JP5814671B2 - Dehumidifier and control method thereof - Google Patents

Description

  The present invention relates to a dehumidifying apparatus capable of supplying low-humidity air to a dry room, for example, and a control method thereof.

  For example, in a manufacturing process of a display device, a semiconductor device, a non-aqueous battery, etc., a dry room that is a low humidity space (ultra-low humidity space) is used. As a device for supplying low dew point air to this dry room, a dehumidifying device using dry dehumidification is known. In this dehumidifying device, the dehumidifying capacity of the adsorption rotor is restored by ventilating the processing air through the adsorption rotor (dehumidification rotor) to adsorb moisture contained in the processing air and ventilating the regeneration air heated to a predetermined temperature. I am letting.

  With regard to this type of dehumidifying device, for example, Patent Document 1 describes the relationship between the temperature of the regeneration air and the dehumidification capability, the relationship between the rotation speed of the adsorption rotor and the dehumidification capability, or the relationship between the amount of the regeneration air and the dehumidification capability. Based on the above, by controlling the regeneration capacity of the dehumidifying material of the adsorption rotor, the regeneration capacity can be freely reduced and the supply air dew point temperature of the processing air can be kept constant.

JP-A-6-63344

  However, the dehumidifying device disclosed in Patent Document 1 has various relationships such as the relationship between the temperature of the regeneration air and the dehumidification capability, the relationship between the rotation speed of the adsorption rotor and the dehumidification capability, and the relationship between the amount of regeneration air and the dehumidification capability. It is necessary to prepare characteristic data. This preparation is complicated and its control is complicated.

  The present invention has been made in view of the above points, and it is possible to stabilize the supply air dew point temperature on the secondary side even when the amount of regenerated air is changed without performing complicated control. An object of the present invention is to provide a dehumidifying device and a control method thereof.

In order to achieve the above object, the present invention is divided into a plurality of areas including a processing area, a regeneration area, and a purge area, and an adsorption rotor that adsorbs moisture in the processing air, and moisture adsorbed on the adsorption rotor. Supply air amount for detecting the supply air amount supplied to the secondary side in a dehumidifying device having a heater for heating the regenerated air for desorbing the air and a rotation drive means for rotationally driving the adsorption rotor Detection means, humidity detection means for detecting the absolute humidity of the processing air at a position before passing through the processing area of the suction rotor, and rotation for controlling the rotational speed of the suction rotor rotated by the rotation driving means The absolute humidity of the processing air detected by the speed control means, the humidity detection means, the supply air amount detected by the supply air amount detection means, and the preset supply air Before calculating the reproduction air amount based on the set value of the point temperature, and a regeneration air amount control means for controlling the reproduction air amount based on the calculation result, the process air passes through the adsorption rotor The processing area area control means is arranged to change the area of the processing area and to change the area of the processing area in accordance with the amount of supplied air. consists shielding mechanism for blocking the processing air is disposed upstream of the processing area through the processing area, and wherein Rukoto set the area of the processing area by increasing or decreasing changes of the area for shielding the processing area To do.

  According to the present invention, the regeneration air amount control means includes the absolute humidity of the processing air detected by the humidity detection means, the supply air amount detected by the supply air amount detection means, and the preset supply air The regeneration air amount can be calculated based on the set value of the dew point temperature, and the regeneration air amount can be controlled based on the calculation result. Therefore, the complicated control is not performed, and the secondary supply air dew point temperature can be stabilized even when the regeneration air amount changes.

  According to the present invention, it is possible to obtain a dehumidifying device and a control method therefor that can stabilize the supply air dew point temperature on the secondary side even when the amount of regeneration air is changed without performing complicated control. .

It is a block diagram which shows typically the dehumidification apparatus which concerns on embodiment of this invention. The structure of a shielding mechanism is shown, (a) is a figure which shows the state which the five process area adjustment plates opened, (b) is a figure which shows the state on which the five process area adjustment plates were laminated | stacked. (C) is a figure which shows the state which the process area adjustment board of 2 sheets of 5 sheets opened. (A) is explanatory drawing which shows the maximum area example which maximized the area of the processing area of the adsorption | suction rotor, (b) is explanatory drawing which shows the minimum area example which minimized the area of the processing area of the adsorption | suction rotor. It is a flowchart which shows the control method of the dehumidification apparatus which concerns on embodiment of this invention.

  Next, embodiments of the present invention will be described in detail with reference to the drawings as appropriate. FIG. 1 is a configuration diagram schematically showing a dehumidifying apparatus according to an embodiment of the present invention.

  As shown in FIG. 1, a dehumidifying device 10 according to the present embodiment supplies an adsorption rotor 12 that adsorbs moisture in processing air that is vented (passed) by a dehumidifying material (not shown) provided therein, and supplies processing air. Processing fan 14a, an inverter 14b for driving and controlling the processing fan 14a, a regeneration fan 16a for supplying regeneration air for desorbing moisture in the adsorption rotor 12, and an inverter 16b for driving and controlling the regeneration fan 16a And a heater 18 that heats the regeneration air used for moisture desorption to a predetermined temperature, and a motor (rotation drive means) 20 that rotationally drives the adsorption rotor 12 in the direction of arrow A at a desired rotational speed. Has been.

  The motor 20 includes a driver (not shown) that is electrically connected to a controller 32 to be described later and controls the rotational speed of the motor 20 based on a rotational speed control signal output from the controller 32. Thus, a rotational speed control means for controlling the rotational speed of the suction rotor 12 is configured.

  Furthermore, the dehumidifying device 10 includes a cooling coil 22a for pre-cooling external air (open air) introduced into the device, and other air for cooling the supply air (dry air) dehumidified by the adsorption rotor 12 A cooling coil 22b, a shielding mechanism (processing area area control means) 24 that makes the shielding area of the suction rotor 12 variable corresponding to the amount of air supplied to the secondary side, and the suction rotor 12 (processing area described later) 36) a temperature / humidity sensor (humidity detection means) 26 for detecting the temperature and absolute humidity of the processing air at a position (upstream side) before the processing air is vented (passed), and processing before passing through the adsorption rotor 12. A differential pressure gauge 28 for measuring the differential pressure between the pressure of the air and the pressure of the processing air after passing through the adsorption rotor 12, and the supply air (secondary side) supplied to an air-conditioned room (dry room) (not shown) A) a dew point sensor 30 for detecting the dew point temperature, and a controller (rotation speed control means, regeneration air amount control means) 32 for controlling the rotation speed of the motor 20 and calculating / controlling the regeneration air amount and the like. .

  It should be noted that the controller 32 receives the temperature and absolute humidity detection signals detected by the temperature / humidity sensor 26 and the detection signal from the dew point sensor 30 and also the differential pressure detection signal detected by the differential pressure gauge 28. The controller 32 performs predetermined control based on these detection signals and the like. The differential pressure gauge 28 and the controller 32 function as supply air amount detection means. The controller 32 is electrically connected to an inverter 14b that drives and controls the processing fan 14a. The controller 32 controls the processing fan 14a by a control signal input to the inverter 14b. The amount of air supplied) can be controlled.

  Further, the controller 32 is electrically connected to an inverter 16b that drives and controls the regeneration fan 16a, and controls the regeneration fan 16b by a control signal input to the inverter 16b, thereby controlling the amount of regeneration air. it can. Furthermore, the controller 32 can output a heating control signal to the heater 18 to control the heating temperature of the regeneration air heated by the heater 18 to a predetermined temperature.

  The adsorption rotor 12 has a disk shape, and has a dehumidifying material (not shown) made of, for example, a honeycomb-shaped nonwoven fabric impregnated with lithium chloride or silica gel, and passes processing air along the axial direction as will be described later. To absorb and remove moisture from the processing air. Further, a partition plate (not shown) is provided on the front and rear portions of the suction rotor 12, and the suction rotor 12 is divided into three areas by the partition plate. The three areas are arranged in the order of the processing area 36, the regeneration area 38, and the purge area 40 in the clockwise direction when viewed from the upstream side of the processing passage 34 described later.

  The suction rotor 12 is supported so as to be rotatable about the motor shaft of the motor 20 connected to the center thereof. By rotating the motor 20 by a rotational speed control signal from the controller 32 to a driver (not shown), the suction rotor 12 rotates along the arrow A direction at a predetermined rotational speed. As a result, the dehumidifying material (not shown) held inside the adsorption rotor 12 circulates and passes in the order of the processing area 36 → the regeneration area 38 → the purge area 40 → the processing area 36 → the regeneration area 38. Is provided.

  One end of the upstream side communicates with the outside air and external air (outside air) is introduced into the processing area 36, and the other end of the downstream side communicates with a processing passage 42 that communicates with an air-conditioned room (not shown). In the processing passage 42, the cooling coil 22a, the processing fan 14a, the temperature / humidity sensor 26, the suction rotor 12, the other cooling coil 22b, and the dew point sensor 30 are arranged from the upstream side toward the downstream side. .

  Further, as described above, the pressure of the processing air before passing through the suction rotor 12 and the dry air (supply air) after passing through the suction rotor 12 are disposed before and after the processing passage 42 with the suction rotor 12 therebetween. A differential pressure gauge 28 is provided for measuring a differential pressure with respect to the pressure.

  Further, a regeneration passage 44 that branches from the upstream side of the processing passage 42 and communicates with the purge area 40 and the regeneration area 38 is provided. After passing through the purge area 40, the regeneration passage 44 makes a U-turn, passes through the regeneration area 38, and exhausts the regeneration air into the atmosphere. In the regeneration passage 44, the heater 18 that heats the regeneration air that has passed through the purge area 40 to a predetermined temperature and the air that flows through the processing passage 42 upstream from the branch point are sucked along the regeneration passage 44. A regenerative fan 16a and an inverter 16b for circulating air are provided.

  In the regeneration passage 44, the portion from the branch point of the processing passage 42 through the purge area 40 to the portion connected to the heater 18 also functions as a purge passage. In this purge passage, the dehumidifying material passing through the purge area 40 is cooled by the precooled processing air.

  FIG. 2 shows the configuration of the shielding mechanism, FIG. 2 (a) is a diagram showing a state in which five processing area adjustment plates are open, and FIG. 2 (b) is a drawing showing five processing area adjustment plates. FIG. 2C is a diagram showing a state where two of the five processing area adjustment plates are opened.

  As shown in FIG. 2, the shielding mechanism 24 has a sector shape provided on the purge area 40 side of the processing area 36, and rotates around the processing area adjustment plates 24 a to 24 e made of a plurality of substantially arc-shaped thin plates. It is configured to be pivotally supported. In this case, the area of the processing area 36 through which the processing air passes can be increased or decreased by changing the central angle of the sector shape. In addition, in this embodiment, although the five process area adjustment plates 24a-24e are illustrated, it is not limited to this.

  The shielding mechanism 24 is provided with an actuator ACT that slides (oscillates) the plurality of processing area adjustment plates 24a to 24e to the open side or the close side by a predetermined angle. This actuator ACT is composed of, for example, an oscillating rotary actuator (vane type that directly rotates a vane, rack and pinion type that converts linear motion into rotary motion, yoke shape, crank shape, screw type), linear actuator, etc. It is good to be done.

  Further, the actuator ACT may be constituted by a fluid pressure cylinder. For example, when a trunnion-type cylinder is used as the actuator ACT (see the broken line in FIG. 2A), the tip of the piston rod is connected to the processing area adjusting plates 24a to 24e so that the piston rod can be moved forward and backward. The processing area adjusting plates 24a to 24e may be displaced and the end of the cylinder tube may be swingably supported by a pin pivotally attached to the bracket. In this case, the entire trunnion-type cylinder may be provided so as to swing around the pin as a fulcrum corresponding to the sliding amount of the plurality of processing area adjustment plates 24a to 24e. Further, each processing area adjustment plate 24a to 24e is provided with a locking claw (not shown), and when one processing area adjustment plate slides along the circumferential direction, the processing area adjustment plate 24a to 24e is locked to another processing area adjustment plate adjacent thereto. The predetermined area adjusting plates adjacent to each other are engaged and slid in conjunction with each other.

  By driving the actuator ACT, it is possible to adjust the area of the processing area 36 shielded by the shielding mechanism 24 by sliding the plurality of processing area adjusting plates 24a to 24e to the open side or the closed side. Further, the plurality of processing area adjustment plates 24a to 24e may be slid to the open side or the close side by an operator's manual operation. In addition, although the processing area adjustment plates 24a to 24e constituting the shielding mechanism 24 may be single, it is preferable that the shielding area of the processing area 36 can be increased or decreased by using a plurality of processing area adjustment plates 24a to 24e. In addition, a plurality of processing area adjustment plates having different shielding areas may be prepared in advance, and a single processing area adjustment plate having a desired shielding area may be attached to the suction rotor 12 in a replaceable manner. Good.

  Further, the shielding mechanism 24 is installed at a position (upstream side) on the upstream side of the processing passage 42 where the processing air passes through the processing area 36 of the suction rotor 12. In this case, the spacing between the shielding mechanism 24 and the suction rotor 12 is preferably as small as possible in a non-contact state.

  Further, when the shielding mechanism 24 shields the processing area 36, a plurality of processing area adjusting plates 24 a to 24 a are arranged along the rotation direction (arrow A direction) of the suction rotor 12 from the side close to the purge area 40 in the processing area 36. By sliding 24e to the open side, the area shielded by the processing area adjustment plates 24a to 24e increases and the area of the processing area 36 decreases (see FIG. 2A). On the other hand, the processing area adjusting plates 24a to 24e are shielded by the processing area adjusting plates 24a to 24e by sliding the plurality of processing area adjusting plates 24a to 24e to the closed side in the direction opposite to the rotation direction of the suction rotor 12 (arrow A direction). And the area of the processing area 36 increases (see FIGS. 2B and 2C).

  In other words, among the plurality of processing area adjustment plates 24a to 24e, by appropriately adjusting the number of processing area adjustment plates 24a to 24e to be slid by the actuator ACT, the area for shielding (blinding) the processing area 36 can be easily changed. can do.

  Further, the shielding mechanism 24 is not limited to a fan shape, and for example, a manifold (branch pipe) (not shown) in which a plurality of processing passages 42 are branched at a position in front of the suction rotor 12 is arranged. A valve may be provided in each branch passage constituted by the branch pipe, and an arbitrary branch passage may be controlled to open and close by a control signal from the controller 32. In this case, the processing air is supplied to the processing area 36 through the branch passage where the valve is open, and the processing area 36 is shielded by the branch passage where the valve is closed.

  Furthermore, two opening shielding plates (not shown) having one or a plurality of slits are overlapped in front of the suction rotor 12 and the two shielding plates are relatively displaced to increase or decrease the opening area of the slits. It may be. In this case, the processing air is supplied to the processing area 36 through a slit opened by two shielding plates, and the processing area 36 is shielded by a portion other than the opening of the slit.

Next, the effect of the shielding mechanism 24 is demonstrated based on FIG.
FIG. 3A is an explanatory diagram showing an example of the maximum area where the area of the processing area of the suction rotor is maximized, and FIG. 3B is an explanation showing an example of the minimum area where the area of the processing area of the suction rotor is minimized. FIG. The maximum area example and the minimum area example differ only in the area of the processing area 36 that is shielded by the processing area adjustment plates 24a to 24e of the shielding mechanism 24, and the other configurations are the same. Further, an arrow A in FIG. 3 indicates the rotation direction of the suction rotor 12. Further, in the maximum area example and the minimum area example, the rotation speed of the suction rotor 12 driven by the motor 20 is set to be the same at the rated rotation speed. For convenience of explanation, in the processing area 36 of the suction rotor 12, a partial processing area 36A (the meshed line portion in FIG. 3) closest to the purge area 40 side is virtually set, and this partial processing area 36A. In the following, it will be assumed that is rotating in the direction of arrow A.

  In the example of the maximum area, as shown in FIG. 3A, the processing area 36 in the suction rotor 12 is set to the area S1 (rated processing area area) at the central angle θ1. In the example of the minimum area, as shown in FIG. 3B, the processing area 36 is set to the area S2 with a central angle θ2 smaller than the central angle θ1 (S1> S2). In this case, when the suction rotor 12 rotates in the arrow A direction at a predetermined rotation speed, the partial processing area 36A closest to the purge area 40 side in the processing area 36 is present in the maximum area example. Stay time is T1.

  In contrast, in the minimum area example, the partial processing area 36A that is closest to the purge area 40 side (shielding mechanism 24 side) has a processing area residence time within the processing area 36 that is shorter than T1. (T1> T2).

  Thus, in the present embodiment, by providing the shielding mechanism 24 and changing the area of the processing area 36 from the maximum to the minimum (S1 → S2), the processing area of the partial processing area 36A closest to the purge area 40 side. The staying time can be shortened (T1 → T2). For example, when the rotation speed of the adsorption rotor 12 is set to be lower than the rated rotation speed and is rotated slowly, in the minimum area example, compared with the case where the adsorption rotor 12 is rotated at the rated rotation speed, moisture saturation in the processing area 36 is achieved. Thus, the water adsorption capacity in the processing area 36 can be sufficiently maintained.

  In other words, when the rotation speed of the adsorption rotor 12 is decreased, in the example of the maximum area in FIG. 3A, the moisture adsorption capacity of the partial processing area 36A is saturated before the partial processing area 36A reaches the regeneration area 38. Thus, the processing air is passed through without being dried, and as a result, a decrease in the dew point of the supply air (dry air) is hindered. That is, the supply air dew point temperature is increased (deteriorated). This tendency becomes remarkable as the rotation speed of the suction rotor 12 becomes low. On the other hand, when the rotation speed of the adsorption rotor 12 is decreased, even if the rotation speed is decreased, the moisture adsorption capability of the partial processing area 36A is maintained in the minimum area example of FIG. be able to. In the present embodiment, the area of the processing area 36 is variable between S1 of the maximum area example and S2 of the minimum area example, but may be fixed.

  Note that the areas shielded by the processing area adjusting plates 24a to 24e of the shielding mechanism 24 are always kept in a high dryness state (dry state) because the passage of the processing air to the suction rotor 12 is blocked. Has been. Therefore, for example, when the supply air amount changes from the low amount state to the increase state, the actuator ACT is energized to displace the processing area adjustment plates 24a to 24e to the closed side (the direction opposite to the rotation direction of the arrow A). In addition, by minimizing the shielding area by the shielding mechanism 24 (see FIG. 2B), it is possible to suppress an increase in the supply air dew point temperature. Incidentally, when the rotation speed of the adsorption rotor 12 is decreased, the regeneration capability of the regeneration area 38 is increased, and the dehumidifying material of the adsorption rotor 12 can be sufficiently regenerated in the regeneration area 38.

  The dehumidifying device 10 according to the embodiment of the present invention is basically configured as described above. Next, the operation and effects thereof will be described.

First, based on FIG. 1, the flow of air in the dehumidifier 10 will be schematically described.
The outside air (OA) introduced from the outside flows along the processing passage 42, passes through the cooling coil 22a, is pre-dehumidified, and then is introduced into the processing area 36 of the suction rotor 12 that is not shielded by the shielding mechanism 24. Is done. In the processing area 36, dry air is generated in which moisture in the air is adsorbed and removed by a dehumidifying material (for example, silica gel, zeolite, etc.) held by the adsorption rotor 12. The dry air that has passed through the processing area 36 is supplied to an air-conditioned room (not shown) as supply air (SA) having a low dew point. In this way, by supplying a predetermined amount of supply air (dry air) to the air-conditioned room (not shown) corresponding to the preset supply air dew point temperature, the environment of the air-conditioned room is reduced to a desired dew point temperature and low humidity. Can be

  At the same time, the regeneration air introduced through the regeneration passage 44 branched from the middle of the processing passage 42 passes through the purge area 40 and is then heated to a predetermined temperature by the heater 18. The regeneration air heated to the predetermined temperature can desorb the moisture adsorbed by passing through the regeneration area 38 from the adsorption rotor 12 and restore the adsorption capability of the adsorption rotor 12. The regeneration air that has passed through the regeneration area 38 is exhausted into the atmosphere as exhaust air (EA).

  By the way, conventionally, the design of the dehumidifying apparatus 10 determines the target supply air amount based on the dew point temperature required in the air-conditioned room (dry room) and the humidity load due to the number of people in the air-conditioned room, The regeneration air amount is determined so that the supply air dew point temperature is satisfied even under summer conditions when the humidity of the outside air introduced into the dehumidifier 10 is the highest. Further, a system has been proposed in which low-humidity air in an air-conditioned room is reused in another air-conditioned room, thereby reducing the amount of air supplied to the dehumidifier 10 and saving energy.

  In this regard, for example, Japanese Patent Application Laid-Open No. 2003-24737 discloses a capacity (heat generation amount) of a heater that detects the air temperature at the regeneration outlet and heats the regeneration air so that the air temperature at the regeneration outlet becomes constant. Is disclosed. According to Japanese Patent Laid-Open No. 2003-24737, it is performed only by controlling the temperature of the regeneration air, and energy saving can be realized by keeping the amount of regeneration air constant.

  However, since the dew point temperature on the outlet side of the processing air is affected by the temperature of the regeneration air, the dew point temperature on the outlet side of the predetermined processing air (the supply air measured by the dew point sensor 30 in this embodiment) In order to maintain the dew point temperature) at a predetermined value, the temperature of the regeneration air may not be lowered. In particular, when the dew point temperature on the outlet side of the processing air is a low dew point temperature, there is a problem that it is difficult to lower the temperature of the regeneration air, and the energy saving effect is reduced.

  In other words, when the dew point temperature on the outlet side of the processing air is a low dew point temperature (when the required dew point is severe), it is difficult to desorb moisture from the adsorption rotor 12 if the temperature of the regeneration air is further reduced. Because it becomes. That is, when the temperature of the regeneration air is lowered, it becomes difficult to sufficiently regenerate the dehumidifying material of the adsorption rotor 12 in the regeneration area 38, and the amount of heat generated by the heater 18 must be increased, so the energy saving effect is reduced. End up.

  Therefore, in the present embodiment, the processing area adjustment plates 24a to 24e of the shielding mechanism 24 shield a part of the processing area 36 of the suction rotor 12 to reduce the area of the processing area 36 through which the processing air passes, and the suction rotor. The rotational speed of 12 is reduced below the rated rotational speed, and the amount of regeneration air is reduced. Thus, in the present embodiment, avoidance of moisture saturation of the dehumidifying material in the processing area 36, sufficient regeneration of the dehumidifying material in the regeneration area 38, and further energy saving are achieved. A control method of the dehumidifying device 10 in this regard will be described based on the flowchart shown in FIG.

FIG. 4 is a flowchart showing a control method of the dehumidifying apparatus according to the embodiment of the present invention.
In step S 1, various data are input to the controller 32. The various data are detected values output from various sensors, and the dry bulb temperature (T) and relative humidity (RH) of the processing air at the position (upstream side) before the adsorption rotor 12 detected by the temperature / humidity sensor 26. The supply air dew point temperature (DP _SA ) of the supply air (dry air) detected by the dew point sensor 30, the pressure of the primary processing air detected by the differential pressure gauge 28, and the secondary processing air (supply air) Differential pressure (ΔP) with the pressure of air). Note that the controller 32 calculates a measured supply air amount (Q _SA ) based on the differential pressure (ΔP) from the differential pressure gauge 28. As described above, the target air supply air amount is set based on the dew point temperature required in the air-conditioned room (dry room) and the humidity load due to the number of people in the air-conditioned room. It is assumed that the actually measured supply air amount (Q _SA ) is controlled so as to match the target supply air amount by feedback control or the like.

In addition, the operator inputs the set value (DP _SET ) of the supply air dew point temperature and the rated operation state of the dehumidifier 10 to the controller 32. The setting of the rated operation state is, for example, the passage speed of the processing air passing through the processing area 36, the area of the processing area 36, the angle (θ) of the central angle of the processing area 36, the passing time of the processing area 36, etc. It is performed by inputting each.

In step S2, the controller 32 calculates the opening degree (θ: angle of the central angle) of the processing area adjustment plates 24a to 24e based on the supply air amount (Q _SA ) obtained in step S1, and the processing area adjustment plate. The opening degree (theta) of 24a-24e is set. Specifically, the required area of the processing area 36 is calculated from the supply air amount (Q _SA ) and the passing surface speed of the processing air passing through the processing area 36, and based on this, the processing area adjustment plates 24 a to 24 e are calculated. The area that can be shielded is calculated, and the opening degree θ of the processing area adjusting plates 24a to 24e is set.

In step S3, the controller 32 calculates the rotational speed (V) of the suction rotor 12 based on the supply air amount (Q _SA ) obtained in step S1, and sets the rotational speed (V) of the suction rotor 12. To do. Specifically, the rotation speed (V) of the suction rotor 12 is set so as to reach a predetermined processing area stay time T from the central angle (θ) of the processing area 36.

Subsequently, in step S4, the controller 32 determines whether or not the supply air dew point temperature (DP _SA ) detected by the dew point sensor 30 is lower than the set value (DP _SET ) of the supply air dew point temperature set in advance in step S1. Determine whether.

When the controller 32 determines that the supply air dew point temperature (DP _SA ) is higher than the set value (DP _SET ) of the supply air dew point temperature (step S4 → No), since the supply air is in a wet state, the inverter 16b A control signal is output to control the amount of regeneration air from the regeneration fan 16a to the maximum value (step S5).

On the other hand, when the controller 32 determines that the supply air dew point temperature (DP _SA ) is lower than the set value (DP _SET ) of the supply air dew point temperature (step S4 → Yes), the supply air is in a dry state. Proceed to step S6. In step S6, the controller 32 calculates the absolute humidity x at the position in front of the suction rotor 12 based on the dry bulb temperature (T) and the relative humidity (RH) of the processing air detected by the temperature / humidity sensor 26, and Based on the differential pressure (ΔP) by the differential pressure gauge 28 and the dry bulb temperature (T), an air supply air amount (Q _SA ) is calculated.

Subsequently, in step S7, the controller 32 determines the absolute humidity x and the supply air amount (Q _SA ) at the position before the adsorption rotor 12 obtained in step S6, and the supply air dew point temperature set in step S1. Based on the set value, the regeneration air amount (Q _h ) is calculated. Note that the regeneration air amount (Q _h ) may be determined based on a database in which relational ratios between the supply air amount (Q _SA ) and the regeneration air amount (Q _h ) are accumulated. In step S8, the controller 32 controls the regeneration fan 16a based on the regeneration air amount (Q _h ) obtained in step S7. Note that the data stored in the database is obtained in advance through experiments or simulations, for example.

  In step S9, the controller 32 outputs a control signal composed of the rotation speed (V) of the suction rotor 12 to the driver of the motor 20, for example, decelerates the rotation speed of the motor 20 compared to the rated operation state. That is, the rotational speed of the motor 20 is controlled so that the suction rotor 12 rotates slowly as compared with the rated operation state.

  Further, in step S9, the controller 32 outputs a control signal composed of the opening degrees (θ) of the processing area adjustment plates 24a to 24e to the actuator ACT, and slides the processing area adjustment plates 24a to 24e by driving the actuator ACT. And set to a predetermined opening (center angle; θ).

Further, in step S9, the controller 32 outputs a control signal composed of the regeneration air amount (Q _h ) to the inverter 16b, and compares the regeneration air amount (Q _h ) from the regeneration fan 16a with, for example, a rated operation state. Control to decrease.

As described above, in the present embodiment, the processing area adjustment plates 24a to 24e of the shielding mechanism 24 are slid based on the supply air amount (Q _SA ) and the absolute humidity x at the position in front of the suction rotor 12, thereby processing areas. 36, the rotation speed (V) of the suction rotor 12 is decreased in response to the decrease in the area (S) of the processing area 36, and the amount of regeneration air (Q _h ) is decreased. I am letting. As a result, in the present embodiment, the amount of regeneration air (Q _h ) can be reduced as compared with the rated operation state, and energy saving can be achieved.

In the present embodiment, the controller sets the supply air amount (Q _SA ), the absolute humidity x at the position in front of the suction rotor 12 detected by the temperature / humidity sensor 26, and the preset supply air dew point temperature. The regeneration air amount (Q _h ) can be calculated based on the value (DP _SET ), and the regeneration air amount (Q _h ) can be controlled based on the calculation result. Accordingly, the secondary side supply air dew point temperature (DP _SA ) detected by the dew point sensor 30 is stabilized even when the regeneration air amount (Q _h ) is changed without performing complicated control. Can do.

Furthermore, in the present embodiment, the moisture in the processing area 36 is provided by changing the area of the processing area 36 and providing the shielding mechanism 24 that increases or decreases the area of the processing area 36 in accordance with the supply air amount (Q _SA ). A saturation state can be avoided and the supply side dew point temperature (DP _SA ) on the secondary side can be stabilized.

Furthermore, in the present embodiment, the rotational speed (V), the regeneration air amount (Q _h ), and the processing area area (S) of the suction rotor 12 corresponding to the supply air amount (Q _SA ) and the absolute humidity x. Can be optimally controlled. As a result, it is possible to reduce the amount of regenerated air (Q _h ) and achieve energy saving.

Furthermore, in the present embodiment, the area (S) of the processing area 36 is set so that the processing area passage surface speed becomes a predetermined value based on the supply air amount (Q _SA ), and the set processing is performed. By setting the adsorption rotor 12 to a predetermined rotational speed (V) corresponding to the area area (S), the secondary side supply air dew point temperature (DP _SA ) in the rated operation state can be stabilized.

Furthermore, in the present embodiment, the processing air passing through the processing area 36 is shielded by the predetermined area adjusting plates 24a to 24e of the shielding mechanism 24 arranged on the upstream side of the processing area 36. Processing air does not pass through the suction rotor 12. Therefore, the part shielded by the shielding mechanism 24 (predetermined area adjusting plates 24a to 24e) is always kept in a high dry state. For this reason, for example, when the supply of the supply air amount (Q _SA ) is switched from the low amount state to the increase state, the processing air passes through a portion with a high degree of dryness shielded by the shielding mechanism 24, thereby supplying the air. An increase in the air dew point temperature (DP _SA ) can be suppressed.

Furthermore, in the present embodiment, the portion of the processing area 36 that is close to the purge area 40 side of the adsorption rotor 12 is held in the most dry state in the processing area 36. When the supply of (Q _SA ) is switched from the low amount state to the increased amount state, the shield region is decreased by displacing the suction rotor 12 in the direction opposite to the rotation direction A, thereby reducing the supply dew point temperature (DP _SA ). The rise can be suppressed.

Furthermore, in the present embodiment, the area (S) of the processing area 36 is reduced by the shielding mechanism 24 (predetermined area adjusting plates 24a to 24e) in accordance with the amount of supplied air (Q _SA ) supplied to the secondary side. It can be increased or decreased. In this case, the portion of the processing area 36 that is close to the purge area 40 side of the suction rotor 12 is held in the most dry state in the processing area 36. For example, the amount of supplied air (Q _SA ) When the supply is switched from the low amount state to the increased amount state, the increase in the supply air dew point temperature (DP _SA ) is suppressed by reducing the shielding area in the processing area 36, and the secondary side supply air dew point temperature (DP _SA ) can be stabilized.

Incidentally, the feedback control or the like, air supply because they are to match the air quantity, the target supply air of the air supply air amount (Q _SA) in the control of the supply air amount (Q _SA) becomes the target It can be controlled by replacing it with the amount of air.

In the above embodiment, the area of the processing area 36 is variable, but may be fixed. That is, by controlling the rotation speed (V) of the suction rotor 12 and the regeneration air amount (Q _h ), the dew point of the supply air (dry air) can be appropriately controlled. Further, the dew point of the supply air (dry air) can be appropriately controlled by fixing the rotation speed of the adsorption rotor 12 and the amount of regenerated air and changing the area of the processing area 36.

DESCRIPTION OF SYMBOLS 10 Dehumidifier 12 Adsorption rotor 18 Heater 20 Motor (rotation drive means)
24 Shielding mechanism (processing area area control means)
24a-24e Processing area adjustment plate 26 Temperature / humidity sensor (humidity detection means)
28 Differential pressure gauge (Supply air amount detection means)
32 controller (supply air amount detection means, rotation speed control means, regeneration air amount control means)
36 Processing area 38 Regeneration area 40 Purge area ACT Actuator

Claims (6)

An adsorption rotor that is divided into a plurality of areas including a processing area, a regeneration area, and a purge area, and that adsorbs moisture in the processing air, and a heater that heats the regeneration air for desorbing moisture adsorbed on the adsorption rotor And a dehumidifying device having rotation driving means for rotating the suction rotor,
Supply air amount detection means for detecting the amount of supply air supplied to the secondary side;
Humidity detecting means for detecting the absolute humidity of the processing air at a position before passing through the processing area of the suction rotor;
Rotation speed control means for controlling the rotation speed of the adsorption rotor rotated by the rotation drive means;
Based on the absolute humidity of the processing air detected by the humidity detection means, the supply air amount detected by the supply air amount detection means, and a preset value of the supply air dew point temperature A regeneration air amount control means for calculating an amount and controlling the regeneration air amount based on the calculation result;
Equipped with a,
A processing area area control means that is disposed at a position before the processing air passes through the suction rotor, makes the area of the processing area variable, and increases or decreases the area of the processing area in accordance with the amount of supplied air. Further comprising
The processing area area control means comprises a shielding mechanism that is arranged upstream of the processing area and shields processing air passing through the processing area, and the area of the processing area is increased or decreased by changing the area that shields the processing area. set dehumidifier characterized Rukoto. Based on the supply air amount detected by the supply air amount detection means and the absolute humidity detected by the humidity detection means,
The rotation speed of the suction rotor by the rotation speed control unit, the regeneration air amount by the regeneration air amount control unit, and the area of the processing area by the processing area area control unit are respectively set. claim 1 Symbol placement dehumidifier. In the processing area, the area of the processing area is decreased by displacing from the purge area side in the rotation direction of the suction rotor to increase the shielding area, while being displaced in the direction opposite to the rotation direction of the suction rotor. dehumidifying device according to claim 1, wherein the area of the processing area is increased by reducing the shielding area Te. An adsorption rotor that is divided into a plurality of areas including a processing area, a regeneration area, and a purge area, and that adsorbs moisture in the processing air, and a heater that heats the regeneration air for desorbing moisture adsorbed on the adsorption rotor And a dehumidifying device having rotation driving means for rotating the suction rotor,
The processing air is disposed at a position before passing through the suction rotor, and includes processing area area control means for changing the area of the processing area by shielding a part of the processing area of the suction rotor,
The dehumidifying apparatus, wherein the processing area area control means increases or decreases the area of the processing area in accordance with the amount of supplied air supplied to the secondary side. An adsorption rotor that is divided into a plurality of areas including a processing area, a regeneration area, and a purge area, and that adsorbs moisture in the processing air, and a heater that heats the regeneration air for desorbing moisture adsorbed on the adsorption rotor And a control method of the dehumidifying device having a rotation driving means for rotating the suction rotor,
Supply to the secondary side determined based on the absolute humidity of the processing air at a position before passing through the processing area of the suction rotor and the pressure difference between the primary side air and the secondary side air of the suction rotor. Calculating the regeneration air amount based on the air air amount and a preset value of the supply air dew point temperature, and controlling the regeneration air amount based on the calculation result;
Calculating the rotation speed of the adsorption rotor based on the amount of supplied air, and controlling the rotation speed of the adsorption rotor based on the calculation result;
Making the area of the processing area variable, and increasing or decreasing the area of the processing area corresponding to the amount of supplied air;
Have
The method of controlling a dehumidifying apparatus , wherein the area of the processing area is set by increasing / decreasing a region that shields the processing air passing through the processing area . An adsorption rotor that is divided into a plurality of areas including a processing area, a regeneration area, and a purge area, and that adsorbs moisture in the processing air, and a heater that heats the regeneration air for desorbing moisture adsorbed on the adsorption rotor And a control method of the dehumidifying device having a rotation driving means for rotating the suction rotor,
Calculate the area of the processing area required based on the amount of air supplied to the secondary side obtained from the differential pressure between the primary side air before passing through the adsorption rotor and the secondary side air after passing through,
A method of controlling a dehumidifying device, wherein a part of the processing area is shielded based on the calculation result.

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