the rotation speed of the regenerating fan 6 is set to N + α rpm. Raise the moisture absorption rate per unit volume to increase the moisture absorption efficiency of the moisture absorbent 1 so that sufficient dehumidification is performed. At the same time, the regeneration heater 5 is set to M + αw, and the rotation of the moisture absorbent 1 is accelerated to make it difficult to heat. The power consumption is increased by the amount that makes it difficult to reproduce, so that sufficient reproduction can be performed.
[0060]
If it is difficult to accurately determine the moisture absorption of the hygroscopic material 1 only by the humidity or the temperature, a more reliable control can be performed by combining the control of the dehumidifying conditions by the humidity and the temperature.
[0061]
Although not shown, it is preferable to control the rotation speed of the regenerating fan 6 in the same manner to improve the moisture absorption efficiency of the moisture absorbent 1 and the energy saving. Further, if necessary, the rotation of the dehumidifying fan 3 can be controlled to avoid an excessive dehumidifying load or to increase the moisture absorption.
[0062]
The set dehumidification may be performed by controlling the rotation speed of the dehumidification fan 3 while monitoring the humidity of the room air 2 after dehumidification by the dehumidification sensor 206. In addition, it is possible to automatically control the humidity of the room air 2 to a predetermined value while monitoring the humidity of the room air 2 with the humidity sensor 205 in accordance with the humidity of the room air 2 after the dehumidification by the dehumidification sensor 206.
[0063]
In short, when the hygroscopic capacity of the hygroscopic material 1 is increased, the power consumption of the regeneration heater 5 is increased, the rotation of the hygroscopic material 1 is increased, and if the rotation of the fan is increased, the dehumidifying efficiency and the dehumidifying efficiency are improved. If the priority is changed in this order in the order of the hygroscopic material 1, the fan, and the regeneration heater 5, it is preferable in terms of the dehumidifying effect and the energy saving effect. The fan refers to the regenerating fan 6 or both of the dehumidifying fan 3 and the regenerating fan 6. However, the amount of air blown by the fan is always in the relationship of the regeneration fan 6 <the dehumidification fan 3. In the air cleaning mode other than the dehumidification mode, the above-described adjustment control of the hygroscopic material 1 is not performed, and only the function of the filter 93 and the dehumidification fan 3 is required, and the circulation system A can be kept off. Also, the highest hygroscopic absorption in the operating calendar is stored, and thereafter the initial operation is performed under the conditions based on that. Such a change in the dehumidifying conditions can be performed according to a preset matrix.
[0064]
In addition to the normal dehumidifying operation mode as described above, a bathroom drying mode for drying the bathroom can be provided. In this mode, when the humidity of the room air 2 reaches a predetermined value, the drying control is turned off. However, in conjunction with this, the upper limit time can be set in advance, and when the upper limit time is reached, the drying control can be turned off, thereby avoiding abnormal continuous operation, ensuring safe use, and avoiding unnecessary operation. And save energy. In addition, the lower limit time is set in advance, the initial operation is continued during the time less than the lower limit time, and after reaching the control of the end of drying after the lower limit time elapses, the drying control based on the humidity monitor for the end of the drying is performed. Start. This can avoid unnecessary drying control.
[0065]
Further, an internal safety timer that monitors the upper limit time and an off timer that is set and operated by the user are provided. When the off timer set time set by the user elapses, the timer is turned off or the mode is switched to the slow drying control, but the off timer set time set by the user is reached. However, when the set time of the internal safety timer has elapsed, priority is given to switching off or slow drying control. According to this, the bathroom can be dried for a time desired by the user while avoiding abnormal or wasteful long-time drying. However, since there is no problem with the lower limit time, the timer time set by the user is prioritized. Even when the user does not set the timer, it is convenient in use to perform the bathroom drying control using the internal safety timer.
[0066]
Note that the internal safety timer can automatically change the set time according to the humidity or temperature of the indoor air 2. Further, in the normal dehumidification mode, no lower limit time is required. The relationship between the upper limit time in the normal dehumidification mode and the upper limit time in the bathroom drying mode is usually> bathroom. Thus, the normal dehumidification mode can cope with a situation that is frequently performed continuously for a long time in order to eliminate discomfort in a humid living environment.
[0067]
FIG. 12 shows an example of control when bathroom drying is performed. In this control, after the initial setting process according to the setting mode, the air volume setting of the dehumidifying fan 3 is set to “strong”. That is, the dehumidification function is maximized. At this time, although not shown, in order to maximize the moisture absorption efficiency of the moisture absorbent 1, it is preferable to maximize at least one of the rotation of the moisture absorbent 1, the power consumption of the regeneration heater 5, and the rotation of the regeneration fan 6. .
[0068]
After a lapse of a predetermined time, for example, one hour, from the start of the operation, it is determined that the dehumidification has been substantially completed, and the humidity information of the indoor air 2 by the humidity sensor 205 is taken in, and it is determined whether or not the set humidity as the drying target has been reached. The predetermined time at this time is the lower limit time referred to above. When the set humidity is reached, the operation end processing is performed. This means that the operation is stopped with an operation necessary for stopping the operation such as sending water in the water receiver 8 to the water storage tank 9.
[0069]
If the set humidity has not been reached, the acquisition and determination of the humidity are repeated until 3 hours have elapsed, and after 3 hours have elapsed, the mode is switched to the mild drying mode and continued until the predetermined T time has elapsed, and the predetermined time T has elapsed. Then, end processing is performed. This predetermined time T is the upper limit time described above.
[0070]
Further, a drain cap 209 is provided on the drain discharge water 209a in the water receiver 8 as shown in FIGS. 3, 6, and 7, and by removing the drain cap 209, the dehumidified water in the water receiver 8 can be discharged. However, the presence or absence of the drain cap 209 is detected by a drain sensor 210 of an optical system, an electromagnetic system, a contact system, or the like, and if the drain cap 209 is not attached, the operation in the normal dehumidification mode is stopped. is there. For this purpose, a drain sensor 210 is also provided in the input system of the control device 202 shown in FIG. In the bathroom drying, the drainage may be drained, so that the operation can be performed without mounting the drain cap 209, and the water storage pump 11 is stopped. In the bathroom drying mode, it is determined not to determine whether or not the drain cap 209 exists. However, at the time of the operation start operation in the normal dehumidification mode, it is preferable to issue a warning or display about operation inhibition due to the absence of the drain cap 209, since it is possible to prompt the user to respond. In addition, when an indication that the drain cap 209 is not attached or a drainage state is displayed at the time of the operation start operation in the bathroom drying mode, the use in such a state will be convinced.
[0071]
It should be noted that whether or not the drain cap 209 is attached can be detected by detecting that a predetermined amount of dehumidified water does not accumulate in the water receiver 8 even when the operation is continued for a predetermined time. During that time, drainage is performed, but there is no particular problem because the amount is extremely small. Therefore, the drain sensor 210 can be omitted.
[0072]
If the drain cap 209 comes off during the normal dehumidification mode, the warning is issued and the operation is stopped. In this case, when the drain cap 209 is attached, the warning is automatically reset. The operation may be automatically restarted at the same time. Even if the drain cap 209 comes off halfway, it can be determined that the user has drained during driving for a certain short period of time, and no warning or operation stop is performed.
[0073]
Further, in the bathroom drying mode, it is considered that a large amount of dehumidified water is generated. When the drain cap 209 is attached, the water storage pump 11 is driven to stop the operation when the water storage tank 9 is full, It copes with overflow of dehumidified water due to continued dehumidification and water leakage in the main body 12. In this case, by issuing a warning, it is possible to notify the stoppage of the operation during the dehumidification, and to urge the drainage of the water storage tank 9 and the restart of the dehumidification.
[0074]
The attachment and detachment of the drain cap 209 is replaced by the opening and closing of a drain valve. When the drain valve is an electromagnetic valve, it can be automatically opened and closed. For example, the drain valve can be automatically closed in a normal dehumidification mode, and can be automatically opened and drained constantly in a bathroom drying mode. In this case, the water storage pump 11 is stopped.
[0075]
Further, when the water level of the water receiver 8 rises even though the drain cap 209 is not detected by the drain sensor 210, it is considered that the water supply passage 26 is clogged. Therefore, even in such a case, the operation can be stopped to cope with the situation, and it is preferable to give a warning to that effect. Further, when the inside of the water receiver 8 reaches the pumping water level and reaches the water level to drive the water storage pump 11 to supply water to the water storage tank 9, the water supply is continued for a predetermined time even if the water receiver 8 reaches the minimum water level. By this, the remaining water in the event of an emergency due to the inclination of the main body 12 or the waving of the water surface is also supplied, so that the time interval until the next water supply is shortened, and the number of times of driving of the water storage pump 11 becomes extremely large. Can be prevented. This is also effective when the operation is stopped.
[0076]
13 and 14 show specific examples of drive control of the water storage pump 11. In FIG. 13, first, the control mode is determined. If it is not bathroom drying, that is, if it is a normal dehumidification mode, the water level detection timer T is started, and when the time is up, the mode is shifted to the water level detection mode. First, when the water storage sensor 207 detects that the water storage tank 9 is full and is turned off, the operation is stopped and notified as drain processing, so that the water storage tank 9 is drained. If the water storage sensor 207 does not detect the full state and is in the on state, the process proceeds to A in FIG. 14, and while the water receiving sensor 131 detects the predetermined water level and is on, the water storage pump 11 is driven to drive the water storage tank 9. When the water receiving sensor 131 detects the lowest water level and turns off, the pump driving timer T1 is started, the water supply is continued until the time is up, and when the time is up, the water storage pump 11 is turned off.
[0077]
In the bathroom drying mode in FIG. 13, the process shifts to B in FIG. 14, and when the operation switch changes from on to off or when the water storage sensor 207 is on, the pump drive timer T2 is stopped to stop the operation. After setting, the water storage pump 11 is driven until the time is up, and the pump is stopped by the time up. When the operation switch does not change from on to off, or when the water storage sensor 207 is off, whether or not the drain cap 209 is attached or detached is determined by the drain sensor 210. If the drain sensor 210 is off and the drain cap 209 is not attached. If so, the water storage pump 11 is stopped. When the drain sensor 210 is on and the drain cap 209 is in the mounted state, the control of FIG. 14A and below is performed in the same manner as in the normal dehumidification mode.
[0078]
【The invention's effect】
According to the dehumidifier of the present invention, the combination of a moisture absorbent, a dehumidifying fan, a regeneration heater, a regeneration fan, and a heat exchanger repeatedly dehumidifies indoor air with a moisture absorbent in a circulation system, and absorbs moisture from indoor air. Dehumidifying water is repeatedly passed through the heated absorbent to remove the dehumidifying water to regenerate the indoor air by assuring the moisture absorption function for the indoor air and dehumidifying with a smaller and lighter than the type using a compressor. Function can be satisfied.
[0079]
At this time, the moisture absorption of the moisture absorbent is determined by the humidity of the moisture absorbed by the regenerated air heated from the room air, and the amount of heat required to remove the humidity, that is, the temperature of the regenerated heater with respect to the temperature of the regeneration heater. It can be known from the falling temperature. Further, the saturated moisture absorption amount per unit volume of the moisture absorbent is known. From these, at least one of the temperature of the regeneration heater, the number of revolutions of the regeneration fan, the number of revolutions of the dehumidification fan, and the moving speed of the moisture absorbent is determined according to the level of the moisture absorption of the moisture absorbent detected by the sensor. By changing, the moisture absorbing material can be placed in a state suitable for absorbing moisture, and the dehumidifying function as set can be exhibited.
[0080]
By changing the dehumidification condition in response to a predetermined change in the moisture absorption, it is difficult to feel a subtle change in the dehumidification, so the dehumidification condition is changed when there is a predetermined change in the moisture absorption of the hygroscopic material. This does not cause a problem, and the change operation does not needlessly be performed. As a result, it is possible to prevent a frequent change operation from causing a failure or shortening the service life.
[0081]
In addition, the change of the dehumidification condition is performed in response to the variation of the average moisture absorption within a predetermined time, and the operation of changing the dehumidification condition is performed by watching the variation of the moisture absorption in a predetermined time unit. You don't need to waste time. As a result, it is possible to prevent a frequent change operation from causing a failure or shortening the service life. In particular, the average value is used to check the moisture absorption in the specified time unit, so the improper or abnormal setting due to the irregular detection / absorption is used to maintain the constant dehumidification condition until the next predetermined time elapses. Can be avoided.
[0082]
Changes in the dehumidification conditions are made in accordance with the moisture absorption detected at the beginning of the operation, and thereafter, in response to fluctuations in the moisture absorption. The fact that the moisture absorption state is not constant due to the influence of humidity is corrected by changing the dehumidification condition based on the moisture absorption detected at the beginning of the operation, and responding to the variation in the moisture absorption during the initial operation. Is adjusted by the variation of the moisture absorption, so that the conditions suitable for moisture absorption can be set both in the initial operation and thereafter.
[0083]
The change of the dehumidification condition is performed in response to the change in the moisture absorption, under a predetermined condition that is less than the change corresponding to the change for a predetermined time, and then performed under the change condition corresponding to the change, thereby changing the dehumidification condition. When there is a change in the degree of moisture absorption that should be performed, it is possible to avoid an abrupt change due to a sudden change to a predetermined condition corresponding to the change, thereby stabilizing the operation state.
[Brief description of the drawings]
FIG. 1 is a longitudinal sectional view showing the entire configuration of an embodiment of a dehumidifier according to the present invention.
FIG. 2 is a cross-sectional view of the dehumidifier of FIG.
FIG. 3 is a rear view of a partition wall having a moisture absorbent of the dehumidifier of FIGS. 1 and 2;
FIG. 4 is a perspective view of the partition wall of FIG. 3 as viewed from the rear side.
FIG. 5 is a perspective view showing a heat exchanger of the dehumidifier in FIGS. 1 and 2;
FIG. 6 is a sectional view showing a water receiver of the dehumidifier of FIGS. 1 and 2;
FIG. 7 is a plan view of the water receiver of FIG. 6;
FIG. 8 is a cross-sectional view of a main part of a communication path portion between a heat exchanger and a regeneration fan of the dehumidifier in FIGS. 1 and 2;
FIG. 9 is a block diagram illustrating an example of a control device of the dehumidifier of FIGS. 1 and 2;
10 is a flowchart showing an example of monitoring control of a hygroscopic material by humidity of the control device shown in FIG. 9;
11 is a flowchart showing an example of monitoring control of a hygroscopic material based on the temperature of the control device shown in FIG. 9;
12 is a flowchart illustrating a control example of a bathroom drying mode of the control device illustrated in FIG. 9;
FIG. 13 is a flowchart of a former stage showing a control example of a water storage pump of the control device shown in FIG. 9;
14 is a flowchart subsequent to the flowchart shown in FIG. 13 of the control device shown in FIG. 9;
[Explanation of symbols]
A circulatory system
1 hygroscopic material
2 indoor air
3 Dehumidification fan
4 Regeneration air
5 Regeneration heater
6 Reproduction fans
7 heat exchanger
8 Water tray
11 water storage pump
28 Operation panel
71 Geared motor
131 Water receiver sensor
201 Moisture absorption sensor
202 Control device
204 temperature sensor
205 Humidity sensor
206 Dehumidification sensor
207 Water storage sensor
208 Indicator lamp
209 Drain cap
209a Drain outlet
210 Drain sensor

Claims (6)

A humidifying material that moves repeatedly, a dehumidifying fan that passes indoor air through the humectant and then returns to the room to dehumidify the room, and circulates that heats the air and passes through the humidifying material to remove and regenerate dehumidified water. A regenerative heater and a regenerating fan that repeats in the system, and a heat exchanger that separates the dehumidified water by exchanging heat with the dehumidified air that is passed through the hygroscopic material to take dehumidified water and return to the regenerative heater side. A sensor for detecting the degree of moisture absorption of the material, and at least one of dehumidification of the temperature of the regeneration heater, the number of revolutions of the regeneration fan, the number of revolutions of the dehumidification fan, and the moving speed of the moisture absorbent according to the level of the degree of moisture absorption of the moisture absorbent. A dehumidifier characterized by changing conditions. 2. The dehumidifier according to claim 1, wherein the degree of moisture absorption is detected by the humidity or temperature of the moisture-absorbed air after the regeneration of the moisture absorbent. 3. The dehumidifier according to any one of claims 1 and 2, wherein the change in the dehumidification condition is performed in accordance with a predetermined change in the degree of moisture absorption. The dehumidifier according to any one of claims 1 to 3, wherein the change in the dehumidification condition is performed in accordance with a change in the average moisture absorption within a predetermined time. The dehumidifier according to any one of claims 1 to 4, wherein the change in the dehumidification condition is performed in accordance with the moisture absorption detected in the early stage of the operation, and thereafter, the change is performed in response to a change in the moisture absorption. The change in the dehumidifying condition is performed under a predetermined condition that is less than a change corresponding to the change in moisture absorption in response to a change in the degree of moisture absorption, and then performed under a change condition corresponding to the change. The dehumidifier according to claim 1.

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