JP6347076B1 - Wine cellar and defrost control method - Google Patents

Abstract

An object of the present invention is to provide a wine cellar that performs optimum defrosting operation according to the use environment. A wine cellar disclosed in the present application is arranged near a cooler and defrost temperature sensor 24 for detecting the cooler ambient temperature, and raises the cooler ambient temperature to melt the frost attached to the cooler. When the heater 25 reaches a predetermined timing, the compressor 31 is stopped, the cooler ambient temperature detected by the defrost temperature sensor 24 is checked, and the warmer heater 25 is started based on the cooler ambient temperature. And a control circuit 11 for determining whether or not to do so. [Selection] Figure 3-2

Description

  The present invention relates to a wine cellar having a defrosting function for melting frost adhering to a cooler.

  Conventionally, defrosting control as described in Patent Document 1 below is known. For example, the refrigerator described in Patent Document 1 below includes a defrost heater for melting frost attached to the cooler and a thermistor installed in the vicinity of the cooler, and periodically starts the defrost heater. Execute defrosting operation. During the defrosting operation, when the temperature detected by the thermistor becomes a predetermined temperature or more, or when the energization time of the defrosting heater reaches the set time, the defrosting heater is stopped and the defrosting operation is finished. .

JP 2003-35483 A

  In the said patent document 1, it describes about the defrost control of the refrigerator which can hold | maintain the inside of a warehouse at low temperature (below zero), Specifically, in the utilization environment on the assumption that frost always adheres to a cooler, Defrosting control is disclosed in which a defrosting heater is periodically activated to remove frost adhered to the cooler.

  However, it is not efficient to uniformly apply the conventional defrosting control to a wine cellar that can be operated at an internal temperature setting such that frost does not adhere to the cooler. That is, there is room for improvement in the conventional defrosting control from the viewpoint of avoiding useless defrosting operation.

  In addition, the wine cellar has a structure to store the moisture in the cabinet without draining it for the purpose of maintaining the humidity in the cabinet (installation of a dish to collect water). Humidity is high. Therefore, in a wine cellar that maintains high humidity, re-frosting with dew adhering to the cooler is repeated simply by defrosting using a defrost heater as in the past, and the remaining There is a problem that new frost adheres to the frost due to dew and the frost adhering to the cooler eventually grows.

  This invention is made | formed in view of the above, Comprising: It aims at providing the wine cellar which performs the optimal defrost operation according to utilization environment.

In order to solve the above-mentioned problems and achieve the object, the wine cellar disclosed in the present application adopts a cooling method using a compressor and has a defrosting function for melting frost adhering to the cooler by a cooling cycle. A temperature sensor disposed in the vicinity of the cooler for detecting the cooler ambient temperature, a heating heater for raising the cooler ambient temperature to melt the frost attached to the cooler, and when a predetermined timing is reached A controller that stops the compressor and checks the ambient temperature of the cooler detected by the temperature sensor, and determines whether to start the heating heater based on the ambient temperature of the cooler , and The controller is configured such that the cooler ambient temperature detected by the temperature sensor at the predetermined timing may cause frost to adhere to the cooler. When the temperature is equal to or lower than the “first temperature” defined as a certain temperature, the warming heater is activated, and the temperature around the cooler after the warming heater is activated is “second temperature (“ first temperature ”). ”<“ Second temperature ”)”, the heating heater is stopped, and the temperature around the cooler after the heating heater is stopped is “third temperature (“ second temperature ”). The compressor is restarted when reaching “temperature” <“third temperature”) ” .

The defrosting control method in the wine cellar disclosed in the present application is a defrosting control method in a wine cellar that adopts a cooling method using a compressor and has a defrosting function for melting frost attached to the cooler by a cooling cycle, The wine cellar is arranged in the vicinity of the cooler and detects a temperature around the cooler; a heating heater that raises the cooler ambient temperature in order to melt frost attached to the cooler; and the cooler And a control unit that performs control for melting frost adhering to the cooler, and as a process of the control unit, when the predetermined timing is reached, the compressor is stopped and the periphery of the cooler detected by the temperature sensor Based on the temperature confirmation step for checking the temperature and the ambient temperature of the cooler obtained as a result of the check. The look-containing and defrost control step of determining whether to activate the warming heater, a Te, in the defrosting control step, the cooler ambient temperature detected by said temperature sensor at the predetermined timing, the cooler When the temperature is equal to or lower than the “first temperature” defined as the temperature at which frost may adhere, the warming heater is activated, and the ambient temperature of the cooler after the warming heater is activated is “second temperature”. When the temperature reaches the first temperature (“first temperature” <“second temperature”) ”, the heating heater is stopped, and the cooler ambient temperature after the heating heater is stopped is“ first temperature ”. When the temperature reaches a temperature of 3 (“second temperature” <“third temperature”) ”, the compressor is restarted .

  The wine cellar disclosed in the present application has an effect that an optimum defrosting operation can be performed according to the use environment.

FIG. 1-1 is a front view and a cross-sectional view of a wine cellar. FIG. 1-2 is a side view and a cross-sectional view of a wine cellar. FIG. 2-1 is a front view and a cross-sectional view of the wine cellar. FIG. 2-2 is a side view and a sectional view of the wine cellar. FIG. 3-1 is a diagram illustrating an example of an electrical diagram of a wine cellar. FIG. 3-2 is a diagram illustrating an example of an electrical system diagram of the wine cellar. FIG. 4A is a diagram illustrating an example of an operation panel. FIG. 4B is a diagram of an example of the operation panel. FIG. 5A is a diagram illustrating an example of a cooling cycle of a wine cellar. FIG. 5-2 is a diagram illustrating an example of a cooling cycle of a wine cellar. FIG. 6A is a diagram illustrating an example of air circulation in the storage chamber. FIG. 6B is a schematic diagram illustrating air circulation in the storage room in the wine cellar disclosed in the present application. FIG. 7A is a flowchart illustrating an example of the cooling function. FIG. 7-2 is a flowchart illustrating an example of a heating function. FIG. 8 is a diagram illustrating a state of the temperature in the storage chamber and the ambient temperature of the cooler in a steady state. FIG. 9 is a flowchart showing the defrosting control method. FIG. 10 is a diagram illustrating an example of defrosting control. FIG. 11 is a diagram illustrating an example of defrosting control. FIG. 12 is a diagram illustrating an example of defrosting control. FIG. 13 is a diagram illustrating an example of defrosting control.

  Hereinafter, embodiments of a wine cellar and a defrosting control method disclosed in the present application will be described in detail with reference to the drawings. Note that the present invention is not limited to the embodiments.

<Overall configuration>
FIG. 1 is a view showing an example of the structure of a wine cellar. Specifically, FIG. 1-1 is a front view and a cross-sectional view of a wine cellar according to the present embodiment, and FIG. It is a side view of the wine cellar and its sectional view.

  1-1 and 1-2, 1 is a wine cellar (main body), and this wine cellar 1 is provided with an upper storage chamber 2a and a lower storage chamber 2b that can be individually temperature controlled. . Each storage chamber is independent by a fixed partition plate 3, and can be set in units of 1 ° C. within a range of 0 ° C. to 20 ° C., for example. In the present embodiment, as an example, it is assumed that a wine cellar capable of storing 12 wine bottles and having a total effective upper and lower capacity of 100 L class (small size). By configuring the upper and lower chambers, more accurate temperature control becomes possible, for example, one for short-term storage (about 7-8 ° C), the other for long-term storage (about 14 ° C), etc. In addition, it is possible to use the upper and lower rooms properly according to the purpose.

  Further, the wine cellar 1 is provided with a glass door 4 in which, for example, a full flat glass having a three-layer structure excellent in heat insulation and interior properties is adopted over the entire surface. In addition, a touch-type operation panel 5 is arranged on the upper part of the glass door 4, and it is possible to perform operations such as ON / OFF of the main power supply and light (LED lighting of each storage room), temperature adjustment in the storage room, etc. It is possible to keep the environment in the storage room in an optimal state by operation.

  Further, the wine cellar 1 has a shelf pitch set so that, for example, a thick wine bottle (champagne diameter) can be smoothly taken in and out, and the upper storage room 2a has three wine bottles in a laid state. Shelf can be stored vertically in a four-stage configuration, and a total of 12 wine bottles can be stored. Further, in the lower storage chamber 2b, for example, three wine bottles are diagonally arranged on the bottom shelf using a step of a storage 6 in which a compressor or the like necessary for a cooling cycle described later is stored. Furthermore, shelves that can store three wine bottles in a laid state are provided in a three-stage configuration vertically, and a total of twelve wine bottles can be stored. In addition, the shelf board 7 which partitions off the shelf of each preservation | save room is a structure which can be removed and attached freely by sliding.

  As shown in FIG. 1-2, a storage 6 is provided at the back of the lower storage chamber 2b so as to obtain a stepped step in the storage chamber. The storage 6 will be described later. Equipment such as a compressor and capillary tube used in the cooling cycle is housed. Further, a storage 8 that is a space partitioned from each storage room by a back panel 9 is provided in the back of each storage room, and this storage 8 is used in, for example, a cooling cycle described later. An accumulator, a cooler, and the like are accommodated, and further, a heater such as a heating heater, LED, an air circulation fan, a defrosting temperature sensor, and the like are also accommodated.

  In the above description, the upper and lower storage chambers 2a and 2b that can be individually controlled in the upper and lower temperatures have been described. However, the wine cellar 1 according to the present embodiment is described here. For example, the storage room as shown in FIG. 2 (FIGS. 2-1 and 2-2) may be one type of wine cellar, and three or more storages are not shown. It may have a chamber. FIG. 2 is a diagram showing an example of the structure of a wine cellar. Specifically, FIG. 2-1 is a front view of a wine cellar of one type of storage room and a cross-sectional view thereof, and FIG. FIG. 2 is a side view and a cross-sectional view of a type of wine cellar with a storage room. The wine cellar 1 having a single storage room is obtained by removing the function of the upper storage room 2a from the two-tiered wine cellar, and is composed only of the storage room 2 having the function of the lower storage room 2b. It will be a thing.

<Detailed configuration>
Next, the configuration of the wine cellar 1 will be described in more detail. In addition, although the structure and operation | movement are described in detail using the wine cellar 1 of the upper and lower two steps structure shown in FIG. 1 as an example here, the wine cellar of a present Example is not restricted to this, For example, FIG. It can be applied to all wine cellars in which the temperature can be adjusted individually for each storage room, such as the wine cellar 1 shown in FIG.

  First, the electrical circuit configuration and control of the wine cellar 1 configured as shown in FIG. 1 will be described. FIG. 3A is a diagram illustrating an example of an electrical diagram of the wine cellar 1.

  As shown in FIG. 3A, in the wine cellar 1, the control circuit 11 receives AC 100V as input and controls electronic devices in the wine cellar 1. Specifically, the LEDs 21a and 21b, indoor temperature sensors 22a and 22b, defrost temperature sensors 24a and 24b, heating heaters 25a and 25b, and fans 26a and 26b provided for the upper storage chamber 2a and the lower storage chamber 2b are controlled. To do. In addition, the control circuit 11 controls the compressor 31 and the electromagnetic valve (three-way valve) 32 used in the cooling cycle as a configuration common to the upper storage chamber 2a and the lower storage chamber 2b. As an example, an electrical system diagram of a wine cellar 1 with one storage room as shown in FIG. 2 is shown in FIG. 3-2. In the wine cellar 1, the control circuit 11 receives AC 100V as input, the LED 21 provided for the storage room 2, the room temperature sensor 22, the defrost temperature sensor 24, the heating heater 25, the fan 26, the compressor 31, the solenoid valve ( 3 way valve) 32 is controlled.

  Further, the control circuit 11 controls the ON / OFF of the main power source and the light (LED lighting of each storage room) and the temperature adjustment of the storage room based on the operation information obtained from the operation panel 5 provided on the glass door 4. I do. FIG. 4A is a diagram illustrating an example of the touch-type operation panel 5. In the present embodiment, since the upper storage chamber 2a and the lower storage chamber 2b are independent, the temperature of each storage chamber can be set individually (corresponding to Upper and Lower in FIG. 4A). FIG. 4B is a diagram illustrating an example of the touch-type operation panel 5 in a wine cellar of a type having one storage room.

  The control circuit 11 of the present embodiment that controls the various electronic devices includes, for example, a control unit including a CPU (Central Processing Unit) and an FPGA (Field Programmable Gate Array), a ROM (Read Only Memory), and a RAM (Random (Access Memory) and the like, and an interface unit that transmits and receives signals to and from the various electronic devices illustrated.

  3A, LED 21a is illumination for the upper storage chamber 2a, and LED 21b is illumination for the lower storage chamber 2b. The control circuit 11 is interlocked with the ON / OFF operation of the operation panel 5, respectively. ON / OFF is controlled by.

  The indoor temperature sensor 22a is, for example, a sensor that is installed at a predetermined position in the upper storage chamber 2a to detect the ambient temperature, and the indoor temperature sensor 22b is installed at a predetermined position in the lower storage chamber 2b and detects the ambient temperature. It is a sensor for detection. Each of the indoor temperature sensors 22a and 22b notifies the control circuit 11 of the temperature of the allocated storage room. Upon receiving this notification, the control circuit 11 sets, for each storage room, the temperature set by operating the operation panel 5 (corresponding to the above 0 ° C. to 20 ° C.) and the temperature notified from the room temperature sensors (22a, 22b). And control related to cooling and heating so that the set temperature of each storage room is maintained. That is, the current temperature (see FIGS. 4A and 4B) displayed on the operation panel 5 corresponds to the temperature in each storage room.

  The defrost temperature sensor 24a is disposed in the vicinity of the cooler for the upper storage chamber 2a, and the defrost temperature sensor 24b is disposed in the vicinity of the cooler for the lower storage chamber 2b. For example, when the defrosting control operation is periodically started (compressor 31 OFF) and then the defrosting control operation is ended (compressor 31 ON) under the control of the control circuit 11, the defrosting temperature sensors 24 a and 24 b are respectively close to each other. Measure the ambient temperature of the cooler (evaporator). Then, the control circuit 11 checks the measurement result. The control circuit 11 can melt the frost adhering to the cooler in the defrosting control operation by performing ON / OFF control of the heating heater (heating heaters 25a and 25b described later) based on the measurement result. .

  The heating heater 25a is, for example, integrated with a cooler for the upper storage chamber 2a, and the heating heater 25b is, for example, integrated with a cooler for the lower storage chamber 2b. The control circuit 11 has a function of increasing the ambient temperature during the defrosting control operation (when the compressor 31 is OFF) and during the normal operation (when the compressor 31 is ON). The fan 26a is installed, for example, in the upper part of the upper storage room 2a, and the fan 26b is installed, for example, in the upper part of the lower storage room 2b, and circulates the air in the assigned storage room under the control of the control circuit 11. Let For example, the temperature in the upper storage chamber 2a can be raised to a preset temperature by the heating heater 25a and the fan 26a being linked in the upper storage chamber 2a and circulating the air warmed by the heating heater 25a. . The same control as described above is possible in the lower storage chamber 2b. Further, when the outside air temperature is particularly low, such as a room in midwinter, it is assumed that the temperature in each storage room of the wine cellar 1 is significantly lower than the set temperature. Even in such a case, the heater 25a is heated. , 25b enables appropriate temperature management.

  In FIG. 3A, the control circuit 11 electrically controls the compressor 31 and the electromagnetic valve 32 and individually controls the cooling cycle of the wine cellar 1 for each storage room. FIG. 5A is a diagram illustrating an example of the cooling cycle of the wine cellar 1. More specifically, two coolers 36a and 36b are allocated to the upper and lower storage chambers one by one, and the control circuit 11 is The cooling cycle of the storage chamber 2a and the cooling cycle of the lower storage chamber 2b are individually controlled.

  The compressor (compressor) 31 compresses the gas refrigerant to generate and output a high-temperature and high-pressure gas refrigerant. The high-temperature and high-pressure gas refrigerant sent from the compressor 31 is changed into a room-temperature and high-pressure liquid refrigerant while radiating heat with a condenser (condenser) 33. Furthermore, the room-temperature and high-pressure liquid refrigerant is converted into water or the like by an accumulator 34. Foreign matter is removed. Here, for example, when the control is performed so as to lower the temperature in the upper storage chamber 2a, the control circuit 11 performs electromagnetic so that the liquid refrigerant from which foreign substances such as moisture are removed by the accumulator 34 is sent to the capillary tube 35a. The valve 32 is controlled. The liquid refrigerant sent through the electromagnetic valve 32 passes through the capillary tube 35a having a small tube diameter, and thus the pressure is lowered so that the liquid refrigerant is easily evaporated (vaporized). Thereafter, the low-temperature and low-pressure liquid refrigerant is sent to the cooler 36a, where it takes heat from the surrounding air and evaporates (vaporizes), and finally the refrigerant that has become gas in the cooler 36a becomes a compressor. Return to 31. By repeating such a cycle, the periphery of the cooler 36a is cooled.

  On the other hand, when the control is performed so as to lower the temperature in the lower storage chamber 2b, the control circuit 11 controls the electromagnetic valve 32 so that the liquid refrigerant from which foreign substances such as moisture are removed by the accumulator 34 is sent to the capillary tube 35b. Control. The liquid refrigerant sent through the electromagnetic valve 32 passes through the capillary tube 35b having a small tube diameter, and thus the pressure is lowered so that the liquid refrigerant is easily evaporated (vaporized). Thereafter, the low-temperature and low-pressure liquid refrigerant is sent to the cooler 36b, where it takes heat from the surrounding air and evaporates (vaporizes), and finally the refrigerant that has become gas in the cooler 36b becomes a compressor. Return to 31. By repeating such a cycle, the periphery of the cooler 36b is cooled.

  Then, in each storage room, the equipment used in the cooling cycle and the fans 26a, 26b work together to circulate the air cooled by the coolers 36a, 36b, that is, the cold air is sent into each storage room. As a result, the temperature in each storage room can be lowered to the set temperature.

  In the cooling cycle, for convenience of explanation, the control circuit 11 alternately operates the electromagnetic valves 32. However, the present invention is not limited to this, and the cooling cycle of the upper storage chamber 2a and the cooling cycle of the lower storage chamber 2b ( The solenoid valve 32 may be adjusted so that two cooling cycles) are performed simultaneously. In addition, since the wine cellar 1 has a two-stage storage chamber as an example, the configuration is such that the two cooling cycles are switched by controlling the electromagnetic valve 32. For example, the storage chamber is of one type. For the wine cellar 1 (see FIG. 2), since the cooling cycle is one system (for example, the cooling cycle including the compressor 31, the condenser 33, the accumulator 34, the capillary tube 35, and the cooler 36), there is no need for switching. 32 becomes unnecessary. FIG. 5B is a diagram illustrating an example of the cooling cycle of the wine cellar 1 with one type of storage room.

  FIG. 6A is a diagram illustrating an example of the circulation of air in the storage room. Specifically, the state of circulation of air cooled by the cooling cycle and air heated by the heating heater is shown. Yes. FIG. 6B is a schematic diagram illustrating air circulation in the storage room in the wine cellar of the present embodiment. In FIGS. 6A and 6B, 41a is a fin type cooler for the upper storage chamber 2a in which the heating heater 25a and the cooler 36a are integrated, and 41b is the heating heater. It is a fin type cooler for the lower storage chamber 2b in which the heater 25b and the cooler 36b are integrally arranged, and each is arranged in the storage 8 on the back of the back panel 9. In the present embodiment, the control circuit 11 circulates the air in the storage chamber by controlling the suction and discharge by the fans 26a and 26b. Specifically, as shown by the arrows in the drawing, the air in the storage chamber is taken into the storage 8 through the suction vents provided in the lower portion of each storage chamber, and warmed by the fin type coolers 41a and 41b. The air that has been cooled or cooled is discharged into each storage chamber through a discharge vent provided in a slit shape at the top of the back panel 9. Thereby, temperature control to the temperature set by the operation panel 5 becomes possible for every preservation | save room.

  Further, in the present embodiment, the fans 26a and 26b are installed so as to be inclined so that, for example, the taken-in air can be discharged obliquely upward and backward by about 10 degrees (see FIGS. 6-1 and 6-2). ). As a result, the air discharged obliquely upward from the discharge vent is reflected on the upper surface of the storage room and reaches the front surface of the storage room, and even when the wine bottle is stored, the wind is not blocked by the wine bottle. Since the air in the storage room can be circulated efficiently, for example, the temperature can be set in units of 1 ° C. within the range of 0 ° C. to 20 ° C. and further in the temperature range. In addition, it is possible to set a low temperature around 0 ° C. by efficiently circulating the air in the storage room as described above, and it is also possible to cope with a wide set temperature (0 ° C. to 20 ° C., etc.). Not only for wine, but also for long-term and short-term storage of sake, shochu, whiskey, etc., and for storage of beer and other beverages.

  As shown in FIG. 6A, the wine cellar 1 is provided with a plurality of outside air exchange holes 42 on the back surface of the main body (the back surface of the storage 8). As a result, moisture contained in the outside air can be taken into the upper storage chamber 2a and the lower storage chamber 2b via the storage 8 and the back panel 9, and excess water can be discharged outside the storage chamber. Therefore, it is possible to keep the humidity in each storage room at an optimum state. In this embodiment, the fans 26a and 26b are inclined and installed. However, the inclination angle is not limited to this, and the angle is appropriately changed so that the wind is not blocked by the wine bottle. Is possible.

<Temperature control method>
Next, the temperature control method in the storage room in the wine cellar of the present embodiment will be described. Here, as an example, a temperature control method in the storage room will be described using the wine cellar shown in FIG.

  Note that the temperature control method of this embodiment is not limited to the wine cellar 1 shown in FIG. 2, for example, all the wine cellars that can be individually adjusted for each storage room, such as the wine cellar 1 shown in FIG. 1. It is applicable to. That is, for a wine cellar having a plurality of storage rooms, the following temperature control method is executed for each storage room. Moreover, in the wine cellar 1, the following operations are enabled as a premise for realizing the temperature control method in the storage room. For example, the temperature setting control is activated by pressing and holding the upper button on the left side of the current temperature display portion of the operation panel 5 for 3 seconds, and then the temperature of the storage room (for example, 0 ° C. to 20 ° C. ° C) can be changed. The set temperature changed here is overwritten in the memory in the control circuit 11 as needed. In this embodiment, the set temperature can be changed by long-pressing a specific button for 3 seconds. However, the method for changing the set temperature is not limited to this, and any method may be used. .

  Hereinafter, the temperature control method in the storage chamber will be described in detail according to the flowchart. FIG. 7 is a flowchart showing a temperature control method in the storage room. Specifically, FIG. 7-1 is a flowchart showing a cooling function that is a function for realizing the temperature control method of the present embodiment. 7-2 is a flowchart showing a heating function which is a function for realizing the temperature control method of the present embodiment. In the wine cellar 1, it is assumed that the initial value of the set temperature X of the storage room is set to 14 ° C., for example, and that value is stored in advance in the memory in the control circuit 11.

<Cooling function>
The control circuit 11 waits for the ON signal sent from the operation panel 5 (step S1, No), and when the main power ON / OFF button is pressed and the ON signal is received (step S1, Yes). Then, the wine cellar 1 is started and control is started.

  In the operation immediately after the main power supply is turned on, the control circuit 11 first reads the initial value of the set temperature X of the storage room from the memory (step S2), and further calculates the temperature A in the storage room measured by the room temperature sensor 22. Confirm (step S3). Then, the control circuit 11 checks whether the temperature A is (X + 1) ° C. or higher, that is, whether “A ≧ X + 1”. For example, if “A ≧ X + 1” (step S4, Yes, In step S5, Yes, the compressor 31 and the fan 26 are activated to lower the temperature in the storage chamber, and a cooling cycle is started (step S6). Thereafter, the control circuit 11 repeatedly executes the processes of steps S1 to S5, No, steps S10, No (main power ON state) until the temperature A falls below (X + 1) ° C., and continues the cooling cycle. Until the temperature A becomes (X−1) ° C. or lower, that is, while the temperature A is “X + 1> A> X−1”, the above steps S1 to S4, No, Steps S7, No, and Step S10. , No is repeatedly executed to continue the cooling cycle. Thereafter, when the temperature A becomes (X−1) ° C. or lower during the cooling cycle, that is, when “A ≦ X−1” (Step S4, No, Step S7, Yes, Step S8, Yes). ), The control circuit 11 ends the operations of the compressor 31 and the fan 26 (step S9), and ends the cooling cycle.

  On the other hand, in the operation immediately after the main power supply is turned on, after executing the processing of step S2 and step S3, for example, it is confirmed whether or not the temperature A is (X + 1) ° C. or more (step S4), and the temperature A is “X + 1> A > X-1 ”(step S4, No, step S7, No), the control circuit 11 does not start the cooling cycle until the temperature A becomes (X + 1) ° C. or higher in order to maintain the current temperature. After that, as a result of continuing the state in which the cooling cycle is not started, when the temperature A becomes (X + 1) ° C. or higher, that is, when “A ≧ X + 1” (step S4, Yes, step S5, Yes), the control The circuit 11 starts the cooling cycle (step S6), and thereafter repeatedly executes the processing of step S1 to step S10, No as described above. On the other hand, as a result of continuing the state where the cooling cycle is not started, when the temperature A becomes (X-1) ° C. or lower (step S4, No, step S7, Yes, step S8, No), the control circuit 11 The state where the cooling cycle is not started is further continued.

  Further, in the operation immediately after the main power supply is turned on, after the processes of step S2 and step S3 are executed, when the temperature A is (X-1) ° C. or lower (step S4, No, step S7, Yes, step S8, No ), The control circuit 11 does not start the cooling cycle until the temperature A becomes (X + 1) ° C. or higher, as described above. The operation when the state where the cooling cycle is not started is continued is the same as described above.

  In the above description, the starting point of the start and end of the cooling cycle is (X ± 1) ° C., but this is an example and is not limited to this. The temperature that is the starting point for starting and ending the cooling cycle can be changed as appropriate according to the performance required of the wine cellar 1. Further, the air volume when the fan 26 is activated in the cooling cycle may be an air volume appropriately changed by the control circuit 11 based on experience values such as experiments and results, or based on the specifications of the fan 26. The air volume (fixed value) may be used.

<Heating function>
Further, in the operation immediately after the main power supply is turned on, after executing the processing of step S2 and step S3, the control circuit 11 determines whether the temperature A is (X-3) ° C. or lower, that is, “A ≦ X-3”. For example, in the case of “A ≦ X-3” (step S11, Yes, step S12, Yes), the temperature in the storage room is set. Since it is necessary to raise, the heating heater 25 and the fan 26 are started and heating control is started (step S13). Thereafter, the control circuit 11 repeatedly executes the processes of Step S1 to Step S3, Step S11, Yes, Step S12, No, (b), and Step S10, No until the temperature A exceeds (X-3) ° C. Until the temperature A reaches (X−1) ° C. or higher, that is, while the temperature A is “X−3 <A <X−1” The process of S3, step S11, No, step S14, No, (b), step S10, No is repeatedly performed, and heating control is continued. Thereafter, when the temperature A becomes (X-1) ° C. or higher during the heating control, that is, when “A ≧ X−1” (step S11, No, step S14, Yes, step S15, Yes), the control circuit 11 ends the operation of the heating heater 25 and the fan 26 (step S16), and ends the heating control.

  On the other hand, in the operation immediately after the main power is turned on, it is confirmed whether or not the temperature A is equal to or lower than (X-3) ° C. after performing the processing of the above steps S2 and S3 (FIG. 7-2 (a), step S11). When the temperature A is “X−3 <A <X−1” (step S11, No, step S14, No), the control circuit 11 maintains the current temperature, so that the temperature A is (X-3). Do not activate the heating control until it is below ℃. After that, as a result of continuing the state in which the heating control is not started, when the temperature A becomes (X−3) ° C. or lower, that is, when “A ≦ X−3” (step S11, Yes, step S12). , Yes), the control circuit 11 activates the heating control (step S13), and thereafter repeats the processes of step S1 to step S3, step S11 to step S16, (b), and step S10, No as described above. To do. On the other hand, as a result of continuing the state in which the heating control is not started, when the temperature A becomes (X-1) ° C. or higher (step S11, No, step S14, Yes, step S15, No), the control circuit 11 Further, the state where the heating control is not activated is further continued.

  Further, in the operation immediately after the main power is turned on, after the processes of step S2 and step S3 are executed, when the temperature A is (X-1) ° C. or higher (step S11, No, step S14, Yes, step S15, No ), The control circuit 11 does not activate the heating control until the temperature A becomes equal to or lower than (X-3) ° C. as described above. The operation when the state in which the heating control is not activated is continued is the same as described above.

  In the above description, the starting points for starting and ending the heating control are (X-3) ° C. and (X-1) ° C., respectively, but this is an example and is not limited thereto. The temperature that is the starting point for starting and ending the heating control can be appropriately changed according to the performance required of the wine cellar 1. Further, the air volume when the fan 26 is started in the heating control may be an air volume appropriately changed by the control circuit 11 based on experience values such as experiments and results, for example, as in the cooling cycle. Moreover, the air volume (fixed value) based on the specification of the fan 26 may be sufficient.

<Main power off>
When the main power ON / OFF button is pressed and the control circuit 11 receives an OFF signal during execution of the processing related to the cooling function and the heating function (Yes in step S10), the control circuit 11 The operating state of the fan 26 by temperature control is confirmed (step S31). For example, when the cooling cycle is continuing (step S31, Yes), the operations of the compressor 31 and the fan 26 are stopped, the cooling cycle is ended (step S32), and the process returns to step S1. Further, when the heating control is being continued (step S31, Yes), the operation of the heating heater 25 and the fan 26 is stopped, the heating control is ended (step S32), and the process returns to step S1. If none of the confirmation processes in step S31 is in operation (step S31, No), the process returns to step S1 as it is.

<Defrost control method>
Next, a defrosting control method in the wine cellar of the present embodiment will be described. Here, as an example, the defrosting control of the cooler 36 will be described using the wine cellar 1 shown in FIG. In addition to the wine cellar 1 shown in FIG. 2, for example, the wine cellar 1 shown in FIG. 1 can be used for the defrosting control method of this embodiment. It is applicable to. That is, for a wine cellar having a plurality of storage rooms, the following defrosting control method is executed for each cooler provided for each storage room.

<Premise>
In this embodiment, the energization accumulated time Z ₁ that starts counting when the main power is turned on is counted, and the compressor 31 every time the counter value Z ₁ in the control circuit 11 reaches a multiple of 6 hours (h). Is controlled to stop (OFF). In this embodiment, the continuous operation possible time of the compressor 31 (counting starts when the compressor 31 is ON) C (= 3.5 h) is preset, and the counter value Z ₂ in the control circuit 11 is C = 3. When 5h is reached, control is performed to stop (OFF) the compressor 31, and Z ₂ is reset at this point.

  In the present embodiment, the state in which the storage chamber 2 is stably maintained at a set temperature (for example, settable within a range of 0 ° C. to 20 ° C.) is referred to as “steady state”, for example. FIG. 8 is a diagram illustrating the state of the temperature in the storage chamber 2 and the ambient temperature of the cooler 36 in a steady state. In the steady state, ON / OFF of the compressor 31 is repeated every few minutes, that is, the cooling / non-cooling of the cooler is repeated, so that the temperature in the storage chamber 2 is stably maintained at the set temperature. Here, as an example, the set temperature of the storage chamber 2 is set to 0 ° C., and the starting point of the cooling cycle is set to the time when the storage chamber temperature reaches 1 ° C. (corresponding to the comp ON shown), and the starting point of the cooling cycle is ended Is the time when the temperature in the storage room reaches 0 ° C. (corresponding to Comp OFF in the figure). In FIG. 8, ON / OFF control of the compressor 31 is performed in about 10 minutes in order to maintain the set temperature of 0 ° C. (For example, refer to FIG. 7-1 for the control of the compressor 31). Therefore, in this embodiment, it is a rare case that the operation time of the compressor 31 reaches the continuous operation possible time C (= 3.5 h) during operation in a steady state. Examples of the case where the operation time of the compressor 31 reaches the continuous operation possible time C are, for example, when the temperature in the storage chamber 2 is high immediately after the power is turned on, or when the temperature in the storage chamber 2 rises due to the wine in / out operation. , Etc. are assumed.

<Specific examples of defrosting control>
Hereinafter, the defrosting control method of the present embodiment will be described in detail according to the flowchart. FIG. 9 is a flowchart showing the defrosting control method of this embodiment.

In the steady state (see FIG. 8) (9, step S31, No), for example, if the accumulated electrification time Z ₁ has reached a multiple of 6h (step S31, Yes), the control circuit 11, stops the compressor 31 ( (Including the case where the compressor 31 is already in the OFF state when the compressor 31 is OFF), the ambient temperature E of the cooler 36 obtained from the defrosting temperature sensor 24 is checked (step S32). Wine cellar 1 of the present embodiment, the detection of Z ₁ (step S31, Yes) shifts from the normal operation mode to a defrost mode as a starting point, then operation restart of the compressor 31 (ON) at the same time as the normal operation mode from the defrost mode Shall be transferred to. Here, the normal operation mode is an operation mode for maintaining the temperature in the storage chamber 2 at the set temperature by executing temperature control (for example, temperature control shown in FIGS. 7-1 and 7-2). It is. In the present embodiment, as an example, it is assumed that shifts to defrost mode when the accumulated electrification time Z ₁ has reached a multiple of 6h, not limited to this, the counter value Z in the control circuit 11 Similarly, when ₂ reaches C = 3.5 h, the mode is shifted to the defrosting mode. In this embodiment, the timing of Z ₁ is set to a multiple of 6h (every 6 hours) as an example. However, the present invention is not limited to this, but every 30 minutes, every hour, every 2 hours, etc. Arbitrary time can be set. In addition, for example, an operation unit such as a defrosting switch may be provided at a predetermined position of the main body, and, in addition to the above-described periodic timing, the operation may be shifted to the defrosting mode starting from a switch operation.

  As a result of checking the ambient temperature E of the cooler 36 in step S32, if E is 1 ° C. or lower (step S33, Yes), the control circuit 11 activates (ON) the heating heater 25 (step S34), and then The ambient temperature E of the cooler 36 is monitored (Step S35, No, Step S36, No). Defrosting of the cooler 36 is started by the heating heater 25ON. In the present embodiment, the condition for starting the heating heater 25 is “E ≦ 1 ° C.”, but is not limited to this. For example, in consideration of the application and the use environment, frost is generated in the cooler 36. Any value may be used as long as it is defined as a value that may adhere. In addition, conditions such as “E = 2 ° C.” and “E = 3 ° C.” described later are also variable depending on this condition.

  During the monitoring of the ambient temperature E of the cooler 36 in step S35, for example, when E reaches 2 ° C. (step S35, Yes), the control circuit 11 stops the heating heater 25 (OFF) (step S37). Further, the ambient temperature E of the cooler 36 is monitored (No at Step S38). For example, when E reaches 2 ° C., the control circuit 11 determines that the frost attached to the cooler 36 has melted and changed to dew.

  Then, during monitoring of the ambient temperature E of the cooler 36 in step S38, for example, when E reaches 3 ° C. (step S38, Yes), the control circuit 11 restarts (ON) the compressor 31 (step S38). S39), transition from the defrost mode to the normal operation mode. In this embodiment, the time required for E to reach 3 ° C. from 2 ° C. is used as the time for dropping water drops remaining in the cooler 36 as dew. As a result, water drops (dew) remaining in the cooler 36 can be reduced, and further, frost growth can be avoided when the cooler 36 is recooled (when the cooling cycle is restarted). In this embodiment, it is assumed that the ambient temperature E of the cooler 36 increases from 2 ° C. to 3 ° C. However, for example, when the room temperature is very low, the temperature changes from 2 ° C. to 3 ° C. depending on the use environment. Assuming a case where it takes time to rise or a case where the temperature does not rise to 3 ° C, the operating time of the heating heater 25 is limited (for example, 30 minutes), and the temperature does not rise to 3 ° C within the time limit. Alternatively, the compressor 31 may be forcibly restarted (shifted to the normal operation mode).

FIG. 10 is a diagram illustrating an example of defrosting control according to the present embodiment. Specifically, “E ≦ 1 ° C.” is detected in the check in step S32, and then E = 2 ° C. is detected within a predetermined time. It is a figure which shows an example of defrosting control in the case of a case. In FIG. 10, as an example, the set temperature of the storage chamber 2 is set to 0 ° C., and when the storage chamber temperature rises and reaches 1 ° C., the cooling cycle is started (compressor 31 ON), and the storage chamber temperature decreases to 0 ° C. When the temperature reaches 0 ° C., the cooling cycle is terminated (compressor 31 OFF), so that substantially 0 ° C. is stably maintained (steady state). In this state, when Z ₁ reaches a multiple of 6 h, the control circuit 11 shifts to the defrosting mode, stops the compressor 31 and checks the ambient temperature E of the cooler 36. At this point, since E is −8 ° C. (see FIG. 10), the control circuit 11 activates the heating heater 25, and the period until E rises to 2 ° C. Use as time to dissolve. Thereafter, when E = 2 ° C. is detected, the control circuit 11 stops the heating heater 25 and drops the water droplets remaining in the cooler 36 as dew during the period until E rises to 3 ° C. Use as time. When E = 3 ° C. is detected, the control circuit 11 restarts the compressor 31 and shifts to the normal operation mode.

  Further, during the monitoring of the ambient temperature E of the cooler 36 in the process of step S35, for example, when the operating time of the heating heater 25 reaches 30 minutes without E reaching 2 ° C. (step S35, No, step S36, Yes), the control circuit 11 stops the warming heater 25 (OFF), restarts the compressor 31 (ON) (step S40), and shifts from the defrosting mode to the normal operation mode.

FIG. 11 is a diagram illustrating an example of the defrosting control of the present embodiment. Specifically, in the case where the operating time of the heating heater 25 has reached 30 minutes without E reaching 2 ° C. in the monitoring in step S35. It is a figure which shows an example of defrost control. In FIG. 11, the control circuit 11 starts the warming heater 25 and monitors the subsequent E because E is −8 ° C. when Z ₁ reaches a multiple of 6 h (transition to the defrosting mode). Even if the operating time of the heating heater 25 reaches 30 minutes, E does not rise to 2 ° C., so the heating heater 25 is stopped and the compressor 31 is restarted to shift to the normal operation mode.

  On the other hand, as a result of checking the ambient temperature E of the cooler 36 in step S32, if E is higher than 1 ° C. and lower than 3 ° C. (step S33, No, step S41, Yes), that is, “1 ° C. <E < In the case of “3 ° C.”, the control circuit 11 further monitors the ambient temperature E of the cooler 36 without starting the heating heater 25 (No in step S38). Here, when E is in the range of “1 ° C. <E <3 ° C.” in step S32, the control circuit 11 does not start the warming heater 25 but only turns off the compressor 36 (cooling cycle stop). It is judged that defrosting is possible.

  Then, during monitoring of the ambient temperature E of the cooler 36 in step S38, for example, when E reaches 3 ° C. (step S38, Yes), the control circuit 11 restarts (ON) the compressor 31 (step S38). S39), transition from the defrost mode to the normal operation mode.

FIG. 12 is a diagram illustrating an example of defrosting control according to the present embodiment, and more specifically, a diagram illustrating an example of defrosting control when “1 ° C. <E <3 ° C.” is detected in the check in step S32. It is. In FIG. 12, as an example, the set temperature of the storage chamber 2 is set to 5 ° C., and when the storage chamber temperature rises and reaches 6 ° C., the cooling cycle is started (compressor 31 ON). When the temperature reaches 0 ° C., the cooling cycle is terminated (compressor 31 OFF), so that about 5 ° C. is stably maintained (steady state). In this state, when Z ₁ reaches a multiple of 6 h, the control circuit 11 shifts to the defrosting mode, stops the compressor 31 and checks the ambient temperature E of the cooler 36. At this time, since E is 2 ° C. (in the range of “1 ° C. <E <3 ° C.”) (see FIG. 12), the control circuit 11 does not start the heating heater 25 and surrounds the cooler 36. The temperature E is further monitored, and when E = 3 ° C. is detected, the compressor 31 is restarted to shift to the normal operation mode.

On the other hand, as a result of checking the ambient temperature E of the cooler 36 in step S32, if E is 3 ° C. or higher (step S33, No, step S41, No), the control circuit 11 indicates that the cooler 36 has frost. monitoring the counter as well as determined that not adhered (step S42, no), when the accumulated electrification time Z ₁ in the above step S31 has elapsed 5 minutes from the time it reaches the multiple of 6h (step S42, Yes) The compressor 31 is restarted (ON) (step S39), and the defrosting mode is shifted to the normal operation mode. In the above description, the compressor 31 is restarted when 5 minutes have elapsed from when Z ₁ reaches a multiple of 6h. However, the present invention is not limited to this, and the time until restart is, for example, cooling From the viewpoint of suppressing temperature change in the storage chamber by cycle stop (compressor 31 OFF), it is desirable to set the shortest time required for restart based on the specifications of the compressor 31.

FIG. 13 is a diagram illustrating an example of defrosting control according to the present embodiment. Specifically, FIG. 13 is a diagram illustrating an example of defrosting control when “E ≧ 3 ° C.” is detected in the check in step S32. In FIG. 13, as an example, the set temperature of the storage chamber 2 is set to 7 ° C., and when the storage chamber temperature rises and reaches 8 ° C., the cooling cycle is started (compressor 31 ON). When the temperature reaches 0 ° C., the cooling cycle is terminated (compressor 31 OFF), so that the temperature is stably maintained at about 7 ° C. (steady state). In this state, when Z ₁ reaches a multiple of 6 h, the control circuit 11 shifts to the defrosting mode, stops the compressor 31 and checks the ambient temperature E of the cooler 36. At this time, since E is 4 ° C. (“E ≧ 3 ° C.”) (see FIG. 13), the control circuit 11 monitors the counter without starting the heating heater 25, and Z ₁ is a multiple of 6h. When 5 minutes have elapsed from when the temperature reached, the compressor 31 is restarted regardless of the value of the ambient temperature E of the cooler 36 to shift to the normal operation mode.

  As described above, the wine cellar according to the present embodiment employs the compressor method as the cooling method. For example, the defrosting temperature sensor 24 that is disposed in the vicinity of the cooler 36 and detects the ambient temperature E of the cooler 36, and the cooler 36. A heater 25 for raising the ambient temperature E to melt the frost adhered to it, and when the predetermined timing is reached, the compressor 31 is stopped and the ambient temperature E detected by the defrost temperature sensor 24 is checked. And a control circuit 11 for determining whether or not to activate the heater 25 based on the above. Thereby, in a wine cellar that can operate at a storage room temperature setting that does not cause frost to adhere to the cooler, it is determined whether or not frost is attached to the cooler, so that useless defrosting operation can be avoided. It becomes possible. That is, the optimum defrosting operation according to the use environment is possible.

  Further, in this embodiment, after the heating heater 25 is stopped in the above step S37, the time until the ambient temperature E of the cooler 36 reaches 2 ° C. to 3 ° C. is used as dew. It was decided to use it as time to drop. As a result, water droplets (dew) remaining in the cooler 36 can be reduced, so that the growth of frost when the cooler 36 is restarted can be suppressed, and as a result, the growth of frost in a long-time operation is minimized. It becomes possible to suppress to.

DESCRIPTION OF SYMBOLS 1 Wine cellar 2 Storage room 2a Upper storage room 2b Lower storage room 3 Partition plate 4 Glass door 5 Operation panel 6 Storage 7 Shelf board 8 Storage 9 Back panel 11 Control circuit 21, 21a, 21b LED
22, 22a, 22b Indoor temperature sensor 24, 24a, 24b Defrost temperature sensor 25, 25a, 25b Heating heater 26, 26a, 26b Fan 31 Compressor 32 Solenoid valve (three-way valve)
33 Condenser
34 Accumulator 35, 35a, 35b Capillary tube 36, 36a, 36b Cooler 41a, 41b Fin type cooler 42 Outside air exchange hole

Claims (8)

In the wine cellar that adopts a cooling method using a compressor and has a defrosting function that melts frost attached to the cooler by the cooling cycle,
A temperature sensor disposed in the vicinity of the cooler for detecting the ambient temperature of the cooler;
A heating heater that raises the ambient temperature of the cooler to melt the frost adhering to the cooler;
When the predetermined timing is reached, the compressor is stopped and the ambient temperature of the cooler detected by the temperature sensor is checked, and it is determined whether to start the heating heater based on the ambient temperature of the cooler. A control unit,
With
The controller is
When the temperature around the cooler detected by the temperature sensor at the predetermined timing is equal to or lower than the “first temperature” defined as a temperature at which frost may adhere to the cooler, the warming heater Start
When the ambient temperature of the cooler after starting the warming heater reaches the “second temperature (“ first temperature ”<“ second temperature ”)”, the warming heater is stopped,
Further, when the ambient temperature of the cooler after the heating heater is stopped reaches the “third temperature (“ second temperature ”<“ third temperature ”)”, the compressor is restarted.
Features and to Ruwa Insera that. The controller is
When the ambient temperature of the cooler detected by the temperature sensor at the predetermined timing is higher than the “first temperature” and lower than the “third temperature”, the cooler is further started without starting the heating heater. Monitor the ambient temperature,
Then, when the ambient temperature of the cooler reaches the “third temperature”, the compressor is restarted.
The wine cellar according to claim 1 . When the cooler ambient temperature detected by the temperature sensor at the predetermined timing is equal to or higher than the “third temperature”, the control unit determines that frost is not attached to the cooler, and the predetermined timing. Restart the compressor after a certain period of time from
The wine cellar according to claim 2 . The predetermined timing is one or both of a predetermined regular timing, a timing when the compressor can be continuously operated,
The wine cellar according to claim 1 , 2 or 3 . A defrosting control method in a wine cellar that employs a cooling method using a compressor and has a defrosting function for melting frost attached to the cooler by a cooling cycle,
The wine cellar is arranged in the vicinity of the cooler and detects a temperature around the cooler; a heating heater that raises the cooler ambient temperature in order to melt frost attached to the cooler; and the cooler And a control unit that performs control for melting frost attached to the
As the processing of the control unit,
A temperature confirmation step of stopping the compressor and checking the cooler ambient temperature detected by the temperature sensor when a predetermined timing is reached;
Defrosting control step for determining whether to start the heating heater based on the ambient temperature of the cooler obtained as the check result;
Including
In the defrosting control step,
When the temperature around the cooler detected by the temperature sensor at the predetermined timing is equal to or lower than the “first temperature” defined as a temperature at which frost may adhere to the cooler, the warming heater Start
When the ambient temperature of the cooler after starting the warming heater reaches the “second temperature (“ first temperature ”<“ second temperature ”)”, the warming heater is stopped,
Further, when the ambient temperature of the cooler after the heating heater is stopped reaches the “third temperature (“ second temperature ”<“ third temperature ”)”, the compressor is restarted.
Defrost control how to characterized in that. In the defrosting control step,
When the ambient temperature of the cooler detected by the temperature sensor at the predetermined timing is higher than the “first temperature” and lower than the “third temperature”, the cooler is further started without starting the heating heater. Monitor the ambient temperature,
Then, when the ambient temperature of the cooler reaches the “third temperature”, the compressor is restarted.
The defrosting control method according to claim 5 , wherein: In the defrosting control step,
When the ambient temperature of the cooler detected by the temperature sensor at the predetermined timing is equal to or higher than the “third temperature”, it is determined that no frost is attached to the cooler, and the predetermined timing is reached. Restart the compressor after a certain time from
The defrosting control method according to claim 6 . The predetermined timing is one or both of a predetermined regular timing, a timing when the compressor can be continuously operated,
The defrosting control method according to claim 5, 6, or 7 .

Images