JP3704778B2 - Static dehumidifier - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention, StaticIt belongs to the technical field of a dehumidifying device incorporating a stationary dehumidifier.
[0002]
[Prior art]
  As this type of device, for example, a drying device that makes a bathroom a dry atmosphere and can be used as a drying room for clothes or the like is known, and can be roughly classified into a device that does not rotate a dehumidifier. The former uses a dehumidifying rotor capable of reversible moisture absorption and dehumidification as a dehumidifier as disclosed in, for example, Japanese Utility Model Laid-Open No. 6-10782 and Japanese Patent Laid-Open No. 7-180956. . Examples of the latter include, for example, JP-A-5-164359 and JP-A-63-287532.In the newsAs shown, a static dehumidifier capable of reversibly absorbing and releasing moisture is used.
[0003]
Although the dehumidifying rotor can be continuously dehumidified, it requires a dynamic seal at the part that feeds the airflow to the rotating dehumidifying rotor, making the configuration complicated and the equipment large. Since the dehumidifier is configured so as not to move, a moving seal is unnecessary and a simple configuration can be adopted, and the manufacture is relatively easy.
[0004]
The dehumidifier itself is either a rotary type or a static type, and is formed by winding a corrugated material or a honeycomb material to which a hygroscopic agent such as silica gel is attached, to form a cylindrical shape, or to form a hexahedral block by stacking. . If the processing air is passed through the passage of the dehumidifier having such a configuration, the air is dehumidified to obtain dry air. Moreover, if the heated air is passed through the passage of the dehumidifier that has absorbed moisture, the dehumidifier is dehumidified and regenerated to exhibit the dehumidifying function again.
[0005]
The dehumidification technique using a static dehumidifier disclosed in Japanese Patent Application Laid-Open No. 63-287532 is a dehumidification process in which room air is passed through the static dehumidifier and then returned to the room, and indoor or outdoor air is heated. Then, the regeneration process of passing through a dehumidifier and exhausting the air outside is repeated alternately. In a drying apparatus to which this technology is applied, as shown in FIG. 13, a stationary dehumidifier 101 is provided in a ventilation path 102 through which indoor air is circulated, and a damper 103 provided in the ventilation path 102 is switched. It is configured to repeat dehumidification / regeneration (ventilation) alternately. An air flow in the same direction flows into the dehumidifier 101 in both the dehumidification process and the regeneration process, and a heater 104 is provided on the upstream side of the dehumidifier 101 to heat the air flow in the regeneration process.
[0006]
[Problems to be solved by the invention]
The drying apparatus using the conventional static dehumidifier 101 as described above cannot fully extract the dehumidifying function of the dehumidifier 101 itself, and remains unsatisfactory in performance. That is, the moisture absorption capacity of this type of dehumidifier 101 is affected by temperature, and the lower the temperature, the higher the moisture absorption capacity. However, the direction of the airflow flowing through the dehumidifier 101 in the dehumidification process and the regeneration process is the same direction. For this reason, when shifting from the regeneration process to the dehumidification process, the airflow always flows from the side that has become hot during the regeneration process, and the characteristics of the dehumidifier 101 cannot be fully utilized.
[0007]
In addition, as described in the section of the prior art, many drying apparatuses can be ventilated by using a configuration for performing a regeneration process. However, in the conventional stationary drying apparatus described above, the ventilation operation is performed. However, since the room air is discharged through the dehumidifier 101, only a small air volume can be ventilated, and it is not possible to cope with a case where ventilation with a large air volume is required.
[0008]
  The present invention has been made to solve the above-described conventional problems, and the problem is that a dehumidification method using a static dehumidifier that can better extract the dehumidifying function of the static dehumidifier.LiveA simple static dehumidifier having a configuration in which the regeneration and heating of the dehumidifier can be performed with a single heater, and the function of the static dehumidifier is improved. It is to obtain a static dehumidification device that can ventilate a large amount of air, and to obtain a static dehumidification device that can accurately switch between dehumidification and regeneration.
[0009]
[Means for Solving the Problems]
  In order to achieve the object, the invention of claim 1There are a large number of linear passages through which the processing air passes, and a stationary dehumidifier with a reversible moisture absorption / release function is interposed in the middle of the ventilation path where the outlet end and the inlet end are opened indoors. On the inlet end side from the dehumidifier of this ventilation path, a blower that forms an air flow from the inlet end to the outlet end through each passage of the dehumidifier is incorporated in the ventilation path, and the outlet end side from the dehumidifier of this ventilation path Is equipped with a heater that raises the temperature of the air passing through the section, and it can be opened and closed by a damper between the dehumidifier and the blower of this ventilation path. Another damper that opens and closes the relevant part of the ventilation path is provided between the connection part to the exhaust passage and the blower, and the air sucked by the blower by closing the ventilation path of this damper and opening the damper of the exhaust passage From the heater side to the dehumidifier Providing a play for the passage out to the outsideAdopt meansThe
[0010]
  By adopting the above means,By opening and closing the damper, an air flow in the opposite direction can flow into the dehumidifier. If the air flow is on the downstream side of the heater, the air dehumidified by the dehumidifier can be supplied to the room to make the room dry, and if the heater is operated, the room can be heated by warm air. . Also, if the regeneration passage is opened, the exhaust passage is opened, and the heater is operated, the dehumidifier can be regenerated by the heated air flow, and the air used for regeneration is exhausted from the exhaust passage, so that the indoor ventilation Is also performed. Furthermore, if the regeneration passage is closed and the exhaust passage is opened, most of the air flow from the blower is sent to the exhaust passage without passing through the dehumidifier.be able to.
[0011]
  In order to achieve the above object, the invention of claim 2 is characterized in that there are a large number of linear passages through which the processing air passes, and a stationary type dehumidifier having a reversible moisture absorption / release function is provided at both ends. It is interposed in the middle of the ventilation path that opens to the interior of each room, and on the opening end side of the dehumidifier of this ventilation path as the boundary, the other opening through the passage of the dehumidifier from one opening end to the ventilation path An axial blower that forms an air flow toward the end is incorporated, and a heater that raises the temperature of the air passing through the relevant part is installed between the dehumidifier and the blower of this ventilation path, and the dehumidifier of the ventilation path is installed. On the other opening end side as a boundary, a damper that can be opened and closed by a damper, communicates with an exhaust passage communicating with the outside, and alternately opens and closes the connecting portion with the exhaust passage of the ventilation path and the other opening end is provided. Communicate across the dehumidifier between the part where the heater faces and the open end opened and closed by the damper The opening and closing meansWith a bypassProvided means to reverse the wind direction by alternately rotating the fan forward and backward.
[0012]
  By adopting the above means,By rotating the blower forward and backward, an air flow in the opposite direction can be caused to flow into the dehumidifier. If the exhaust passage is closed by a damper and the air flow is such that the heater side is on the downstream side, the air dehumidified by the dehumidifier can be supplied into the room to make the room a dry atmosphere. If the heater is operated in this state, the room can be heated with warm air. Moreover, if the opening end of the ventilation path is closed with a damper, the exhaust passage is opened, the heater is operated, and the heater side is an upstream air flow, the dehumidifier can be regenerated by the heated air flow. Since the air supplied to is exhausted from the exhaust passage, the room is also ventilated. And when the dehumidifier is regenerated, the opening and closing means is opened to circulate the indoor air through the bypass.be able to.
[0013]
  In order to achieve the above object, the invention of claim 3 provides:An auxiliary heater is provided in the ventilation path near the heater in the means according to claim 1.Adopt means.
[0014]
  By adopting the above means,In addition to the function according to claim 1 or 2, the heating function can be improved and the auxiliary heater can be operated during dehumidification to raise the temperature of the room.The
[0015]
  In order to achieve the above object, the invention of claim 4 provides:Either claim 1 or claim 2In such meansHumidity sensors are installed near both sides of the dehumidifier passage end, and the air feeding direction to the dehumidifier is alternately switched by the controller based on the difference between the detected values of these humidity sensors.Adopt a means.
[0016]
  By adopting the above means,Either claim 1 or claim 2With such a function,Accurately grasps moisture absorption / regeneration of the dehumidifier and automatically switches between dehumidification / regenerationCan.
[0017]
  In order to achieve the above object, the invention of claim 5 is a claim.1Or claims2In the means according to any ofTemperature sensors are installed near both sides of the dehumidifier's passage end, and the air feeding direction to the dehumidifier is alternately switched by the controller based on the difference between the detected values of these temperature sensors.Adopt a means.
[0018]
  By adopting the above means, the claim1Or claims2Along with the function according to eitherGrasping moisture absorption / regeneration of the dehumidifier accurately and switching between dehumidification / regeneration automaticallybe able to.
.
[0025]
DETAILED DESCRIPTION OF THE INVENTION
Next, embodiments of the present invention will be described with reference to the drawings.
Embodiment 1 of the Invention
The dehumidifying method of the first embodiment is to dehumidify the room as shown in FIG. 2 using the dehumidifier 1 having the structure as shown in FIG. 1 having a reversible moisture absorption / release function. . As shown in FIG. 1, a dehumidifier 1 applied to this dehumidifying method is formed by laminating a corrugated structure material or a honeycomb structure material in which a hygroscopic agent such as silica gel is bonded to inorganic fibers such as ceramics using a polymerization reaction. In addition, a large number of linear passages 2 through which the processing air passes are configured in a rectangular parallelepiped shape or a cubic shape distributed throughout. Each passage 2 is parallel, and the opening ends thereof are all open on two opposing surfaces of the dehumidifier 1.
[0026]
As shown in FIG. 2, the dehumidifier 1 having the above-described configuration is interposed in the ventilation path 3 so that each of the paths 2 constitutes a part of the ventilation path 3 to form the stationary dehumidifier 1. The stationary dehumidifier 1 is made to repeat the dehumidification process and the regeneration process alternately. The dehumidifying process is a process in which indoor air is sucked by the blower 4 and passed through the dehumidifier 1 in the ventilation path 3 to be dehumidified and returned to the room. The regeneration process is a process in which the indoor air sucked by the blower 4 is heated to about 140 ° C. by a heater 5 as a heating means provided in the air passage 3 and then passed through the dehumidifier 1 to be discharged outside the room. A feature of the dehumidifying method of the first embodiment is that the indoor air passing directions to the dehumidifier 1 are reversed in the dehumidifying process and the regeneration process.
[0027]
The moisture absorption capacity of this type of dehumidifier 1 is affected by the temperature, and the lower the temperature, the higher the moisture absorption capacity. However, when the direction of the airflow flowing through the dehumidifier 1 in the dehumidification process and the regeneration process is the same direction, When shifting from the regeneration process to the dehumidification process, the air flow in the dehumidification process always flows from the side that has become hot during the regeneration process, and the above-described characteristics of the dehumidifier cannot be fully utilized. On the other hand, when the passage direction of the room air to the dehumidifier 1 in the dehumidifying process and the regeneration process is opposite, that is, counterflow, the temperature on the inflow side in the dehumidifying process of the dehumidifier 1 that has undergone the regeneration process. Can be prevented, the dehumidifying performance of the dehumidifier 1 can be brought out, and the energy efficiency can be increased.
[0028]
The time of the dehumidifying process is set slightly shorter than the time of the regeneration process, and the reversal of the direction of the airflow can be performed by switching the air path by opening / closing the damper 6 or by combining the forward / reverse switching of the axial flow type blower and the damper. good. If a temporal cushion at the time of transition from the regeneration process to the dehumidification process, that is, a short cooling time is set, the temperature on the inflow side in the dehumidification process of the dehumidifier 1 that has undergone the regeneration process can be further reduced. The dehumidifying function of the dehumidifier 1 can be brought out.
[0029]
According to the dehumidifying method of the first embodiment, not only the functionality of the dehumidifier 1 can be improved, but also the heater 5 used in the regeneration process can be used to perform heating. That is, if an air flow in the same direction as the dehumidifying process is formed and the heating means is operated, heating by blowing warm air into the room is realized. At this time, since the heater 5 used in the regeneration process is positioned downstream of the dehumidifier 1, the heated airflow does not pass through the dehumidifier 1, so that the dehumidifier 1 does not lose heat and its life. Is not shortened, and it is possible to smoothly shift to the dehumidifying process for the reasons described above.
[0030]
Each embodiment described below relates to a static dehumidifier using the dehumidification method using the static dehumidifier 1 shown in the first embodiment.
[0031]
Embodiment 2 of the Invention
FIG. 3 is a cross-sectional configuration diagram showing the static dehumidifier of the second embodiment, and FIG. 4 is a vertical cross-sectional configuration diagram. This static dehumidifier is the same as the stationary dehumidifier 1 shown in Embodiment 1 in the middle of an air passage 9 in which an indoor outlet 7 and an indoor inlet 8 are opened as outlet ends and inlet ends, respectively. Ventilation by the passage 2 is possible. The ventilation path 9 is defined in a main body casing 11 attached to a ceiling or the like of a room to be dehumidified such as a bathroom 10, and the indoor suction port 8 and the indoor air outlet 7 are separated from each other on the lower surface of the main body casing 11. Open to the room. A grill is provided at the indoor inlet 8 and the indoor outlet 7, and a filter 12 is mounted inside the grill of the indoor inlet 8.
[0032]
A blower 13 that forms an air flow by indoor air from the dehumidifier 1 of the ventilation path 9 to the indoor suction port 8 side through the passage 2 of the dehumidifier 1 from the indoor suction port 8 to the indoor outlet 7 in the ventilation path 9. Is incorporated. In addition, a heater 14 that raises the temperature of the air passing through the part is incorporated in a state crossing the ventilation path 9 on the side of the indoor outlet 7 from the dehumidifier 1 of the ventilation path 9. Between the dehumidifier 1 and the blower 13 in the ventilation path 9, there is communicated an exhaust passage 16 that can be opened and closed by an electric damper 15 and one end communicates with the outside. An electric damper 17 that opens and closes the portion of the ventilation path 9 is provided between a portion of the exhaust passage 16 that communicates with the ventilation path 9 and the blower 13. In the vicinity of the dehumidifier 1, a regeneration passage 18 is formed in parallel with the portion of the ventilation passage 9 formed by each passage 2. One end of the regeneration passage 18 communicates with the ventilation path 9 near the blower outlet of the blower 13, and the other end communicates with the ventilation path 9 between the indoor blowout opening 7 and the heater 14. The electric damper 17 that opens and closes the ventilation path 9 is configured to close the regeneration passage 18 by opening the ventilation path 9 and open the regeneration path 18 by closing the ventilation path 9.
[0033]
A uniform plate 19 made of a thin plate of metal or the like in which a large number of small holes are distributed almost uniformly on the entire surface is provided between the heater 14 and one surface serving as an entrance / exit facing the opening end of each passage 2 of the dehumidifier 1. It is attached so as to cross the ventilation path 9. Moreover, the 1st and 2nd temperature sensors 20 and 21 are integrated in the ventilation path 9 of the vicinity of the opposing surface which the opening end of each channel | path 2 of the dehumidifier 1 faces. The first temperature sensor 20 and the second temperature sensor 21 are connected to a controller 22 incorporated in the main body casing 11, and any detection output is input to the controller 22. The operation of the heater 14, the electric dampers 15, 17 and the blower 13 is controlled by the controller 22.
[0034]
As shown in FIG. 5, the stationary dehumidifier having the above-described configuration is attached using the space behind the ceiling so that the indoor suction port 8 and the indoor air outlet 7 face and open on the ceiling surface of the room such as the bathroom 10. . One end of the exhaust passage 16 is connected to the outside by a duct 23. In this apparatus, the electric dampers 15, 17, the blower 13, and the heater 14 are controlled by the controller 22, and the alternating installation of the dehumidifying process and the regeneration process is repeated to make the installed room a dry atmosphere. That is, in the dehumidifying process, the blower 13 is operated, the electric damper 15 of the exhaust passage 16 is kept closed, the electric damper 17 of the ventilation passage 9 is operated to open the ventilation passage 9 and close the regeneration passage 18, The energization to the heater 14 is cut off.
[0035]
Thereby, indoor air is sucked into the ventilation path 9 from the indoor suction port 8 by the blower 13. The sucked air passes through the passages 2 of the dehumidifier 1 from the direction indicated by the solid line in the figure, and is blown into the room from the indoor outlet 7 to circulate the room air. The indoor air sucked by passing through each passage 2 of the dehumidifier 1 interposed in the ventilation path 9 is dehumidified and returned to the room as dry air, whereby a dry atmosphere advances in the room.
[0036]
In the regeneration process performed after the dehumidification process, the operation of the blower 13 is continued, the electric damper 15 of the exhaust passage 16 is opened, the electric damper 17 of the ventilation path 9 closes the ventilation path 9, and the regeneration path 18 opens. The heater 14 is energized. Thereby, indoor air is sucked into the ventilation path 9 from the indoor suction port 8 by the blower 13. The sucked air flows into the ventilation path 9 from the heater 14 side through the regeneration passage 18. And a part passes the heater 14, it is heated to about 140 degreeC, the temperature distribution is equalized by the uniform board 19, and it passes each channel | path 2 of the dehumidifier 1 from the direction of a dotted arrow in the figure, and is open | released. The air is exhausted from the passage 16 to the outside of the room to ventilate the room. When the hot air passes through each passage 2 of the dehumidifier 1 interposed in the ventilation path 9, the dehumidifier 1 that has absorbed moisture in the previous dehumidifying process is released, and the dehumidifier 1 is regenerated.
[0037]
Part of the indoor air that has passed through the regeneration passage 18 returns to the room from the indoor outlet 7 and forms a circulating flow in the room, although not much. Therefore, some degree of indoor drying is achieved even during the regeneration process. By alternately repeating the dehumidification process and the regeneration process, the bathroom or the like can be made into a dry atmosphere together with ventilation. When the objects to be dried 24 such as clothes are hung in the bathroom 10 and dried, the drying time becomes shorter in a dry atmosphere having a higher degree of drying. However, it is also an important factor that shortens the drying time to quickly remove the moisture taken away from the object to be dried 24 from the object to be dried 24 and eliminate it. In this static dehumidifier, part of the air circulates in the regeneration process as described above, and the moisture peeled off by the exhaust is discharged to the outside, so that the moisture is quickly separated from the material to be dried 24. The drying time is shortened.
[0038]
The transition from the dehumidification process to the regeneration process and the transition from the regeneration process to the dehumidification process are performed by the controller 22 based on the detection values of the first temperature sensor 20 and the second temperature sensor 21. As dehumidification progresses in the dehumidification process, the temperature rise due to heat of adsorption decreases, and if the dehumidifier 1 loses its adsorption capacity, the upstream and downstream temperatures of the dehumidifier 1 are in an equilibrium state. When these temperatures reach a predetermined temperature difference before equilibration, the controller 22 operates to shift to the regeneration process. Further, in the regeneration process, as the moisture release progresses, the temperature drop due to the moisture release decreases, and if the moisture release from the dehumidifier 1 disappears, the upstream and downstream temperatures of the dehumidifier 1 reach a high equilibrium state. When these temperatures reach a predetermined temperature difference before equilibration, the controller 22 operates to shift to the dehumidifying process. Thereby, moisture absorption and regeneration of the dehumidifier 1 can be accurately grasped, and dehumidification and regeneration can be automatically switched.
[0039]
The dehumidifying capacity of the dehumidifier 1 is affected by the temperature. The lower the temperature, the higher the dehumidifying capacity. Therefore, when the regeneration is completed in the regeneration process, the temperature of the dehumidifier 1 is shifted to the dehumidification process at a high temperature. Therefore, it is not preferable. The static dehumidifier of the second embodiment utilizes the dehumidification method shown in the first embodiment, and in the dehumidification process and the regeneration process, the direction of the airflow passing through the dehumidifier 1 is reversed to form a counter flow. Therefore, the effect as shown in the first embodiment can be obtained as it is.
[0040]
As described above, since the indoor air is circulated in the dehumidifying process, the function of the dehumidifying process can be used as it is, and the heater 14 that is not normally used in the dehumidifying process can be operated to heat the room. In this case as well, this static dehumidifying device in which the heater 14 is located downstream of the dehumidifier 1 does not pass the heat to the dehumidifier 1 because the warm air does not pass through the dehumidifier 1, so the heat of the heater 14 is used for heating. Can work effectively. Further, it is possible to prevent the dehumidifier 1 from being thermally deteriorated due to continuous heating operation for a long time. This heating operation can also be performed in the dehumidification process. That is, when the room temperature is low or the object to be dried 24 is desired to be dried quickly, the heater 14 is operated even in the dehumidifying process, and if the room temperature is raised, the evaporation of moisture is promoted and the drying time can be shortened.
[0041]
Also, as described above, in the regeneration process, indoor air is exhausted, so indoor ventilation is performed. However, since the dehumidifier 1 is allowed to pass through, only a small amount of ventilation can be expected, and ventilation with a large amount of air is required. I can not cope with the case. In this static type dehumidifier, the indoor air blown from the blower 13 is operated by switching the electric damper 17 to the side for closing the regeneration passage 18 and opening the electric damper 15 of the exhaust passage 16 to operate the blower 13. Can be exhausted from the exhaust passage 16 to the outside without passing through the dehumidifier 1. That is, if necessary, a large air volume can be ventilated, which has an expanded function.
[0042]
Note that switching between the dehumidifying process and the regeneration process may be performed by setting a timer in the controller 22 and setting time by the timer. The apparatus for drying the bathroom 10 may be set to perform a regeneration process of about 2 minutes after a dehumidification process of about 3 minutes to 5 minutes. Further, even if the first temperature sensor 20 and the second temperature sensor 21 are replaced with the first humidity sensor 25 and the second humidity sensor 26, the transition between the dehumidification process and the regeneration process can be automatically performed. . That is, as the dehumidification progresses in the dehumidification process, the adsorption capacity of the dehumidifier 1 decreases, and the upstream and downstream humidity of the dehumidifier 1 eventually reach an equilibrium state. The controller 22 may be operated so as to shift to the regeneration process when the humidity becomes a predetermined humidity difference before equilibration. In addition, as the moisture release proceeds in the regeneration process, the amount of moisture released decreases, and the humidity on the upstream side and the downstream side of the dehumidifier 1 eventually reaches an equilibrium state. If the controller 22 is operated so as to shift to the dehumidifying process at the time when the humidity becomes a predetermined humidity difference before equilibration, dehumidification / regeneration can be automatically switched as in the case of the temperature sensor. .
[0043]
The uniform plate 19 is a functional component for eliminating unevenness of the heat distribution of the air flow by the heater 14, uniformizing it, and feeding it to the dehumidifier 1. By providing the uniform plate 19, the regeneration function of the regeneration process can be stabilized, Further, although the dehumidifier 1 can be prevented from deteriorating due to the radiant heat of the heater 14, it is accompanied by pressure loss, so it is not an indispensable part, and even if it is removed, the above-described functions are not hindered.
[0044]
If the electric dampers 15 and 17 are switched as in the dehumidification process, the heater 14 is stopped and the blower 13 is operated, a part of the room air can be ventilated while circulating indoor air. Thus, a small air volume ventilation with an appropriate air volume is performed through the exhaust passage 16, and at the same time, indoor air can be circulated through the regeneration passage 18 and the indoor outlet 7. In the bathroom 10 after bathing, it is possible to dry walls and floors by this ventilation operation, and it is possible to suppress the occurrence of mold and the like.
[0045]
Embodiment 3 of the Invention
The static dehumidifier of the third embodiment is a further improvement of the heating function of the static dehumidifier shown in the second embodiment, and the configuration other than the configuration related to the heating function is shown in the second embodiment. Is the same. Therefore, the same reference numerals are used for the same parts as those of the second embodiment, and description thereof will be omitted.
[0046]
As shown in FIGS. 6 and 7, this static dehumidifier has a configuration in which an auxiliary heater 27 is incorporated in the vicinity of the indoor outlet 7 of the main body casing 11. The regeneration of the dehumidifier 1 is performed by operating the heater 14 as in the second embodiment. By operating this auxiliary heater 27 together with the heater 14, it is possible to perform rapid heating. In addition, when the room temperature is low or when it is desired to dry the material to be dried 24 quickly, only the auxiliary heater 27 is operated to increase the room temperature, promote the evaporation of moisture, and shorten the drying time. . Since other configurations and functions are the same as those of the second embodiment, description thereof will be omitted.
[0047]
Embodiment 4 of the Invention
The static dehumidifier of Embodiment 4 is one in which the flow of air to the dehumidifier 1 in the dehumidification process and the regeneration process is reversed by forward and reverse rotation of the axial flow type blower. This is the same as the static dehumidifier shown in the second embodiment. Therefore, the same reference numerals are used for the same parts as those of the second embodiment, and description thereof will be omitted.
[0048]
As shown in FIGS. 8 and 9, the static dehumidifier of the fourth embodiment is different from the static dehumidifier 1 shown in the first embodiment in that the indoor outlet 7 and the indoor inlet 8 are the outlet end and the inlet end. In the middle of the ventilation path 9 respectively opened in the room, ventilation through the passage 2 is possible. The ventilation path 9 is defined in a main body casing 11 attached to a ceiling or the like of a room to be dehumidified such as a bathroom, and the indoor suction port 8 and the indoor air outlet 7 are separated from each other on the lower surface of the main body casing 11. It opens toward the room. The indoor suction port 8 and the indoor air outlet 7 are provided with grills, and filters 12 are attached to the insides of the grills.
[0049]
An axial flow blower 28 that forms an air flow in the ventilation path 9 is incorporated on the ventilation outlet 9 side of the ventilation path 9 from the dehumidifier 1. The blower 28 is operated forward and backward alternately by the controller 22. A heater 14 for raising the temperature of the air passing through the part is incorporated in a state of crossing the ventilation path 9 on the side of the indoor outlet 7 from the dehumidifier 1 of the ventilation path 9. Between the dehumidifier 1 of the ventilation path 9 and the indoor suction port 8, there is communicated an exhaust passage 16 that can be opened and closed by an electric damper 29 and one end communicates with the outside. The electric damper 29 is configured to close the exhaust passage 16 by opening the ventilation passage 9 on the indoor suction port 8 side and open the exhaust passage 16 by closing the indoor suction port 8 side.
[0050]
Similarly to the second embodiment, the stationary dehumidifier configured as described above uses the space behind the ceiling so that the indoor air inlet 8 and the indoor air outlet 7 face the ceiling surface of the room such as the bathroom 10. Mounted. One end of the exhaust passage 16 is connected to the outside by a duct. In this apparatus, the controller 22 controls forward / reverse switching of the electric damper 29 and the blower 28 and the heater 14, and alternate switching between the dehumidification process and the regeneration process is repeated to make the installed room a dry atmosphere. That is, in the dehumidifying process, the blower 28 is rotated forward, the exhaust passage 16 is kept closed by the electric damper 29, the indoor suction port 8 of the ventilation passage 9 is opened, and the energization to the heater 14 is cut off.
[0051]
Thereby, the indoor air is sucked into the ventilation path 9 from the indoor suction port 8 by the blower 28. The sucked air passes through the passages 2 of the dehumidifier 1 from the direction indicated by the solid line in the figure, and is blown into the room from the indoor outlet 7 to circulate the room air. The indoor air sucked by passing through each passage 2 of the dehumidifier 1 interposed in the ventilation path 9 is dehumidified and returned to the room as dry air, whereby a dry atmosphere advances in the room.
[0052]
In the regeneration process performed after the dehumidification process, the blower 28 is reversed, the exhaust passage 16 is opened by the operation of the electric damper 29, the indoor suction port 8 of the ventilation path 9 is closed by the electric damper 29, and the heater 14 is energized. Done. Thereby, the indoor air is sucked into the ventilation path 9 from the indoor outlet 7. The sucked air passes through the heater 14 and is heated, passes through each passage 2 of the dehumidifier 1 from the direction indicated by the dotted line arrow, and is exhausted from the open exhaust passage 16 to the outside of the room to ventilate the room. When the hot air passes through each passage 2 of the dehumidifier 1 interposed in the ventilation path 9, the dehumidifier 1 that has absorbed moisture in the previous dehumidifying process is released, and the dehumidifier 1 is regenerated.
[0053]
If the blower 28 is rotated forward, the exhaust passage 16 is closed by the electric damper 29, and the heater 14 is energized, the room can be heated. The rest is basically the same as that of the second embodiment. That is, the uniform plate 19 can be provided, and the first and second temperature sensors 20 and 21 can be alternately switched between the dehumidifying process and the regeneration process. However, unlike the second embodiment, ventilation with a large air volume is impossible.
[0054]
Embodiment 5 of the Invention
In the static dehumidifier of the fifth embodiment, the air flow to the dehumidifier 1 in the dehumidification process and the regeneration process is reversed by forward / reverse rotation of the axial blower 28 as in the fourth embodiment. However, it is basically the same as the static dehumidifier shown in the fourth embodiment. Therefore, the same reference numerals are used for the same parts as those of the fourth embodiment, and description thereof will be omitted.
[0055]
The stationary dehumidifier of the fifth embodiment shown in FIGS. 10 and 11 sends a part of air into the room even during the regeneration process so as to form a circulation flow advantageous for drying. That is, a bypass 30 is provided across the dehumidifier 1 in the ventilation path 9. A damper 31 that opens and closes the bypass 30 is incorporated in the bypass 30. Even if the damper 31 is opened and the electric damper 29 closes the indoor suction port 8 side of the ventilation path 9, the indoor outlet of the ventilation path 9 is bypassed through the bypass 30. 7 communicates with the indoor suction port 8. As a result, similar to that shown in the second embodiment, part of the air can be circulated in the regeneration process to promote drying. Since other configurations and functions are the same as those of the fourth embodiment, description thereof will be omitted.
[0056]
Embodiment 6 of the Invention
The static dehumidifying device of the sixth embodiment is configured to attach the static dehumidifying device shown in each of the above-described embodiments to the outside, and other configurations are shown in the above-described embodiments. Is the same. Therefore, the same reference numerals are used for the same parts as those of the static dehumidifier of each embodiment, and the description thereof is omitted.
[0057]
The stationary dehumidifier of the sixth embodiment shown in FIG. 12 has a configuration in which a main body 32 incorporating functional parts such as the blower 13, the dehumidifier 1, and the heater 14 shown in the second embodiment can be attached outdoors. The main body 32 is connected to the indoor suction port 8, the indoor outlet 7, and the indoor terminal device 33 that constitutes a part of the ventilation path 9 connected to the indoor suction port 8 and the indoor outlet port 7, so as to be in a functional state. The indoor terminal device 33 is attached to an indoor inner wall surface, a ceiling surface, or the like, and the main body 32 is attached to the outside of the room such as the back of the ceiling or outdoors. The main body 32 and the indoor terminal 33 are connected by a communication duct or the like that penetrates a wall, a ceiling plate, or the like. Since other configurations are the same as those of the above-described embodiments, description thereof will be omitted.
[0058]
According to the static dehumidifying apparatus of the sixth embodiment, the room can be used widely, and it is not only useful to narrow the bathroom 10 etc., but also to the bathroom 10 etc. which is relatively narrow. There is an advantage that the structure of the main body 32 can be simplified without taking measures against water due to moisture, dew condensation or the like when applied to the main body 32. Since the other functions and advantages are the same as those shown in the above-described embodiments, description thereof will be omitted.
[Brief description of the drawings]
FIG. 1 is a perspective view showing a stationary dehumidifier used in a dehumidifying method according to a first embodiment of the invention.
FIG. 2 is an explanatory diagram showing a dehumidifying method according to the first embodiment of the invention.
FIG. 3 is a cross-sectional configuration diagram of a static dehumidifier according to Embodiment 2 of the present invention.
FIG. 4 is a longitudinal sectional configuration diagram of a static dehumidifier according to Embodiment 2 of the present invention.
FIG. 5 is an explanatory diagram showing the stationary dehumidifying device according to the second embodiment of the present invention in an installed state.
FIG. 6 is a cross-sectional configuration diagram of a static dehumidifier according to Embodiment 3 of the present invention.
FIG. 7 is a longitudinal sectional configuration diagram of a static dehumidifier according to Embodiment 3 of the present invention.
FIG. 8 is a longitudinal sectional configuration diagram of a static dehumidifier according to Embodiment 4 of the present invention.
FIG. 9 is a vertical side view of the stationary dehumidifier according to Embodiment 4 of the present invention.
FIG. 10 is a longitudinal sectional configuration diagram of a static dehumidifier according to Embodiment 5 of the present invention.
FIG. 11 is a vertical side view of the stationary dehumidifier according to Embodiment 5 of the present invention.
FIG. 12 is a longitudinal sectional configuration diagram of a static dehumidifier according to Embodiment 6 of the present invention.
FIG. 13 is a cross-sectional view showing a configuration of a conventional dry ventilation apparatus.
[Explanation of symbols]
1 Dehumidifier
2 passage
3 Ventilation path
4 Blowers
5 Heater
7 Indoor outlet
8 Indoor inlet
9 Ventilation path
13 Blower
14 Heater
15 Electric damper
16 Exhaust passage
17 Electric damper
18 Recycling passage
19 Uniform plate
20 First temperature sensor
21 Second temperature sensor
22 Controller
25 First humidity sensor
26 Second humidity sensor
27 Auxiliary heater
28 Blower
29 Electric damper
30 Bypass
31 Damper

Claims (5)

  There are a large number of linear passages through which the treated air passes, and a static dehumidifier with a reversible moisture absorption / release function is interposed in the middle of the ventilation path where the outlet end and the inlet end are opened indoors. On the inlet end side of the ventilation path from the dehumidifier, a blower that forms an air flow from the inlet end to the outlet end through each passage of the dehumidifier is incorporated in the ventilation path. From the dehumidifier of the ventilation path, A heater that raises the temperature of the air passing through the relevant part is built in the outlet end, and a damper can be opened and closed between the dehumidifier and the blower in this ventilation path, and an exhaust passage that communicates with the outside is connected. In addition, another damper for opening and closing the part of the ventilation path is provided between the connection part of the ventilation path with the exhaust passage and the blower, and closing the ventilation path of the damper and the damper of the exhaust path By opening, the air flow sucked by the blower is Introduced from over the other side to the dehumidifier static dehumidifier, characterized in that a regeneration passage out to the outdoors from the exhaust passage. There are a large number of linear passages through which treated air passes, and static dehumidifiers equipped with a reversible moisture absorption / release function are interposed in the middle of the ventilation path where the open ends of both ends are opened indoors. An axial flow type that forms an air flow from one opening end to the other opening end through one passage end of the dehumidifier in the ventilation passage on one opening end side of the ventilation passage with the dehumidifier as a boundary. The heater is installed between the dehumidifier and the blower in the ventilation path, and the other opening end with the dehumidifier in the ventilation path as a boundary. On the side, there is provided a damper that can be opened and closed by a damper, communicates with an exhaust passage that communicates with the outside of the room, and alternately opens and closes the communicating portion with the exhaust passage of the ventilation path and the other open end, and the portion where the heater faces And the open end that is opened and closed by the damper are connected across the dehumidifier That a bypass with a closing means is provided, the static dehumidifier, characterized in that the wind direction on the opposite to the positive reversed alternately the ventilator.   3. The static dehumidifier according to claim 1, wherein an auxiliary heater is provided in a ventilation path near the heater.   The static dehumidifier according to claim 1 or 2, wherein a humidity sensor is provided in the vicinity of both sides of the passage end of the dehumidifier, and the dehumidifier is provided based on a difference between detection values of these humidity sensors. A static dehumidifier characterized in that the air feeding direction is alternately switched by a controller.   The static dehumidifier according to claim 1 or 2, wherein temperature sensors are provided in the vicinity of both sides of the passage end of the dehumidifier, and air to the dehumidifier is detected based on detection values of these temperature sensors. The static dehumidifier is characterized in that the feeding direction is alternately switched by a controller.

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