JP4769917B2 - Dehumidification drying system - Google Patents

Description

  The present invention relates to a dehumidifying and drying system for dehumidifying and drying dried products such as farm products and processed foods such as straw, wheat, and soybeans disposed in a greenhouse.

  If the moist rice is left standing or accumulated for a long time, the rice cake becomes burnt rice (fermented rice) due to the action of mold, etc., causing quality degradation. Is.

As an example of an apparatus for performing such a drying process, Patent Document 1 discloses a configuration of a hot air (dry air) type drying apparatus. The drying device of Patent Literature 1 includes an upward-opening substantially box-shaped container for housing a soot, a warmer for heating the outside air to generate hot air, and hot air from the warmer in the container. And a blower unit for forced introduction. In this case, the soot in the container is heated and dried by the hot air sent into the container from the warmer through the blower unit. The warmer is of the type that generates hot air by heating the outside air by burning fossil fuel.
Japanese Utility Model Publication No. 53-152969

  However, in the method of generating hot air by burning fossil fuel as in Patent Document 1, a lot of expensive fossil fuel must be consumed to dry a large amount of soot, which increases running costs and is not effective. There was a problem of economy.

  Moreover, in the drying process using hot air, the drying speed of the koji is extremely fast (the drying time is short), so that the koji is easily dried more than necessary, and the rice taste deteriorates as a result. There was a risk of causing problems. Further, due to the extremely high drying speed of the koji, the difference in moisture between the surface layer and the inside of the koji is likely to increase, and there is a possibility of causing the problem of increased body cracked rice and cracked rice. That is, in the hot air type drying apparatus as in Patent Document 1, it is difficult to maintain the quality and taste of rice bran (rice) in a good state.

  Therefore, the present invention has a technical problem to provide a dehumidifying and drying system that solves the above problems.

  In order to solve this technical problem, the invention of claim 1 is a dehumidifying and drying system for dehumidifying and drying an object to be dried such as agricultural products and processed foods disposed in a greenhouse, by at least A container for containing dry matter, a blower unit for forcibly introducing air in the greenhouse into the container, a ventilation fan for ventilating the greenhouse, and atmospheric humidity in the greenhouse And a control means for controlling the operation of the ventilation fan and the blower unit based on the control information of the humidity sensor.

  The invention according to claim 2 is the dehumidification drying system according to claim 1, wherein the control means includes a low humidity mode used when the outside air humidity outside the greenhouse is low and a high humidity mode used when the outside air humidity is high. One of them is selected based on the control information of the humidity sensor, and when the atmospheric humidity in the greenhouse is higher than the target humidity during the execution of the low humidity mode, the air flow rate of the ventilation fan is increased, When the atmospheric humidity is lower than the target humidity, the ventilation volume of the ventilation fan is reduced. On the other hand, when the atmospheric humidity in the greenhouse is higher than the target humidity during execution of the high humidity mode, the ventilation fan The air flow rate is decreased, and when the atmospheric humidity is lower than the target humidity, control is performed to increase the air flow rate of the ventilation fan.

  According to a third aspect of the present invention, in the dehumidifying and drying system according to the second aspect of the present invention, the dehumidifying and drying system includes a drying unit for drying the air in the greenhouse, and the control unit includes When the atmospheric humidity of the greenhouse is higher than the target humidity and the ventilation fan has reached a predetermined large volume of ventilation, the atmospheric humidity in the greenhouse is lower than the target humidity and the ventilation fan is running during the high humidity mode. When the amount of blast air reaches a predetermined small amount of blast air, the drying means is controlled to operate.

  The invention according to claim 4 is the dehumidifying and drying system according to claim 2 or 3, wherein a temperature sensor for detecting an atmospheric temperature in the greenhouse and a memory in which the target humidity corresponding to the atmospheric temperature is stored in advance. And the control means performs control so as to acquire the appropriate target humidity from the storage means based on the control information of the temperature sensor.

  A fifth aspect of the present invention is the dehumidifying and drying system according to any one of the first to fourth aspects, wherein the container and the blower unit are configured to be removable from the greenhouse.

  According to the invention of claim 1, at least a container for storing the material to be dried, a blower unit for forcibly introducing air in the greenhouse into the container, and ventilation for the greenhouse Since it comprises a ventilation fan, a humidity sensor for detecting the atmospheric humidity in the greenhouse, and a control means for controlling the operation of the ventilation fan and the blower unit based on the control information of the humidity sensor, By effectively using the humidity of the outside air taken into the greenhouse by driving a ventilation fan, the object to be dried in the container can be dried (adjusted to an appropriate amount of water). Compared to the above, wasteful fuel consumption can be effectively prevented. For this reason, in the whole dehumidification drying system, a running cost is suppressed and there exists an effect that it is very economical.

  According to the configuration of claim 2, during the execution of the low humidity mode when the outside air humidity outside the greenhouse is low, if the atmospheric humidity in the greenhouse is higher than the target humidity, the air blowing amount of the ventilation fan increases, When the atmospheric humidity is lower than the target humidity, the ventilation volume of the ventilation fan is reduced. On the other hand, when the atmospheric humidity in the greenhouse is higher than the target humidity during execution of the high humidity mode when the outside air humidity is high. When the ventilation amount of the ventilation fan decreases and the atmospheric humidity is lower than the target humidity, the ventilation amount of the ventilation fan increases.

  In this way, the amount of outside air introduced by the ventilation fan per unit time can be changed and adjusted according to the humidity condition of the outside air and the target moisture content of the soot, so dehumidification drying control of the object to be dried using outside air can be performed. The effect is that it can be executed efficiently and appropriately.

  According to the configuration of claim 3, when the atmospheric humidity in the greenhouse is higher than the target humidity and the ventilation fan reaches a predetermined large volume during the execution of the low humidity mode, When the atmospheric humidity in the greenhouse is lower than the target humidity during execution and the ventilation amount of the ventilation fan reaches a predetermined small amount of ventilation, a drying means for drying the air in the greenhouse is activated. Therefore, there is an effect that it is possible to efficiently dry the object to be dried without reducing the drying performance while suppressing the running cost.

  According to the structure of Claim 4, based on the control information of the temperature sensor for detecting the atmospheric temperature in the said greenhouse, the said target humidity appropriate from the memory | storage means which memorize | stored previously the said target humidity corresponding to the said atmospheric temperature Therefore, if the data on the target humidity relating to the grain to be dried is stored in the storage means, it is possible to efficiently and smoothly execute the dehumidifying and drying control for various grains.

  According to the structure of Claim 5, since the said container and the said ventilation unit are the structures which can be removed from the inside of the greenhouse, if these are removed from the inside of the greenhouse at the time of non-use, the greenhouse will be raised by raising seedlings or horticulture It can be used for various applications. Therefore, the greenhouse can be used for the entire year, and the range of use is expanded.

  DESCRIPTION OF EMBODIMENTS Embodiments embodying the present invention will be described below with reference to the drawings (FIGS. 1 to 7). 1 is a schematic plan view of a greenhouse, FIG. 2 is a partially cutaway perspective view of a container, FIG. 3 is a functional block diagram of a controller, FIG. 4 is a flowchart of dehumidification drying control, and FIG. 5 is a flowchart showing a mode of low humidity mode control. FIG. 6 is a flowchart showing an aspect of high humidity mode control, and FIG. 7 is a flowchart showing an aspect of high temperature prevention control.

  As shown in FIG. 1, the greenhouse 1 of the present embodiment has a framework composed of a large number of columns and frames. A plurality of side windows 2 and doors 3 for entering and exiting are provided on the side wall of the greenhouse 1 so as to be openable and closable. Ventilation fans 4 for ventilating the inside of the greenhouse 1 are attached to two side walls adjacent to the side walls, respectively. An opening / closing shutter 5 is provided on the side wall facing the side wall with the door 3. A plurality of lighting fixtures such as a white lamp and a mercury lamp are arranged on the ceiling side in the greenhouse 1 (not shown). A control panel 6 having a controller 7 (see FIG. 3), which is an example of a control means, is disposed on one side wall of the greenhouse 1 near the door 3.

  The dehumidifying and drying system according to the present embodiment is for dehumidifying and drying a dried product such as farm products and processed foods such as straw, wheat, and soybean, and for storing the dried product as a dried product. Container 8, a blower unit 9 for forcibly introducing air in the greenhouse 1 into the container 8, a dehumidifier 10 for dehumidifying the air in the greenhouse 1, and warming the air in the greenhouse 1 , A pair of ventilation fans 4 described above, an IC-type temperature sensor 12 (see FIG. 3) for detecting the ambient temperature in the greenhouse 1, and the ambient humidity in the greenhouse 1 are detected. For example, an impedance change type humidity sensor 13 (see FIG. 3) and a controller 7 (see FIG. 3) in the control panel 6 are provided. The dehumidifier 10 and the warmer 11 correspond to the drying means described in the claims. Note that any one of the dehumidifier 10 and the warmer 11 may be used as the drying means.

  As shown in FIG. 1, a plurality of rows of rails 14 are laid on the floor surface of the greenhouse 1 so as to be arranged in parallel at appropriate intervals in a direction intersecting the longitudinal direction in plan view. A plurality of containers 8 are placed on the rails 14 of each set so as to be movable along the longitudinal direction of the rails 14 (in this embodiment, one set of rails 14). 5 per one).

  The container 8 is formed in a substantially box shape with an upward opening. As shown in FIG. 2, a fine mesh-like ventilation floor plate 15 is stretched inside the container 8, and the presence of the ventilation floor plate 15 makes the inside of the container 8 beside the upper jar storage chamber 16 and the lower side. And an air chamber chamber 17. Therefore, the bag storage chamber 16 and the air chamber chamber 17 communicate with each other through the mesh of the ventilation floor plate 15.

  In this embodiment, the harvested straw is directly put into the straw storage chamber 16 without bagging. For this reason, a horizontally long discharge port 18 for discharging the soot in the soot storage chamber 16 is formed at one side lower part of the soot storage chamber 16. The discharge port 18 is closed by an openable cover body 19. An inlet 20 for introducing air into the air chamber 17 from the outside is formed on one side wall of the air chamber 17.

  The bottom surface of the container 8 is provided with a pair of claw insertion portions 21 for inserting a fork claw (not shown) of a forklift and wheels 22 that run on each set of rails 14 in a rollable manner. Yes.

  The blower unit 9 is provided corresponding to each set of rails 14 (one for each set of rails 14), and extends in parallel with the rails 14 to one side of the arrangement direction of each set of rails 14. And a blower fan 24 for sending air into the blower duct 23. The blower fan 24 is provided at one end of the blower duct 23 (a location close to the side wall with the door 3 in FIG. 1). The other end of the air duct 23 is closed.

  Each air duct 23 is provided with a plurality of branch ducts 25 projecting toward the rail 14 in plan view on the side surface on the rail 14 side corresponding to the air duct 23 (in this embodiment, five).

  Although not shown in detail, each branch duct 25 is configured to be extendable and retractable along its protruding direction (a direction intersecting the longitudinal direction of the air duct 23), and urges each branch duct 25 to be in an extended state. An urging means is provided. Further, in the dehumidifying and drying system of this embodiment, when the container 8 approaches and separates from the branch duct 25, the branch duct 25 is shortened so as to move away from the container 8, and the container 8 has its introduction port 20 connected to the branch duct 25. There is a restricting means for allowing the branch duct 25 to extend so as to abut against the container 8 when it is at the facing position opposed to the container 8.

  In this case, when the corner portion of the container 8 moving along each set of rails 14 comes into contact with the branch duct 25 (when it reaches a nearby position), the branch duct 25 resists the biasing force of the biasing means from the container 8. It shortens in the direction to go away and does not prevent the movement of the container 8. When the container 8 that has moved further reaches the facing position, the branch duct 25 is allowed to extend by the urging means, and the leading end of the branch duct 25 is in close contact with the introduction port 20 in the container 8. As a result, the air chamber 17 of the container 8 and the branch duct 25 are connected in communication. If the container 8 is further moved, the container 8 is displaced from the facing position, so that the branch duct 25 is shortened away from the container 8 again.

  Therefore, in this embodiment, the container 8 and the branch duct 25 can be connected in a one-touch manner by simply moving the container 8 along each set of rails 14.

  Note that the air blowing unit 9 itself is also removable from the greenhouse 1 like the container 8.

  The dehumidifier 10 is provided corresponding to each set of rails 14 similarly to the blower unit 9, and is connected to one end of each blower duct 23. The air dehumidified by the dehumidifier 10 is sent into the air chamber chamber 17 of each container 8 through the blower duct 23 and each branch duct 25 by driving the blower fan 24, and is vented from the air chamber chamber 17. It flows through the mesh of the floor plate 15 and into the basket housing chamber 16. And this air distribute | circulates between ridges and is discharged | emitted in the greenhouse 1 again from the upper surface opening of the container 8. FIG.

  On the other hand, unlike the air blower unit 9 and the dehumidifier 10, only one warmer 11 is arranged alone in the greenhouse 1. The air in the greenhouse 1 heated by the warmer 11 is taken into the blower duct 23 via the dehumidifier 10. Note that the dehumidifier 10 and the warmer 11 are also detachable from the greenhouse 1.

  In this embodiment, the temperature sensor 12 and the humidity sensor 13 for detecting the state quantity of cultivation environment, such as temperature and humidity, are attached in each branch duct 25, and these two types of sensors 12 and 13 are control panels. 6 is connected to the input interface of the controller 7 in the controller 6 (see FIG. 3). Note that both the temperature sensor 12 and the humidity sensor 13 may be disposed at appropriate locations in the greenhouse 1.

  The controller 7 in the control panel 6 operates the ventilation fan 4 and the blower unit 9 based on the control information of the temperature sensor 12 and the humidity sensor 13 to execute dehumidification drying control of the soot stored in the container 8. Yes, in addition to the central processing unit 26 (CPU) for executing various arithmetic processes, a read only memory 27 (ROM) for storing control programs and data, and read / write at any time for temporarily storing control programs and data A memory 28 (RAM), a clock as a timer function, an input / output interface for exchanging data (control information) with a sensor, an actuator, and the like are provided (see FIG. 3).

  In the ROM 27 of the controller 7, a relational expression indicating the relationship between the atmospheric temperature T (air blowing temperature, unit: K) of the air supplied to the container 8 and the target atmospheric humidity h (target humidity, unit:%) or A control map is stored in advance. The ROM 27 of the present embodiment corresponds to the storage means described in the claims.

  In this embodiment, when a substance is left in an atmosphere of a constant temperature / humidity condition, the moisture content of the substance becomes a constant value corresponding to the temperature / humidity condition described above. A relational expression based on the -Clayton expression is created.

As a relational expression in this case,
h = exp {−f1 · T ^g1 · exp (−f2 · T ^g2 · M)}
Is adopted. Here, all of f1, f2, g1, and g2 are parameters according to the type of grain, and are obtained by experiments or the like. M is the equilibrium water content of the grain (target water content, unit:%).

  In addition, you may make it memorize | store the data of a pair of the ventilation temperature T and the target humidity h in ROM27 of the controller 7 as a table map.

  In addition to the two types of sensors 12 and 13 described above, the input interface 29 of the controller 7 is connected to an input unit 29 having a main switch, a keyboard and the like for turning on and off the entire dehumidifying and drying system, an alarm buzzer 30 and the like. ing. The input unit 29 and the alarm buzzer 30 are provided on the control panel 6.

  In addition, a pair of ventilation fans 4, a pair of blower fans 24, a dehumidifier 10 and a single warmer 11 are connected to the output interface.

  Next, an example of dehumidifying and drying control by the controller will be described with reference to the flowcharts shown in FIGS. Here, the equilibrium water content M (target water content) of the soot in the container 8 and data related to the set time TM0 described later are stored in the ROM 27, or the RAM 28 of the controller 7 is operated by a setting device (not shown). Or set it in advance.

  First, following the start of the dehumidifying and drying control shown in FIG. 4, the blower fan 24 of each blower unit 9 is rotationally driven (step S1). Next, both of the ventilation fans 4 are driven to rotate at a maximum drive frequency (corresponding to the maximum air flow) for an appropriate time (step S2), and then the measured humidity H1 obtained from the detection information (control information) of the humidity sensor 13 is used. Is read (step S3). In this embodiment, the ventilation fan 4 has a maximum drive frequency of 60 Hz and a drive time of 5 minutes. Moreover, since there are five humidity sensors 13 in each air duct 23, the average value of the measured humidity at each humidity sensor 13 is adopted as the measured humidity H1.

  Then, both of the ventilation fans 4 are rotated at a minimum drive frequency (corresponding to the minimum air flow) for an appropriate time (step S4), and then the measured humidity H2 obtained from the detection information (control information) of the humidity sensor 13 is used. Is read (step S5). In this embodiment, the minimum drive frequency of the ventilation fan 4 is set to 30 Hz, and the drive time is set to 5 minutes. Also in this case, the average value of the measured humidity at each humidity sensor 13 is used as the measured humidity H2.

  Next, it is determined whether or not the measured humidity H1 when the ventilation fan 4 is rotationally driven at the maximum drive frequency is smaller than the measured humidity H2 when the ventilation fan 4 is rotationally driven at the minimum drive frequency (step S6).

  The case where the measured humidity H1 at the maximum drive frequency is smaller than the measured humidity H2 at the minimum drive frequency is when the humidity of the outside air taken into the greenhouse 1 by driving the ventilation fan 4 is low (for example, in winter). Conversely, the case where the measured humidity H1 at the maximum drive frequency is greater than or equal to the measured humidity H2 at the minimum drive frequency means that the humidity of the outside air is high (for example, the rainy season, summer season, etc.) ing.

  Therefore, when it is determined that the measured humidity H1 at the maximum drive frequency is smaller than the measured humidity H2 at the minimum drive frequency (S6: YES), the drive rotation speed of the ventilation fan 4 is a medium value (45 Hz in this embodiment). ) (Step S7), the low humidity mode control is executed (step S8).

  On the other hand, when it is determined that the measured humidity H1 at the maximum drive frequency is greater than or equal to the measured humidity H2 at the minimum drive frequency (S6: NO), the drive rotational speed of the ventilation fan 4 is set to a medium value (in this embodiment, After changing to 45 Hz) (step S9), the high humidity mode control is executed (step S10).

  During the execution of the low-humidity mode control or the high-humidity mode control, or after one cycle of these controls is completed, the measurement time TM1 counted from the start of the rotational driving of the blower fan 24 by the clock built in the controller 7 It is determined whether or not the set time TM0 has passed (step S11). The set time TM0 of this embodiment is set to 4 hours.

  When it is determined that the measurement time TM1 is less than the set time TM0 (S11: NO), the process returns to step S11 again to wait as it is. When it is determined that the measurement time TM1 is equal to or longer than the set time TM0 (S11: YES), the process returns to step S1 to resume execution of the dehumidifying and drying control. That is, during the execution of the dehumidifying and drying control, the low humidity mode control or the high humidity mode control is selected every time the set time TM0 elapses.

  The low-humidity mode control in step S8 is executed by the procedure shown in FIG. 5, for example. That is, first, the blowing temperature T obtained from the detection information (control information) of the temperature sensor 12, the blowing humidity H obtained from the detection information of the humidity sensor 13, and the target equilibrium moisture M of the soot are read. Step S12). As with the humidity sensor 13, there are five temperature sensors 12 for each air duct 23, and therefore, as the air temperature T, the average value of the temperature measured by each temperature sensor 12 is used. The ventilation humidity H is also the average value of the measured humidity at each humidity sensor 13. During the execution of the low-humidity mode control, this reading is set to be performed at intervals of 2 minutes.

  Next, a target atmospheric humidity h (target humidity) is obtained from the blowing temperature T read in step S12, the equilibrium moisture M of the soot, and the relational expression or control map stored in advance in the ROM 27 of the controller 7 ( Step S13).

  Next, it is determined whether or not the value obtained by subtracting the target humidity h from the air blowing humidity H read in step S12 is 2% or more (step S14).

  When it is determined that the value obtained by subtracting the target humidity h from the blast humidity H is 2% or more (S14: YES), since the blast humidity H is still high and the moisture content of the soot in the container 8 is large, Next, it is determined whether or not the current drive frequency of the ventilation fan 4 is the maximum drive frequency (60 Hz) (step S15).

  When it is determined that the current drive frequency of the ventilation fan 4 is not the maximum drive frequency (S15: NO), the drive frequency of the ventilation fan 4 is appropriately increased (step S16), and the unit air per unit time of low humidity is low. After increasing the introduction amount, the process returns to step S12. If the ventilation fan 4 is stopped in step S16, the ventilation fan 4 is rotationally driven at the minimum drive frequency (30 Hz). In this embodiment, the increase width of the drive frequency of the ventilation fan 4 is set to 5 Hz.

  When it is determined that the current drive frequency of the ventilation fan 4 is the maximum drive frequency (S15: YES), the introduction amount per unit time of low-humidity outside air cannot be increased any more, and then the dehumidifier 10 is driven. It is determined whether or not it is in the middle (step S17).

  When it is determined that the dehumidifier 10 is stopped (S17: NO), after the dehumidifier 10 is driven (step S18), the drive rotation speed of the ventilation fan 4 is changed to a medium value (45 Hz). (Step S19), the process returns to step S12.

  When it is determined that the dehumidifier 10 is being driven (S17: YES), it is then determined whether or not the warmer 11 is being driven (step S20).

  When it is determined that the warming machine 11 is stopped (S20: NO), after driving the warming machine 11 (step S21), the drive rotation speed of the ventilation fan 4 is set to a medium value (45 Hz). Change (step S22) and return to step S12.

  When it is determined that the warmer 11 is being driven (S20: YES), since both the dehumidifier 10 and the warmer 11 are being driven, the alarm buzzer 30 is set to alert the operator. It rings (step S23) and returns to step S12. The ringing of the alarm buzzer 30 is set to continue until at least one of the dehumidifier 10 and the warmer 11 stops.

  Returning to step S14, when it is determined that the value obtained by subtracting the target humidity h from the blowing humidity H is less than 2% (S14: NO), then, the value obtained by subtracting the blowing humidity from the target humidity h is 2% or more. It is determined whether or not there is (step S24).

  When it is determined that the value obtained by subtracting the blowing humidity H from the target humidity h is less than 2% (S24: NO), the blowing humidity H is a value close to the target humidity h, but the moisture content of the soot in the container 8 In order to ensure that the water content settles below the equilibrium moisture M, the process returns to step S12 to continue the low-humidity mode control.

  When it is determined that the value obtained by subtracting the blowing humidity H from the target humidity h is 2% or more (S24: YES), the blowing humidity H is lower than the target humidity h and the moisture content of the soot in the container 8 is the equilibrium moisture M. Then, it is determined whether or not the current drive frequency of the ventilation fan 4 is the minimum drive frequency (30 Hz) (step S25).

  When it is determined that the current driving frequency of the ventilation fan 4 is not the minimum driving frequency (S25: NO), the driving frequency of the ventilation fan 4 is appropriately lowered (step S26), and the unit air per unit time of the low humidity is low. After reducing the introduction amount, the process returns to step S12. In this embodiment, the descending width of the drive frequency of the ventilation fan 4 is also set to 5 Hz.

  When it is determined that the current drive frequency of the ventilation fan 4 is the minimum drive frequency (S25: YES), the introduction amount per unit time of low humidity outside air cannot be reduced any more. It is determined whether or not the vehicle is stopped (step S27).

  When it is determined that the warmer 11 is being driven (S27: NO), the warmer 11 is stopped (step S28), and then the drive rotation speed of the ventilation fan 4 is set to a medium value (45 Hz). Change it (step S29) and return to step S12.

  When it is determined that the warmer 11 is stopped (S27: YES), it is then determined whether or not the dehumidifier 10 is stopped (step S30).

  When it is determined that the dehumidifier 10 is being driven (S30: NO), the dehumidifier 10 is stopped (step S31), and then the drive rotational speed of the ventilation fan 4 is changed to a medium value (45 Hz). (Step S32), the process returns to step S12.

  When it is determined that the dehumidifier 10 is stopped (S30: YES), the alarm buzzer 30 is then sounded to alert the operator (step S33), and then the ventilation fan 4 and the blower fan 24 are used. Is also stopped (step S34), one cycle of the low-humidity mode control is completed, and the process returns.

  The high humidity mode control in step S10 is executed, for example, according to the procedure shown in FIG. That is, first, the blowing temperature T obtained from the detection information of the temperature sensor 12, the blowing humidity H obtained from the detection information of the humidity sensor 13, and the target equilibrium moisture M of the soot are read (step S35). As the blowing temperature T, an average value of the measured temperatures by the five temperature sensors 12 is used. The ventilation humidity H is also the average value of the measured humidity at each humidity sensor 13. Even during execution of the high humidity mode control, this reading is set to be performed at intervals of 2 minutes.

  Next, the target atmospheric humidity h (target humidity) is obtained from the blowing temperature T read in step S35, the equilibrium water content M of the soot, and the relational expression or control map stored in advance in the ROM 27 of the controller 7 ( Step S36).

  Next, it is determined whether or not the value obtained by subtracting the target humidity h from the ventilation humidity H read in step S35 is 2% or more (step S37).

  When it is determined that the value obtained by subtracting the target humidity h from the blowing humidity H is 2% or more (S37: YES), the blowing humidity H is still high and the amount of moisture in the container 8 is large. Next, it is determined whether or not the current drive frequency of the ventilation fan 4 is the minimum drive frequency (30 Hz) (step S38).

  When it is determined that the current driving frequency of the ventilation fan 4 is not the minimum driving frequency (S38: NO), the driving frequency of the ventilation fan 4 is appropriately lowered (step S39), and the high humidity outside air per unit time is determined. After increasing the introduction amount, the process returns to step S35. If the ventilation fan 4 is stopped in step S39, the ventilation fan 4 is rotationally driven at the maximum drive frequency (60 Hz). In this embodiment, the descending width of the drive frequency of the ventilation fan 4 is set to 5 Hz.

  When it is determined that the current drive frequency of the ventilation fan 4 is the minimum drive frequency (S38: YES), since the introduction amount per unit time of high humidity outside air cannot be reduced any more, the dehumidifier 10 is then driven. It is determined whether or not it is in the middle (step S40).

  When it is determined that the dehumidifier 10 is stopped (S40: NO), after the dehumidifier 10 is driven (step S41), the drive rotation speed of the ventilation fan 4 is changed to a medium value (45 Hz). (Step S42), the process returns to step S34.

  When it is determined that the dehumidifier 10 is being driven (S40: YES), it is then determined whether or not the warmer 11 is being driven (step S43).

  When it is determined that the warming machine 11 is stopped (S43: NO), after driving the warming machine 11 (step S44), the drive rotation speed of the ventilation fan 4 is set to a medium value (45 Hz). Change (step S45) and return to step S34.

  When it is determined that the warmer 11 is being driven (S43: YES), it is then determined whether or not the dehumidifier 10 or the warmer 11 is being driven for an appropriate time (in this embodiment, 10 minutes) or longer. (Step S46). When the dehumidifier 10 or the warmer 11 has not been driven for an appropriate time or longer, the process directly returns to step S35.

  When the dehumidifier 10 or the warmer 11 is driven for an appropriate time or longer, the alarm buzzer 30 is sounded to call the operator's attention (step S47), and the process returns to step S35. The ringing of the alarm buzzer 30 is set to continue until at least one of the dehumidifier 10 and the warmer 11 stops.

  Returning to step S37, when it is determined that the value obtained by subtracting the target humidity h from the blowing humidity H is less than 2% (S37: NO), then, the value obtained by subtracting the blowing humidity from the target humidity h is 2% or more. It is determined whether or not there is (step S48).

  When it is determined that the value obtained by subtracting the ventilation humidity H from the target humidity h is less than 2% (S48: NO), the ventilation humidity H is a value close to the target humidity h, but the moisture content of the soot in the container 8 In order to ensure that the water content settles below the equilibrium moisture M, the process returns to step S35 and the high humidity mode control is continued.

  When it is determined that the value obtained by subtracting the blowing humidity H from the target humidity h is 2% or more (S48: YES), the blowing humidity H is lower than the target humidity h and the moisture content of the soot in the container 8 is the equilibrium moisture M. Next, it is determined whether or not the current drive frequency of the ventilation fan 4 is the maximum drive frequency (60 Hz) (step S49).

  When it is determined that the current drive frequency of the ventilation fan 4 is not the maximum drive frequency (S49: NO), in order to check whether the moisture content of the soot in the container 8 settles below the equilibrium moisture M, ventilation is performed. The drive frequency of the fan 4 is increased as appropriate (step S50), the amount of introduction of high humidity outside air per unit time is increased, and the process returns to step S35. In this embodiment, the increase width of the drive frequency of the ventilation fan 4 is also set to 5 Hz.

  When it is determined that the current drive frequency of the ventilation fan 4 is the minimum drive frequency (S49: YES), the introduction amount per unit time of high humidity outside air cannot be increased any more. It is determined whether or not the vehicle is stopped (step S51).

  When it is determined that the warmer 11 is being driven (S51: NO), the warmer 11 is stopped (step S52), and then the drive rotation speed of the ventilation fan 4 is set to a medium value (45 Hz). Change (step S53) and return to step S35.

  When it is determined that the warmer 11 is stopped (S51: YES), it is then determined whether or not the dehumidifier 10 is stopped (step S54).

  When it is determined that the dehumidifier 10 is being driven (S54: NO), the dehumidifier 10 is stopped (step S55), and then the drive rotation speed of the ventilation fan 4 is changed to a medium value (45 Hz). (Step S56), the process returns to step S35.

  When it is determined that the dehumidifier 10 is stopped (S54: YES), the alarm buzzer 30 is then sounded to alert the operator (step S57), and then the ventilation fan 4 and the blower fan 24 are activated. (Step S58), one cycle of the high humidity mode control is completed, and the process returns.

  According to the above control, by effectively using the humidity of the outside air taken into the greenhouse 1 by driving the ventilation fan 4, the soot in the container 8 can be dried (adjusted to an appropriate amount of water). Compared to the hot air type, wasteful fuel consumption can be effectively prevented. For this reason, running cost is suppressed in the whole dehumidification drying system, and it is very economical. Of course, it goes without saying that the effect of raising the temperature of the internal air by the greenhouse 1 contributes to increasing the efficiency of the drying process of the soot.

  In the present embodiment, when the humidity of the outside air taken into the greenhouse 1 is low (low humidity mode), if the blowing humidity H is higher than the target humidity h, the drive frequency (blowing amount) of the ventilation fan 4 increases, and the blowing humidity H Is lower than the target humidity h, the drive frequency (air flow rate) of the ventilation fan 4 decreases. On the other hand, when the humidity of the outside air is high (high humidity mode), if the ventilation humidity H is higher than the target humidity h, the drive frequency (air flow rate) of the ventilation fan 4 decreases, and if the ventilation humidity H is lower than the target humidity h, The drive frequency (air flow rate) of the ventilation fan 4 increases.

  In this way, the amount of outside air introduced by the ventilation fan 4 per unit time can be changed and adjusted according to the humidity condition of the outside air and the target amount of soot moisture, so that the dehumidifying and drying control of the soot using the outside air is efficiently performed. It can be done properly.

  In addition, as described above, the dehumidification drying control of the cocoon is performed using the humidity of the outside air, so that the cocoon in the container 8 can be dried in a state very close to natural drying, and overdrying, cracked rice, etc. are generated. Can be prevented. For this reason, the quality and taste of rice bran (rice) can be maintained in a good state.

  In addition, when the low humidity mode is executed, the ventilation humidity H is higher than the target humidity h and the driving frequency of the ventilation fan 4 reaches the maximum driving frequency (maximum ventilation volume) (see steps S18 and S22), or the high humidity mode When the ventilation humidity H is lower than the target humidity h during execution and the drive frequency of the ventilation fan 4 reaches the minimum drive frequency (minimum ventilation volume) (see steps S41 and S44), the dehumidifier 10 and the warmer 11 are turned on. Since it is actuated, it is possible to perform an efficient soot drying process without reducing the drying performance while suppressing the running cost.

  Furthermore, in this embodiment, since the appropriate target humidity h can be acquired from the relational expression or control map stored in advance in the ROM 27 of the controller 7 based on the air blowing temperature T obtained from the detection information of the temperature sensor 12, the drying is performed. If the relational expression or control map relating to the grain to be processed is stored in the ROM 27 in advance, the dehumidifying and drying control for various grains can be executed efficiently and smoothly.

  In this embodiment, since the container 8, the blower unit 9, the dehumidifier 10 and the warmer 11 are removable from the greenhouse 1, if they are removed from the greenhouse 1 when not in use, the greenhouse 1 can be used for various purposes such as raising seedlings and horticulture. Therefore, the greenhouse 1 can be used for the entire year, and the range of use can be expanded.

  In this embodiment, during the execution of the dehumidifying and drying control, the high temperature prevention control shown in the flowchart of FIG. 7 is set to be interrupted at appropriate time intervals.

  In this high temperature prevention control, first, it is determined whether or not the blowing temperature T read in step S12 or step S35 is higher than 35 ° C. (step S59). When it is determined that the blowing temperature T is 35 ° C. or less (S59: NO), the process directly returns to step S2 in FIG.

  When it is determined that the air blowing temperature T is higher than 35 ° C. (S59: YES), after the ventilation fan 4 is driven at the maximum driving frequency (60 Hz) (step S60), an alarm buzzer is used to alert the operator. 30 is sounded (step S61). This ringing is set to continue until the air temperature becomes less than 30 ° C. and the process returns to step S2 in FIG.

  Next, it is determined whether or not the warmer 11 is being driven (step S62). When it is determined that the warmer 11 is stopped (S62: NO), the process proceeds to step S64 described later. When it is determined that the warmer 11 is being driven (S62: YES), the warmer 11 is stopped (step S63).

  Next, in step S64, the blowing temperature T obtained from the detection information of the temperature sensor 12 is read again, and then it is determined whether or not the blowing temperature T is less than 30 ° C. (step S65). When it is determined that the blowing temperature T is 30 ° C. or higher (S65: NO), the process returns to step S65 again to stand by. When it is determined that the blowing temperature T is less than 30 ° C. (S65: YES), the high temperature prevention control is terminated and the process returns to step S2 in FIG.

  By such control, the quality and taste of rice bran (rice) can be maintained in a better state, and a high effect can be exhibited in the drying treatment of rice bran.

  The present invention is not limited to the above-described embodiment, and can be embodied in various forms. For example, as the storage means, in addition to the ROM 27, for example, a nonvolatile memory such as an EEPROM that can rewrite the stored contents may be used. In addition, the structure of each part is not limited to embodiment of illustration, A various change is possible in the range which does not deviate from the meaning of this invention.

It is a schematic plan view of a greenhouse. It is a partially cutaway perspective view of a container. It is a functional block diagram of a controller. It is a flowchart of dehumidification drying control. It is a flowchart which shows the aspect of low humidity mode control. It is a flowchart which shows the aspect of high humidity mode control. It is a flowchart which shows the aspect of high temperature prevention control.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Greenhouse 4 Ventilation fan 7 Controller 8 as a control means Container 9 Blower unit 10 Dehumidifier 11 as a drying means 11 Heating machine 12 as a drying means Temperature sensor 13 Humidity sensor 14 Rail 15 Ventilation floor board 16 Acupuncture storage room 17 Air chamber room 20 Inlet 23 Air duct 24 Air fan 25 Branch duct 27 ROM as storage means

Claims (5)

A dehumidifying and drying system that dehumidifies and dries dried items such as farm products and processed foods placed in a greenhouse by blowing air,
At least a container for accommodating the material to be dried, a blower unit for forcibly introducing air in the greenhouse into the container, a ventilation fan for ventilating the greenhouse, and the greenhouse A humidity sensor for detecting the atmospheric humidity of the inside, and a control means for controlling the operation of the ventilation fan and the blower unit based on control information of the humidity sensor,
Dehumidification drying system. The control means selects one of a low humidity mode used when the outside air humidity outside the greenhouse is low and a high humidity mode used when the outside air humidity is high based on control information of the humidity sensor,
During execution of the low-humidity mode, if the atmospheric humidity in the greenhouse is higher than the target humidity, the ventilation rate of the ventilation fan is increased, and if the ambient humidity is lower than the target humidity, the ventilation rate of the ventilation fan While reducing
During execution of the high humidity mode, if the atmospheric humidity in the greenhouse is higher than the target humidity, the air flow rate of the ventilation fan is decreased, and if the atmospheric humidity is lower than the target humidity, the ventilation fan is sent. Control to increase the air volume,
Dehumidification drying system. Further comprising a drying means for drying the air in the greenhouse,
The control means includes a case where the atmospheric humidity in the greenhouse is higher than a target humidity during the execution of the low-humidity mode and the ventilation amount of the ventilation fan reaches a predetermined large amount of ventilation, and the execution of the high-humidity mode. When the atmospheric humidity in the greenhouse is lower than the target humidity and the air blowing amount of the ventilation fan reaches a predetermined small amount of air blowing, the drying means is controlled to operate.
The dehumidifying and drying system according to claim 2. A temperature sensor for detecting the ambient temperature in the greenhouse; and storage means for storing the target humidity corresponding to the ambient temperature in advance.
The control means controls to acquire the appropriate target humidity from the storage means based on the control information of the temperature sensor.
The dehumidifying and drying system according to claim 2 or 3. The container and the blower unit are configured to be removable from the greenhouse.
The dehumidifying and drying system according to any one of claims 1 to 4.

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