JP2020101350A - Freezing facility - Google Patents

Abstract

To provide a freezing facility that can prevent frost heaving while eliminating the need for ground excavation at the time of construction.SOLUTION: A freezing facility 100 comprises a wall 6, a ceiling 7, a floor 5 located on an earth floor slab 1, and a freezer 40 whose periphery is covered by a heat insulating material 16. A ceiling space 11 is formed between a top end surface of the freezer 40 and the ceiling 7. A wall space 12 is formed between a side surface of the freezer 40 and the wall 6. An underfloor space 3 is formed in the floor 5. The ceiling space 11, the wall space 12, and the underfloor space 3 communicate with one another and form a flow passage 15 for fluid. The freezing facility 100 comprises an exhaust fan 20 or an air supply fan for passing the fluid through the flow passage 15.SELECTED DRAWING: Figure 1

Description

The present invention relates to a refrigeration facility.

In a freezing facility such as a food factory, a large-scale freezer is installed inside the building, and the temperature inside the freezer is negative, so this cold heat is transferred to the ground below the building. It may cause frost heave. The freezing mechanism is as follows. First, the heat transfer from the freezer causes the ground freezing line, which causes the formation of ice lenses and the movement of water in the ground. Here, the ice lens is a phenomenon in which water collects near the freezing surface to form lens-shaped ice crystals in the process of freezing underground water. After that, the ice lens grows and leads to the uplift of the ground. As described above, the ground is elevated due to freezing and volume expansion of underground water, which may cause damage such as inclination of the facility.

Examples of measures to prevent this frost heave include the so-called ventilation pipe construction method in which a frost heave prevention pipe is installed, and the so-called double floor construction method in which an underground pit is created and the ground itself that is subject to frost heave is eliminated from directly under the facility. ..

In the ventilation pipe method, a pipe for introducing outside air is buried in the ground under the floor of the freezer, and the ground is excavated when the pipe is buried. This ground excavation is the same in the double floor construction method that excludes the ground itself directly under the facility. In this ground excavation, there are problems of ground excavation cost and residual soil treatment cost, and this problem becomes remarkable as the size of the refrigeration facility increases. In the ventilation pipe construction method, the material cost of the PVC pipe is further increased, and in the double floor construction method, the foundation beam frame is constructed when the underfloor space is formed, and the floor requires a deck for receiving concrete. Expenses and material costs will increase further. Moreover, since the ground must be excavated, the construction period of the refrigeration facility may be prolonged. Further mentioning the ventilation pipe construction method, by introducing outside air into the pipe, dew condensation water may adhere to the pipe in the summer, so the pipe should be constructed with a slope to allow drainage to the outside. However, if the scale of the refrigeration facility is large and the pipe is long, it may be difficult to secure the gradient required for this drainage. In addition, the pipe needs to be opened to the outside air, but when the freezer is arranged in the center of the facility, a room that does not require frost heave measures is also constructed during construction, which may result in unnecessary construction costs. There is also.

Here, an underfloor blast pipe with a perforated pipe is arranged in the underfloor crushed stone layer, and hot air by exhaust heat of the freezer outdoor unit and the outside air are taken into this blast pipe, and the outer wall and roof of the building and the freezer etc. An underfloor frost heaving prevention method has been proposed in which the air that has flowed into the space between the wall and the wall is switchably sent (for example, see Patent Document 1).

JP, 2004-069098, A

The underfloor frost heave prevention method described in Patent Document 1 corresponds to the above ventilation pipe construction method because the underfloor crushed stone layer is provided below the soil concrete and the underfloor blast pipe is embedded in this underfloor crushed stone layer, and the ventilation pipe construction method is It will be a technology that includes the above-mentioned various problems.

The present invention has been made in view of the above problems, and an object of the present invention is to provide a refrigeration facility capable of preventing frost heave while eliminating the need to excavate the ground during construction.

In order to achieve the above object, one aspect of the refrigeration facility according to the present invention is:
A freezing facility with a built-in freezer,
The freezing facility has a wall, a ceiling, a floor above the dirt slab, and the freezer whose periphery is covered with a heat insulating material,
A ceiling space is formed between the ceiling of the freezer and the ceiling,
A wall space is formed between the side surface of the freezer and the wall,
An underfloor space is formed inside the floor,
The ceiling space, the wall space and the underfloor space communicate with each other to form a fluid passage.
An exhaust fan or an air supply fan for circulating a fluid in the flow passage is provided.

According to this aspect, by circulating a fluid such as air in the floor above the earth slab (earth concrete slab), excavation of the ground is unnecessary, and the floor on which the freezer is placed and the floor below it. The ground can be effectively heated, and frost heave can be prevented by eliminating the transfer of cold heat from the freezer to the ground. Either an exhaust fan or an air supply fan is applied as a fan for circulating a fluid in a flow passage formed by communication between a ceiling space, a wall space, and an underfloor space.

When using an exhaust fan, the air existing in the ceiling space, which tends to be hot due to solar radiation, can be actively sent to the underfloor space, and the floor above the dirt slab and the ground below the floor are effective even with a small air volume. Can be heated to. Therefore, for example, it is not always necessary to apply a high-standard exhaust fan. In order to prevent the inside of the refrigeration facility from becoming negative pressure due to the exhaust gas, an inflow opening through which outside air can enter is provided at any part of the refrigeration facility.

On the other hand, when the air supply fan is applied, the outside air is actively introduced by this air supply fan, but the outside air at a temperature higher than the cold heat from the freezer causes the floor above the earth slab and the ground below the floor. Can be effectively heated. In order to prevent the pressure in the refrigeration facility from rising due to the air supply, an exhaust opening capable of exhausting outside air is provided at any part of the refrigeration facility. In addition, in this aspect, a dehumidifier may be installed at an intermediate position of the flow passage.

Further, another aspect of the refrigeration facility according to the present invention is,
A freezing facility with a built-in freezer,
The freezing facility has a wall, a ceiling, a floor above the dirt slab, and a freezer whose periphery is covered with a heat insulating material,
A ceiling space is formed between the ceiling of the freezer and the ceiling,
A wall space is formed between the side surface of the freezer and the wall,
An underfloor space is formed inside the floor,
The ceiling space, the wall space and the underfloor space communicate with each other to form a fluid passage.
A dehumidifier and a circulation fan are installed in the middle of the flow passage.

According to this aspect, by circulating the fluid such as the air in the facility to the flow passage by the circulation fan, for example, the air existing in the ceiling space that is likely to become hot due to solar radiation heat can be sent to the underfloor space. Even the air volume can effectively heat the floor above the dirt slab. Further, by operating the dehumidifier arranged in the middle of the flow passage as needed, it is possible to suppress the occurrence of dew condensation in the underfloor space, the ceiling space, or the like. In particular, since the underfloor space is closer to the ground, dew condensation is more likely to occur than other parts of the flow passage.Therefore, if the dew condensation in the underfloor space can be suppressed, the dew condensation will naturally occur in other parts of the flow passage including the ceiling space. Can also be suppressed.

Further, in another aspect of the refrigeration facility according to the present invention, the refrigeration facility has a control device, sensors are respectively installed at a plurality of locations of the flow passage, and measurement data by the sensor is transmitted to the control device. Like this,
When the temperature of the ceiling space is higher than the temperature of the underfloor space, or when the dew point temperature of the ceiling space is lower than the temperature of the underfloor space, the controller operates the air supply fan or the exhaust fan. It is characterized by controlling.

According to this aspect, in the refrigeration facility having the exhaust fan or the air supply fan, the measurement data transmitted from the sensor is used to control the heating of the floor and the ground thereunder by the control of the control device according to the purpose. It is possible to prevent freezing and frost condensation in the underfloor space. Here, the “sensor” includes a thermometer and a dew point meter. For example, a thermometer and a dew point meter are installed in a ceiling space that constitutes a flow passage, and a thermometer is similarly installed in an underfloor space that constitutes a flow passage. The measurement data of each sensor is transmitted to the control device. Further, the control device is configured by a microcomputer installed inside or outside the refrigeration facility.

Further, in another aspect of the refrigerating facility according to the present invention, the refrigerating facility has a control device, sensors are respectively installed at a plurality of positions of the flow passage, and measurement data by the sensor is transmitted to the control device. Like this,
When the temperature of the ceiling space is higher than the temperature of the underfloor space, or when the dew point temperature of the ceiling space is lower than the temperature of the underfloor space, the controller controls the operation of the circulation fan,
When the dew point temperature of the ceiling space is higher than the temperature of the underfloor space, or when the relative humidity of the ceiling space is higher than a predetermined relative humidity threshold, to control the operation of the dehumidifier by the controller. Characterize.

According to this aspect, in the refrigeration facility having the dehumidifier and the circulation fan, the measurement data transmitted from the sensor is used to control the floor and the ground below the floor by the control of the control device according to the purpose. It is possible to prevent freezing and to prevent dew condensation in the underfloor space and ceiling space. Here, the "sensor" includes a thermometer, a dew point meter, and a hygrometer. For example, a thermometer, a dew point meter, and a hygrometer are installed in the ceiling space that constitutes the flow passage, and under the floor that similarly constitutes the flow passage. A thermometer is installed in the space, and measurement data from each sensor is transmitted to the control device.

Further, in another aspect of the refrigerating facility according to the present invention, the floor is formed by a plurality of laminated heat insulating material layers and a pressed concrete layer, and the underfloor space is formed between the plurality of heat insulating material layers. It is characterized by

According to this aspect, since the floor is formed by the plurality of laminated heat insulating material layers and the pressed concrete layer on the soil concrete slab, the opening for the underfloor space is formed in any of the heat insulating material layers. The underfloor space can be easily formed by providing. The freezer is generally surrounded by, for example, a heat insulating foam, and a heat insulating layer made of a plurality of stacked heat insulating foams is placed on the lower surface of the freezer.

As can be understood from the above description, according to the refrigeration facility of the present invention, it is possible to prevent frost heave while excavating the ground during construction is unnecessary.

It is a longitudinal cross-sectional view showing an example of a refrigeration facility according to the first embodiment. It is a II-II arrow line view of FIG. 1, and is a longitudinal cross-sectional view of a floor. It is a figure which shows an example of the hardware constitutions of a control apparatus. It is a figure which shows an example of a functional structure of a control apparatus. It is a flow chart which shows an example of the control method of the refrigerating facility concerning a 1st embodiment by a control device. It is a flow chart which shows another example of the control method of the refrigeration facility concerning a 1st embodiment by a control device. It is a longitudinal cross-sectional view showing an example of a refrigeration facility according to the second embodiment. It is a flow chart which shows an example of a control method of a refrigerating facility concerning a 2nd embodiment by a control device. It is a flowchart which shows the other example of the control method of the refrigeration facility which concerns on 2nd Embodiment by a control apparatus.

Hereinafter, an example of a refrigeration facility according to each embodiment and a control method thereof will be described with reference to the accompanying drawings. In the present specification and the drawings, substantially the same components may be denoted by the same reference numerals to omit redundant description.

[Refrigeration facility according to the first embodiment]
First, the refrigerating facility according to the first embodiment will be described with reference to FIGS. 1 to 4. Here, FIG. 1 is a vertical cross-sectional view showing an example of the refrigeration facility according to the first embodiment, and FIG. 2 is a II-II arrow view of FIG. 1 showing a vertical cross-sectional view of the floor. .. 3 is a diagram showing an example of the hardware configuration of the control device, and FIG. 4 is a diagram showing an example of the functional configuration of the control device.

As shown in FIG. 1, the refrigeration facility 100 includes a single-floor building 10 having a floor 5, walls 6, and a ceiling 7, and a freezer 40 placed on the floor 5 inside the building 10. The soil concrete slab 1 is on the ground G, and the floor 5 is placed on the soil concrete slab 1.

The floor 5 has a heat insulating material layer 2 formed by laminating a plurality of heat insulating material foams 2A, 2B, 2C, and a pressing concrete layer 4 that presses the heat insulating material layer 2 from above. Here, the heat insulating material foams 2A, 2B, and 2C are formed of foam materials such as expanded polystyrene, expanded styrene, polystyrene, and styrene.

The ceiling 7 is formed by a metal roof made of a steel plate, stainless steel, a gallium barium steel plate, or a corrugated plate or a folded plate obtained by applying a synthetic resin coating or plating to these plate materials. On the other hand, the wall 6 has a structure in which an exterior material and an interior material made of metal are joined by a base material made of a shaped steel material such as channel steel, and is erected on a cloth foundation 9 made of reinforced concrete.

The freezer 40 is surrounded by a heat insulating material foam 16 (an example of a heat insulating material), and the lower end of the heat insulating material foam 16 is brought into contact with the heat insulating material layer 2 so that the circumference of the freezer 40 is completely insulated. Be surrounded by The heat insulating foam 16 may be made of the same material as the heat insulating layer 2.

A ceiling space 11 is formed between the top end surface of the freezer 40 and the ceiling 7, a wall space 12 is formed between the side surface of the freezer 40 and the wall 6, and an underfloor space 3 is formed inside the floor 5. There is. The ceiling space 11, the wall space 12 and the underfloor space 3 communicate with each other to form a flow passage 15 through which a fluid such as air flows.

As shown in detail in FIG. 2, in a heat insulating material layer 2 formed by laminating a plurality of heat insulating material foams 2A, 2B, 2C, for example, a plurality of openings 3 are provided in the lowermost heat insulating material foam 2C, This opening 3 forms an underfloor space. Further, as shown in FIG. 1, a drainage pipe 3 a is buried in the end portion of the soil concrete slab 1, and the drainage pipe 3 a communicates with the underfloor space 3. If dew condensation occurs in the flow passage 15, it can be drained to the ground G through the drain pipe 3a. As described above, in the refrigeration facility 100, the underfloor space 3 through which air flows is formed on the soil concrete slab 1, and like the conventional ventilation pipe construction method, the ground is excavated and a pipe for ventilation is arranged. There is no need for construction.

In the illustrated example, an inflow opening 6a through which outside air enters is formed above the left side wall 6. On the other hand, below the right side wall 6, an exhaust fan 20 is attached. Here, as the exhaust fan 20, various types of fans such as a propeller fan, a sirocco fan, a turbo fan, a mixed flow fan, and a line flow fan can be applied.

Further, in the illustrated example, a control device 30 configured by a microcomputer is stored in the connecting portion between the wall 6 and the ceiling 7 on the right side. The control device 30 may be installed anywhere in the building 10 or may be installed in another building or the like outside the building 10.

A thermometer 51 and a dew point meter 52, which are included in a ceiling space sensor 50 (an example of a sensor), are installed in the ceiling space 11 that constitutes the flow passage 15. A thermometer 56, which is included in the underfloor space sensor 55 (an example of a sensor), is installed in the underfloor space 3 that constitutes the flow passage 15. Then, the measurement data from the respective sensors 50 and 55 are transmitted to the control device 30.

The exhaust fan 20 has a drive motor (not shown) and is connected to a commercial AC power source (not shown) by wiring. In addition, an operation/stop switch (not shown) is interposed in this wiring, receives the operation control signal and the operation stop control signal transmitted from the control device 30, and the operation/stop switch is turned on (operation) side or It is designed to be operated to the OFF (operation stop) side. The drive motor and the control device 30 transmit and receive signals wirelessly or by wire connection.

When the operation of the exhaust fan 20 is controlled by the control device 30, the outside air is taken into the flow passage 15 in the X1 direction via the inflow opening 6a, and passes through the wall space 12 forming the flow passage 15 and the underfloor space 3. Air (an example of a fluid) flows in the X2 direction toward the exhaust fan 20 side. Due to the flow of the air, the air existing in the ceiling space 11 which is relatively high in temperature due to solar radiation heat is drawn toward the wall space 12 side in the X3 direction and introduced into the underfloor space 3 through the wall space 12. The air flowing into the underfloor space 3 is exhausted to the outside in the X4 direction via the duct 18 and the exhaust fan 20. By thus flowing the warm air through the underfloor space 3, the floor 5 is heated, and the ground G below the floor 5 is also heated, so that heat transfer of cold heat from the freezer 40 to the ground G is suppressed. , The freezing of the ground G is suppressed or suppressed.

As shown in FIG. 3, the control device 30 configured by a microcomputer includes a CPU (Central Processing Unit) 71, a RAM (Random Access Memory) 72, a ROM (Read Only Memory) 73, and an NVRAM (Non-Volatile). It has a RAM 74, an HDD (Hard Disc Drive) 75, an I/O port 76, and the like. And each part is connected by the bus 77 so that information can be transmitted.

The ROM 73 stores various programs, data used by the programs, and the like. The RAM 72 is used as a storage area for loading a program and a work area for the loaded program. The CPU 71 realizes various functions by processing the program loaded in the RAM 72. The HDD 75 stores programs and various data used by the programs. Further, the HDD 75 stores a series of process sequences (control methods for various refrigeration facilities) based on the measurement data. The NVRAM 74 stores various setting information and the like. The I/O port 76 includes an operation panel 58, a ceiling space sensor 50 (an example of a sensor, which includes a thermometer 51, a dew point meter 52, and a hygrometer 53), an underfloor space sensor 55 (an example of a sensor, a thermometer). (Including 56) and the like, and is connected by wire or wirelessly to control input/output of various data and signals. The hygrometer 53 is applied to the refrigeration facility 100A according to the second embodiment shown in FIG.

The CPU 71 constitutes the center of the control device 30 and executes the control program stored in the ROM 73 or the like. Further, the CPU 71, based on the instruction signal from the operation panel 58, follows the process sequence stored in the HDD 75 (and the circulation fan 20A included in the refrigeration facility 100A shown in FIG. 7) and FIG. The operation operation and the operation stop operation of the dehumidifier 60 included in the refrigeration facility 100A shown in FIG. That is, the CPU 71 executes various determination controls in accordance with the process sequence based on the measurement data transmitted from the ceiling space sensor 50 and the underfloor space sensor 55, and controls and operates the fan 20 (20A) and the dehumidifier 60. Execute stop control.

The program applied by the control device 30 may be stored in, for example, a hard disk, a compact disk, a magneto-optical disk, or the like. Further, the process sequence and the like may be set in the control device 30 and stored in a portable computer-readable storage medium such as a CD-ROM, a DVD, or a memory card, and may be read out. The control device 30 is also an input device such as a keyboard and a mouse that performs a command input operation, a display device such as a display that visualizes and displays the operating status of the fan 20 (20A) and the dehumidifier 60, and an output of a printer or the like. It may have a user interface such as a device.

Further, as shown in FIG. 4, the control device 30 includes a calculation unit 31, a control command unit 32, and a data storage unit 33.

The data storage unit 33 stores measurement data regarding temperature, dew point, and humidity transmitted from the ceiling space sensor 50 and the underfloor space sensor 55 as needed. The data storage unit 33 also stores input data regarding a threshold value of relative humidity in a ceiling space or the like.

The arithmetic unit 31 reads out the measurement data from the ceiling space sensor 50 and the underfloor space sensor 55 stored in the data storage unit 33, and performs various determination controls according to a series of process sequences. The various determination controls will be described in detail below.

The control command unit 32 transmits a driving control command signal or a driving stop control command signal to the fan 20 (20A) or the dehumidifier 60 based on the determination content of the calculation unit 31. As described above, these command signals are transmitted to the operation/stop switch by wire or wirelessly, and the operation of the operation/stop switch to the ON (operation) side or the OFF (operation stop) side causes the fan 20 ( 20A) and one of the dehumidifiers 60, a simultaneous operation of both, or an operation of stopping the operation is executed.

The refrigerating facility 100 shown in the figure has a form in which an inflow opening 6a is provided in the wall 6 and the warm air in the ceiling space 11 is guided to the underfloor space 3 while the outside air is taken into the flow passage 15 by the exhaust fan 20. Other forms may be used. For example, an air supply fan (not shown) is provided at the position of the inflow opening 6a to actively introduce the outside air into the flow passage 15, and an exhaust opening is provided at the position of the exhaust fan 20 to exhaust the introduced outside air. A form in which the gas is exhausted through the opening may be used. Also in the refrigeration facility of this aspect, as the introduced outside air flows through the flow passage 15, the warm air in the ceiling space 11 can be introduced into the underfloor space 3, the floor 5 is heated, and the floor 5 is heated. By heating the ground G below the ground, heat transfer of cold heat from the freezer 40 to the ground G is suppressed, and frost heave of the ground G is suppressed or suppressed.

<Example of control method>
Next, an example of a control method of the refrigeration facility 100 will be described with reference to FIGS. 5 and 6. Here, FIG. 5 and FIG. 6 are flowcharts showing an example of a control method of the refrigeration facility 100 by the control device 30.

The control method of the refrigerating facility 100 shown in FIG. 5 is a control method for heating the floor 5 and the ground G below the floor 5 for the purpose of preventing freezing.

First, the calculation unit 31 executes the determination control of the temperature of the ceiling space 11 and the temperature of the underfloor space 3 (step S1). When it is determined that the temperature of the ceiling space 11 is higher than the temperature of the underfloor space 3, the floor 5 and the ground G therebelow can be heated by supplying the air in the ceiling space 11 to the underfloor space 3. An operation control command signal is transmitted from the command unit 32 to the exhaust fan 20 to execute exhaust fan operation control (step S2). As described above, when the operation of the exhaust fan 20 is controlled, the outside air is taken into the flow passage 15 through the inflow opening 6a and flows to the side of the exhaust fan 20 through the underfloor space 3. The air existing in the ceiling space 11 which is relatively high in temperature due to the heat received by solar radiation is introduced into the underfloor space 3. By introducing this warm air into the underfloor space 3, the floor 5 and the ground G below the floor 5 are heated.

On the other hand, when it is determined that the temperature of the ceiling space 11 is lower than the temperature of the underfloor space 3, even if the air in the ceiling space 11 is supplied to the underfloor space 3, the floor 5 and the ground G below it cannot be heated. Then, the control command unit 32 transmits an operation stop control command signal to the exhaust fan 20 to execute the exhaust fan operation stop control (step S3). Note that this operation stop control is to stop the operation when the exhaust fan 20 has been operated until then, and to maintain that state when the exhaust fan 20 has not been operated until then.

Next, the control method of the refrigerating facility 100 shown in FIG. 6 is a control method for the purpose of preventing dew condensation in the underfloor space 3.

First, the calculation unit 31 executes the determination control as to whether the dew point temperature of the ceiling space 11 and the temperature of the underfloor space 3 are high or low (step S4). When it is determined that the dew point temperature of the ceiling space 11 is lower than the temperature of the underfloor space 3, by sending the air in the ceiling space 11 to the underfloor space 3, dew condensation of the underfloor space 3 can be prevented, so that the control command unit An operation control command signal is transmitted from 32 to the exhaust fan 20 to execute the exhaust fan operation control (step S2). On the other hand, when it is determined that the dew point temperature of the ceiling space 11 is higher than the temperature of the underfloor space 3, even if the air in the ceiling space 11 is sent to the underfloor space 3, it cannot contribute to the prevention of dew condensation in the underfloor space 3, An operation stop control command signal is transmitted from the command unit 32 to the exhaust fan 20 to execute the exhaust fan operation stop control (step S3).

As described above, according to the control method of the refrigeration facility 100 by the control device 30, the operation of the exhaust fan 20 that is suitable for each purpose such as prevention of frost heave of the ground G below the floor 5 and prevention of dew condensation in the underfloor space 3 is performed. Control can be executed.

Here, two specific examples will be described. The first embodiment simulates the daytime of a sunny day in summer, and the second embodiment simulates the nighttime of summer.

In the first embodiment, the conditions of the outside air are a temperature of 30° C. and a relative humidity of 55%. The conditions of the ceiling space 11 are a temperature of 40° C., a relative humidity of 30%, and a dew point temperature of 19° C. The temperature of the surface of the soil concrete slab 1 is 20°C.

In the first embodiment, by executing the exhaust fan operation control based on the flowcharts shown in FIGS. 5 and 6, it is possible to prevent both frost heaving due to heating of the ground G and dew condensation in the underfloor space 3. ..

On the other hand, in the second embodiment, the outside air conditions are a temperature of 25° C. and a relative humidity of 70%. The conditions of the ceiling space 11 are a temperature of 40° C., a relative humidity of 70%, and a dew point temperature of 19° C. The temperature of the surface of the soil concrete slab 1 is 20°C.

Also in the second embodiment, by executing the exhaust fan operation control based on the flowcharts shown in FIGS. 5 and 6, it is possible to prevent both frost heaving due to heating of the ground G and dew condensation in the underfloor space 3. ..

[Refrigeration facility according to the second embodiment]
Next, a refrigeration facility according to the second embodiment will be described with reference to FIG. 7. Here, FIG. 7 is a vertical cross-sectional view showing an example of the refrigerating facility according to the second embodiment.

As shown in FIG. 7, the refrigeration facility 100A eliminates the outside air introduction and exhaust fan 20 like the refrigeration facility 100, disposes the circulation fan 20A and the dehumidifier 60 in the ceiling space 11 forming the flow passage 15, and distributes the air. This is a form in which the air in the facility is circulated in the passage 15.

A thermometer 51, a dew point meter 52, and a hygrometer 53, which are included in the ceiling space sensor 50A, are installed in the ceiling space 11 that constitutes the flow passage 15. Further, a thermometer 56 included in the underfloor space sensor 55 is installed in the underfloor space 3 that constitutes the flow passage 15.

When the control device 30 controls the operation of the circulation fan 20A, the air existing in the ceiling space 11 which is relatively high in temperature due to solar radiation heat is pushed out to the wall space 12 side, and the underfloor space 3 is passed through the wall space 12. Will be introduced to. The air that has flowed into the underfloor space 3 returns to the circulation fan 20A, and the air in the flow passage 15 circulates in the X5 direction in this way, so that the floor 5 is heated and the ground G below the floor 5 is also heated. Be warmed. By heating the floor 5 and the ground G below it, the transfer of cold heat from the freezer 40 to the ground G is suppressed, and the frost heave of the ground G is suppressed or suppressed. Here, it is preferable that a duct (not shown) extends from the circulation fan 20A to extend to the underfloor space 3 so that the air pushed by the circulation fan 20A is efficiently provided to the underfloor space 3. In addition to the circulation fan 20A provided in the ceiling space 11 as in the illustrated example, the circulation fan 20A may be provided in the wall space 12.

Further, by controlling the operation of the dehumidifier 60 by the control device 30, the relative humidity of the ceiling space 11 is set to be equal to or lower than a predetermined threshold value, whereby dew condensation in the ceiling space can be prevented. Further, by controlling the temperature of the underfloor space 3 to be equal to or lower than the dew point temperature of the ceiling space 11, it is possible to prevent dew condensation in the underfloor space 3.

<Example of control method>
Next, an example of a control method of the refrigeration facility 100A will be described with reference to FIGS. 8 and 9. Here, FIG. 8 and FIG. 9 are flowcharts showing an example of a control method of the refrigeration facility 100A by the control device 30. Also in the refrigeration facility 100A, the operation control of the circulation fan 20A is executed by the same method as the operation control method of the exhaust fan 20 included in the refrigeration facility 100. That is, the control method of the refrigerating facility 100 shown in FIG. 5 which is a control method for heating the floor 5 and the ground G below the floor 5 for the purpose of preventing frost heave, and FIG. The control method of the refrigerating facility 100 shown in is similarly applied to the refrigerating facility 100A.

The control method shown in FIGS. 8 and 9 is a control method for the dehumidifier 60 included in the refrigeration facility 100A. FIG. 8 shows a control method of the dehumidifier 60 for the purpose of preventing dew condensation in the underfloor space 3.

First, the calculation unit 31 executes control of determining whether the dew point temperature of the ceiling space 11 and the temperature of the underfloor space 3 are high or low (step S5). When it is determined that the dew point temperature of the ceiling space 11 is higher than the temperature of the underfloor space 3, by controlling the operation of the dehumidifier 60, dew condensation of the underfloor space 3 can be prevented, so the dehumidifier 60 is controlled by the control command unit 32. The operation control command signal is transmitted to and the dehumidifier operation control is executed (step S6). On the other hand, when it is determined that the dew point temperature of the ceiling space 11 is lower than the temperature of the underfloor space 3, even if the dehumidifier 60 is controlled to operate, it cannot contribute to the prevention of dew condensation in the underfloor space 3, so that the control command unit 32 An operation stop control command signal is transmitted to the dehumidifier 60 to execute dehumidifier operation stop control (step S7). In this way, by suppressing unnecessary operation of the dehumidifier 60, it is possible to reduce the power cost.

Next, FIG. 9 shows a method of controlling the dehumidifier 60 for the purpose of preventing dew condensation in the ceiling space. At the time of this control, the data storage unit 33 shown in FIG. 4 stores a relative humidity threshold value (for example, 80% relative humidity) of the ceiling space 11.

In the calculation unit 31, the relative humidity of the ceiling space 11 and the relative humidity threshold value of the ceiling space 11 are controlled to be high or low (step S8). When it is determined that the relative humidity of the ceiling space 11 is higher than the relative humidity threshold value. Since the dehumidification of the ceiling space 11 can be prevented by controlling the operation of the dehumidifier 60, the control command unit 32 transmits an operation control command signal to the dehumidifier 60 to execute the dehumidifier operation control (step S6). On the other hand, when it is determined that the relative humidity of the ceiling space 11 is lower than the relative humidity threshold value, even if the dehumidifier 60 is operation-controlled, it cannot contribute to the prevention of dew condensation in the ceiling space 11. An operation stop control command signal is transmitted to 60, and dehumidifier operation stop control is performed (step S7).

As described above, according to the control method of the refrigerating facility 100A by the control device 30, according to respective purposes such as prevention of freezing of the ground G below the floor 5, dew condensation of the underfloor space 3, and dew condensation of the ceiling space 11. Thus, suitable operation control of the circulation fan 20A and the dehumidifier 60 can be executed. In addition, in order to satisfy a plurality of purposes at the same time, the simultaneous operation control of the circulation fan 20A and the dehumidifier 60 may be executed, and either one operation control is executed and the other operation stop control is executed. There is also.

Here, four specific examples of the refrigeration facility 100A will be described. The first embodiment and the second embodiment have the same conditions as the first embodiment and the second embodiment in the summer of the refrigeration facility 100 described above. Further, the third embodiment simulates an example of the daytime on a cloudy summer day, and the fourth example simulates another example of the daytime on a cloudy summer day. The relative humidity threshold of the ceiling space 11 is 80%.

In the first embodiment, by executing the circulation fan operation control based on the flowcharts shown in FIGS. 5 and 6, it is possible to prevent both frost heaving by heating the ground G and dew condensation in the underfloor space 3. ..

On the other hand, in the first embodiment, even if the circulator operation control is executed based on the flowcharts shown in FIGS. 8 and 9, it cannot contribute to the prevention of dew condensation in the underfloor space 3 and the ceiling space 11, so the dehumidifier operation is stopped. Execute control.

In the second embodiment, by executing the exhaust fan operation control based on the flowcharts shown in FIGS. 5 and 6, it is possible to prevent both frost heaving due to heating of the ground G and dew condensation in the underfloor space 3. ..

On the other hand, in the second embodiment, by performing the circulator operation control based on the flowcharts shown in FIGS. 8 and 9, it is possible to prevent dew condensation in the underfloor space 3 and the ceiling space 11. Execute.

In the third embodiment, the conditions of the outside air are a temperature of 26° C. and a relative humidity of 85%. The conditions of the ceiling space 11 are that the temperature is 27° C., the relative humidity is 81%, and the dew point temperature is 23° C. The temperature of the surface of the soil concrete slab 1 is 20°C.

In the third embodiment, by performing the exhaust fan operation control based on the flowchart shown in FIG. 5, it is possible to prevent frost rise due to the heating of the ground G, but based on the flowchart shown in FIG. Even if the operation control is executed, the dew condensation of the underfloor space 3 cannot be prevented. Therefore, in the third embodiment, for example, the operation stop control of the circulation fan 20A is executed. Here, based on the determination that it is sufficient to prevent frost heaving by heating the ground G, the operation control of the circulation fan 20A may be executed.

On the other hand, in the third embodiment, by performing the circulator operation control based on the flowcharts shown in FIGS. 8 and 9, it is possible to prevent dew condensation in the underfloor space 3 and the ceiling space 11. Execute.

In the fourth example, the conditions of the outside air are a temperature of 25° C. and a relative humidity of 70%. The conditions of the ceiling space 11 are a temperature of 30° C., a relative humidity of 75%, and a dew point temperature of 25° C. The temperature of the surface of the soil concrete slab 1 is 20°C.

In the fourth embodiment, although the exhaust fan operation control is executed based on the flowchart shown in FIG. 5, it is possible to prevent frost rise due to the heating of the ground G, but the exhaust fan is formed based on the flowchart shown in FIG. Even if the operation control is executed, the dew condensation of the underfloor space 3 cannot be prevented. Therefore, in the fourth embodiment, for example, the operation stop control of the circulation fan is executed. Here, also in the fourth embodiment, the operation control of the circulation fan 20A may be executed based on the determination that it is sufficient to prevent the frost rise by heating the ground G.

On the other hand, in the fourth embodiment, it is possible to prevent dew condensation in the underfloor space 3 by executing the circulator operation control based on the flow chart shown in FIG. 8, but based on the flow chart shown in FIG. Even if the operation control is executed, it cannot contribute to the prevention of dew condensation on the ceiling space 11. Therefore, in the fourth embodiment, for example, the operation stop control of the dehumidifier is executed.

There may be other embodiments in which other components are combined with the configurations and the like described in the above embodiments, and the present invention is not limited to the configurations shown here. This point can be changed without departing from the spirit of the present invention, and can be appropriately determined according to the application form.

1: Soil concrete slab, 2: Heat insulating material layer, 2A, 2B, 2C: Heat insulating material foam, 3: Underfloor space (opening), 4: Pressed concrete layer, 5: Floor, 6: Wall, 6a: Inflow opening, 7 : Ceiling, 10: Building, 11: Ceiling space, 12: Wall space, 15: Flow path, 16: Insulation foam (insulation material), 20: Exhaust fan (fan), 20A: Circulation fan (fan), 30: Control device, 31: arithmetic unit, 32: control command unit, 33: data storage unit, 40: freezer, 50, 50A: ceiling space sensor (sensor), 51: thermometer, 52: dew point meter, 53: hygrometer, 55: underfloor space sensor (sensor), 56: thermometer, 60: dehumidifier, 100, 100A: refrigeration facility, G: ground

Claims (5)

A freezing facility with a built-in freezer,
The freezing facility has a wall, a ceiling, a floor above the dirt slab, and the freezer whose periphery is covered with a heat insulating material,
A ceiling space is formed between the ceiling of the freezer and the ceiling,
A wall space is formed between the side surface of the freezer and the wall,
An underfloor space is formed inside the floor,
The ceiling space, the wall space and the underfloor space communicate with each other to form a fluid passage.
A refrigeration facility having an exhaust fan or an air supply fan for circulating a fluid in the flow passage. A freezing facility with a built-in freezer,
The freezing facility has a wall, a ceiling, a floor above the dirt slab, and a freezer whose periphery is covered with a heat insulating material,
A ceiling space is formed between the ceiling of the freezer and the ceiling,
A wall space is formed between the side surface of the freezer and the wall,
An underfloor space is formed inside the floor,
The ceiling space, the wall space and the underfloor space communicate with each other to form a fluid passage.
A refrigeration facility, wherein a dehumidifier and a circulation fan are installed in the middle of the flow passage. The refrigeration facility has a control device, sensors are respectively installed at a plurality of locations of the flow passage, and measurement data by the sensor is transmitted to the control device.
When the temperature of the ceiling space is higher than the temperature of the underfloor space, or when the dew point temperature of the ceiling space is lower than the temperature of the underfloor space, the controller operates the air supply fan or the exhaust fan. The refrigeration facility according to claim 1, wherein the refrigeration facility is controlled. The refrigeration facility has a control device, sensors are respectively installed at a plurality of locations of the flow passage, and measurement data by the sensor is transmitted to the control device.
When the temperature of the ceiling space is higher than the temperature of the underfloor space, or when the dew point temperature of the ceiling space is lower than the temperature of the underfloor space, the controller controls the operation of the circulation fan,
When the dew point temperature of the ceiling space is higher than the temperature of the underfloor space, or when the relative humidity of the ceiling space is higher than a predetermined relative humidity threshold, to control the operation of the dehumidifier by the controller. The refrigeration facility according to claim 2, which is characterized in that. 5. The floor is formed by a plurality of heat insulating material layers and a pressing concrete layer that are stacked, and the underfloor space is formed between the plurality of heat insulating material layers, any one of claims 1 to 4. The refrigeration facility according to 1 above.

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