JP4840469B2 - Supercooling control refrigerator - Google Patents

Description

  The present invention relates to a supercooling control refrigerator for temporarily keeping the temperature in a refrigerator for storing and storing fresh food or the like in a supercooled state below a freezing point and promoting the long-term storage of food and the deliciousness of food. About.

  In recent years, in order to preserve fresh foods such as fruits and vegetables, meat and seafood, or processed foods such as tofu, ham, and kamaboko in a refrigerated condition, it is preferable to store them at a temperature that is as low as possible without freezing and at a humidity that is as high as possible without condensation. High humidity technology and soaking technology have been developed. As a typical operation method, there is a method by wall surface cooling. Wall cooling means cooling the wall surface in the refrigerator to around -3 ° C to 3 ° C with the cold air flowing around it, and improving the airtightness in the refrigerator by attaching a door to make the inside of the refrigerator uniformly in the range of 0-5 ° C. While cooling, it captures the moisture that enters by opening and closing the door, thereby increasing the humidity. Natural cooling from the 4th or 5th wall without leakage or entry of cold air, the refrigerator can be cooled uniformly and reliably, and even if the inside temperature is cooled to 0 ° C, the temperature inside the refrigerator There is little unevenness and there is little freezing partially.

  However, in order to cool uniformly, there is a limit to the storage capacity, and as the storage capacity increases, the ratio of the cooling area decreases, and the distance between the cooled wall and the cold insulation product increases, and the storage capacity increases. The food placed in the central part takes time until it becomes uniform, and the cooling speed becomes very slow. In other words, although there are few problems in keeping cold things or keeping them cold for a long time, the doors are frequently opened and closed like household refrigerators, and foods and soft drinks that are kept at room temperature It takes time to put in and out beer, etc., and cool those cold-reserved products from room temperature to an appropriate temperature, which significantly reduces the commercial value.

  Therefore, in order to increase the cooling rate in the refrigerator, the refrigerant passes through the compressor, the condenser, the throttle valve, the evaporator, and returns to the compressor again. The cold air cooled by the evaporator is cooled in the refrigerator with a cold air circulation fan. An indirect cooling method in which the inside of the refrigerator is cooled by a cooling mechanism that discharges to the inside is preferable.

  However, in this method, cold air having a temperature lower than the set temperature in the cabinet is blown, and in order to adjust to the set temperature in the cabinet, cold air is blown in conjunction with the cold air circulation fan, the compressor, and the temperature detector in the cabinet. Intermittent operation is required. That is, the product temperature curve repeats up-and-down fluctuations as shown in the graph of changes in the set temperature in the refrigerator and the product temperature in FIG.

  In addition, there is a place where cold air does not rotate in the stagnant part in the refrigerator and the cooling is insufficient, and there is a spot that is supercooled in the vicinity of the cold air outlet. As a result, large temperature unevenness occurs in the refrigerator. In consideration of this temperature unevenness, it was necessary to keep the entire set temperature high so that the food does not freeze in places where the temperature is low or in temperature fluctuations. In particular, when fresh vegetables and fruits are frozen, the moisture in the cells is frozen, and the cells are destroyed by expansion due to freezing. Therefore, storage at a temperature considerably higher than the optimum storage conditions for fresh foods is unavoidable in a refrigerator, and it has been very difficult to maintain freshness.

  There is a method to reduce the amount of cool air that flows by reducing the opening and closing of the damper to equalize the temperature with the indirect cooling method, but if the refrigerator capacity is small, it can achieve considerable temperature equalization, but the capacity is similar to wall cooling As the value increases, the temperature unevenness increases.

Furthermore, in such a cooling method, since it passes through the very low evaporator surface, dehumidification is performed on the evaporator surface, and the cold air blown out has a low relative humidity, which promotes drying of the food that is a cold insulator.

  As a solution to the above problem, Patent Document 1 (Japanese Patent Application Laid-Open No. 10-318645) includes a refrigerator consisting of a refrigerator compartment and a vegetable compartment and a freezer in different temperature zones. The rotation speed of the circulation fan and variable capacity compressor is set, and each cool air circulation fan can change the rotation speed according to the output of the temperature sensor, which is the internal temperature detection mechanism, and adjust the temperature of each target temperature chamber Thus, the air volume can be adjusted in order to eliminate a large temperature difference between the set temperature in the refrigerator and the cool air temperature fed by the cool air circulation fan.

  In recent household refrigerator-freezers, a refrigeration evaporator and a refrigeration evaporator are connected in parallel, the evaporation temperature in the refrigeration evaporator is increased, the surface temperature of the evaporator is set higher, and the dehumidification effect is lowered. When the compressor is stopped, a mechanism is installed to humidify the refrigerator by operating only the cold air circulation fan for the frost on the evaporator inside the refrigerator.

  In Patent Document 2 (Japanese Patent Laid-Open No. 8-247608), the cold air cooled by the cooler passes through the cold air guide passage and is supplied into the refrigerator cabinet, but a rotating cold air discharge member is provided at the cold air discharge port. It is devised to cool the inside of the refrigerator uniformly by distributing the cold air from side to side.

Patent Document 3 (Japanese Patent Laid-Open No. 7-115952) describes a method for imparting stress to a living body to improve umami. In other words, give breathing organisms such as vegetables, fruits, cereals, live fish, shellfish, etc., stress treatment by drying, hydration, pressure, light, snow, sound waves, etc. in a low temperature zone below 0 ° C. It is described that it can secrete various umami-related components into the living body, fully immature things can be fully ripe, things that are not originally seasonal taste can be improved to seasonal taste, and further taste can be improved. As a natural phenomenon that proves its effect, there is an increase in the sweetness of Chinese cabbage when frost falls.
JP-A-10-318645 JP-A-8-247608 Japanese Patent Laid-Open No. 7-115952

  However, as disclosed in Patent Document 1 (Japanese Patent Laid-Open No. 10-318645), a cold air circulation fan corresponding to each cooling temperature is provided, and the number of rotations is set in accordance with the refrigeration temperature zone with a variable capacity compressor. When the target temperature can be adjusted by changing the number of rotations of the fan according to the output of the temperature sensor, the rotating cold air discharge member of the cold air discharge port is disclosed in Patent Document 2 (Japanese Patent Laid-Open No. 8-247608). Even if the cold air is dispersed to the left and right to cool the inside of the refrigerator uniformly, the food cannot be stored in a supercooled state as shown in Patent Document 3 (Japanese Patent Laid-Open No. 7-115952), When the temperature setting is lowered, the food freezes in a part of the cabinet, cells are destroyed, and the taste of the food is lowered.

  In addition, even if stress treatment with drying, hydration, pressure, light, snow, sound waves, etc. is applied in a low temperature zone of 0 ° C. or lower, it is impossible to keep the temperature constant for a long time in a home refrigerator. When ice nuclei are formed by stimulation, freezing starts and the cells of the fresh food are destroyed.

  Accordingly, an object of the present invention is to provide a supercooling control refrigerator that can extract the taste of the fresh food, promote ripening, and suppress evaporation of vegetables and the like.

In order to achieve the above object, the present invention provides a heat insulating box having a door that can be opened and closed, a cooling means for cooling the inside of the box formed by the heat insulating box, and the inside of the box at a predetermined temperature set value. Control means for controlling, and the control means controls to operate in a supercooling temperature zone which is a temperature set value below the freezing point of the cold-reserved product stored in the storage.

  In the present invention, the cold-insulated product temporarily falls below the freezing point, but the freezing does not proceed immediately, so the supercooled state is maintained. Moreover, even if freezing is started, the freezing does not proceed easily because it requires heat of solidification, and the effect of promoting the ripening is exhibited by drawing out the taste of fresh food in a supercooled state.

The invention described in claim 1 is a heat insulating box having a door that can be opened and closed, a cooling means for cooling the inside of the box formed by the heat insulating box, and a control means for controlling the inside of the box to a predetermined temperature set value. And the cooling means includes a variable capacity cold air circulation fan and a variable capacity compressor, and is in a supercooling temperature zone that is a temperature set value that is equal to or lower than a freezing point of the cold insulation product stored in the storage. When the control means controls to operate, and the internal temperature changes due to the change of the outside air temperature or the opening and closing of the door by the control means, the rotation speed of the variable capacity compressor depends on the internal temperature. Although controlled, when operating in the supercooling temperature zone, the variable capacity cold air circulation fan is controlled differently from the variable capacity compressor so as to have a constant air volume. Temporarily keep the cool product below the freezing point. Monono freezing to proceed becomes no supercooled state immediately, nor easily to complete the freeze in the order that requires heat of solidification even freezing is initiated.

  In addition, fresh food in a supercooled state produces an effect as shown in Japanese Patent Laid-Open No. 7-115952, and draws out the taste of fresh food to promote ripening. In addition, in vegetables and the like, the pores contract and water evaporation is reduced.

  The invention according to claim 2 is provided with a duct provided with a plurality of outlets for circulating the cool air cooled by the evaporator into the inside of the cabinet, so that the temperature of the cold air discharged from the outlet is as close as possible to the inside temperature. The supercooling control operation can be performed reliably by making the temperature in the refrigerator uniform without being affected by the amount of storage in the refrigerator.

  According to a third aspect of the present invention, there is provided a temperature detection means for detecting the temperature in the warehouse, and the supercooling operation is performed so that the interior of the warehouse is controlled to a predetermined temperature set value by interlocking the cooling means and the temperature detection means. Thus, the temperature inside the refrigerator can be made uniform and the supercooling control operation can be performed reliably.

According to a fourth aspect of the present invention, the variable capacity cold air circulation fan is operated in conjunction with the temperature detection means so as to control the inside of the refrigerator to a predetermined temperature set value when the fan is not operated in the supercooling temperature zone. By controlling the number of rotations of the cold air circulation fan , the cooling means and the temperature detection means are linked to perform a supercooling operation so that the inside of the refrigerator is controlled to a predetermined temperature setting value, thereby making the temperature inside the refrigerator uniform. It is possible to reliably perform supercooling control operation .

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

(Embodiment 1)
FIG. 1 is a cross-sectional view showing the internal structure of the supercooling control refrigerator according to Embodiment 1 of the present invention. In FIG. 1, reference numeral 1 denotes a heat insulating box of the refrigerator 3, which has a structure in which a heat insulating material is provided inside the exterior panel 5. Inside the heat insulating box 1, the refrigerator compartment 9, the vegetable compartment 11, the first freezer compartment 13, and the second freezer compartment 15 are configured in multiple stages from above, and the refrigerator compartment 9, the vegetable compartment 11, the first freezer compartment 13, The second freezer compartment 15 is provided with opening / closing doors 17, 18, 19, and 20, respectively, and the opening and closing of the opening / closing doors 17, 18, 19, and 20 allows the food and other cold insulation products 21 to be taken in and out.

  A space between the vegetable compartment 11 and the first freezer compartment 13 is divided into upper and lower parts independently by a heat insulating wall 22 into a refrigerator 23 and a freezer 25 having different set temperatures.

The refrigerator interior 23 is composed of a refrigerator compartment 9 and a vegetable compartment 11, and the refrigerator compartment 9 and the vegetable compartment 11 are partitioned up and down by a partition plate 27 so that cold air circulates. Since the partition plate 27 circulates cold air at the same temperature, no heat insulating material is required, and the partition plate 27 is formed of the same material as the removable shelf 29 and the storage container 31 provided in the refrigerator compartment 9, and has a small occupied space. It is set so that it can be used.

In the first evaporator 33, the heat exchanged cold air is sent forward by the first variable capacity cold air circulation fan 35 to the front side of the open / close door 17, and then flows through the refrigerator compartment 9 and the vegetable compartment 11 as indicated by arrows. By repeating the circulation from the cold air flow path 41 at the rear to the first evaporator 33 again, it is set so that an appropriate refrigerator temperature can be obtained.
The cold air flow path 41 is formed by notching a part of the rear surface of the shelf and providing an opening 43 through the refrigerator 9 to the vegetable compartment 11 on the front side.

  The refrigerator 25 includes a first freezer compartment 13 and a second freezer compartment 15, and is partitioned vertically by a partition plate 49 so that cold air circulates. The partition plate 49 does not require a heat insulating material since cold air of the same temperature circulates, and is formed thin with the same member as the storage container 51 provided in the warehouse. One of the cold air exchanged heat in the second evaporator 53 is fed into the first freezer compartment 13 from the cold air flow passage 61 of the partition plate 49 by the second variable capacity cold air circulation fan 55, and the other is connected to the corner wall 63. It is sent to the second freezer compartment 15 from between the partition plates 49. In addition, the cold air that has passed through the first freezer compartment 13 merges in the second freezer compartment 15 through a communication hole 65 formed in front of the partition plate 49 that goes out to the second freezer compartment 15, and the second freezer compartment It is set so that a freezer temperature of −15 ° C. or less can be obtained by repeating circulation through the gap between the 15 storage containers 51 and the refrigerator bottom wall 66 and returning to the second evaporator 53 again.

  The machine room 67 provided at the lowermost part of the heat insulating box 1 is provided with a variable capacity compressor 69 and a condenser 71, a three-way valve 72, a first throttle valve 73, and a second throttle valve 74. In addition to the first evaporator 33, the first variable capacity cold air circulation fan 35, the second evaporator 53, and the second variable capacity cold air circulation fan 55 described above, the cooling mechanism 77 including the refrigeration cycle shown in FIG. (Cooling means) is configured.

  That is, in the refrigeration cycle shown in FIG. 2, the first evaporator 33 and the second evaporator 53 are connected in parallel, and the refrigerant discharged from the compressor 69 is passed in two directions by the condenser 71 and the three-way valve 72. One is passed from the first throttle valve 73 to the first evaporator 33, and the other is passed through the second throttle valve 74 in the order of the second evaporator 53, and again. A refrigeration cycle 78 returning to the compressor 69 is configured.

  In the refrigerator configured as described above, the variable capacity compressor 69 is provided with a temperature detection mechanism 79 (temperature detection means) of the refrigerator 23 in the refrigerator 23 constituting each temperature zone space. 25 is provided with a temperature detection mechanism 81 for the inside of the freezer 25, and the number of rotations is set in accordance with the temperature zone of either the refrigerator 23 or the freezer 25 according to the output and the set temperature. The first and second variable capacity cold air circulation fans 35 and 55 adjust the temperature of the refrigerator 23 and the freezer 25 by variably controlling the number of rotations according to the output of the internal temperature detection mechanisms 79 and 81. Can be performed respectively.

  The temperature setting in the refrigerator 23 is set by the control device 83 for the exterior panel of the heat insulation box 1, and can be set to two temperatures, a refrigeration temperature value and a supercooling temperature value, which are bordered by the freezing temperature of the food. It is.

The specific value used in the first embodiment is that the first freezer compartment 13 and the second freezer compartment 15 are set to −18 to −20 ° C. as the freezing temperature, and the temperature in the refrigerator 23 of the refrigerator compartment 9 and the vegetable compartment 11 is set. Is set to a refrigeration temperature value of 3 ° C and a supercooling temperature value of -5 ° C. In the freezer 25, the cold air that has passed through the second evaporator 53 by driving the second variable capacity cold air circulation fan 55 is supplied to the first freezer compartment 13 and the second freezer compartment 15 as described above. The number of rotations of the second cool air circulation fan 55 is controlled so that the temperature of the blown air becomes −24 ° C.

  Further, the temperature detection mechanism 79 and the cooling mechanism 77 are linked by a control device 83 (control means) to control the temperature in the refrigerator 23. That is, the inside of the refrigerator 23 is initially maintained at 3 ° C., but the inside of the refrigerator 23 in the control device 83 is detected by detecting the opening / closing of the door 17 of the refrigerator or the door 18 of the vegetable room by a detecting means (not shown). The set temperature is switched to −5 ° C., and the supercooling operation is started. The supercooling setting operation is detected to be −5 ° C., and is completed when about 10 minutes have passed by the timer 85 in the control device 83, and then the normal cooling operation at 3 ° C. is switched again. In addition, the counter 87 that counts the number of notches based on 3 ° C. in the refrigerator starting from the time of switching to the refrigeration operation in the control device 83 causes the excess of −5 ° C. again after the count number has passed twice. The cooling operation is set to start. Therefore, after 10 minutes, the normal operation is resumed at 3 ° C. That is, when the door is opened or closed or the timing of whether the notch count indicates 2 is reached, the above operation is repeated.

  Since the temperature of the first evaporator 33 is directly connected to the second throttle valve 73 and the evaporator 53 shown in FIG. 2, the evaporation temperature can be freely set by the throttle valve 73. In the present embodiment, The temperature was set to −10 ° C. Therefore, the rotational speed of the first variable capacity cold air circulation fan 35 is controlled so that the cold air ejection temperature is about −5 ° C. Further, when the temperature inside the cabinet changes due to a change in the outside air temperature or the opening / closing of the door, the rotation speed of the variable capacity compressor 69 is controlled according to the temperature inside the warehouse, but the variable capacity cold air circulation fan during the supercooling setting operation. The maximum air volume was set to 35.

  When the temperature of the second evaporator 53 changes, the temperature of the first evaporator 33 also changes, but the rotational speed of the first cold air circulation fan 35 so that the cold air blowing temperature to the refrigerator compartment 9 becomes the set temperature. And the temperature in the refrigerator 23 can be maintained. Even if the compressor is stopped, the first cool air circulation fan 35 continues to rotate until a predetermined time comes, and humidifies the inside 23 of the refrigerator with frost on the surface of the first evaporator 33.

  With reference to the flowchart centering on temperature control in the refrigerator shown in FIG. 3, the normal operation operation of the refrigerator and the operation operation at the time of switching to the supercooling setting operation according to the first embodiment of the present invention will be described.

  The refrigerator 3 is powered on and the variable capacity compressor 69 and the first and second variable capacity cold air circulation fans 35 operate (step 320). Then, it is checked whether or not the temperature in the refrigerator is 3 ° C. or higher (step 330). If it is 3 ° C. or higher, the procedure returns to step 320 and the same operation is repeated. When the temperature is 3 ° C. or lower, the compressor 69 is turned off (step 350). At this time, the circulation fan 35 is kept ON for a predetermined time, the frost attached to the first evaporator 33 is melted, and the inside of the refrigerator 23 is humidified.

  Next, the internal temperature of the refrigerator 23 is checked again (step 360). If it is 3 ° C or higher, the counter 87 is counted once, and if the integrated count is 2 or less, the process goes to step 320. Turn on the return compressor. If the refrigerator temperature is 3 ° C. or lower in step 360, the compressor 69 is kept stopped. When the steps from step 320 to step 360 are repeated and the count number becomes 2 or more, the supercooling operation (step 380) is started. That is, the compressor 69 and the cold air circulation fan are operated at the maximum capacity (step 390), and the temperature in the refrigerator is cooled to -5 ° C.

In step 400, if the temperature in the refrigerator is −5 ° C. or higher, the compressor 69 and the circulation fan 35 are used.
Keeps the operating state, and if it becomes -5 ° C. or lower, the timer check (step 410) starts. That is, the elapsed time of the timer that measures the time since the start of the supercooling operation is checked. If it is within 10 minutes, the operation is continued until 10 minutes, and if 10 minutes have elapsed, the process returns to step 360. Repeat the same operation.

  Further, when a door open / close signal is input, the supercooling operation is forcibly started.

  The reason for setting the timer to 10 minutes is that, in this embodiment, two wet filter papers are placed on the glass plate as a simulated load in the refrigerator 23, and the value of the thermometer sandwiched between the two filter papers is set. Calculated based on the result of an experiment in which the unit time required for the surface temperature of the refrigerated product to decrease by 1K in the refrigerated temperature range was 30 seconds when the surface temperature of the refrigerated product was used. The operating time is set to be shorter than 80 times the unit time to avoid freezing of the food surface. That is, in calculation, if it is within about 40 minutes, it does not freeze, but in the present embodiment, it is set to 10 minutes in the present embodiment, and is not necessarily restricted to 10 minutes.

  The reason why the number of counts is set to two is to eliminate partial freezing during the supercooling operation by continuing the operation at 3 ° C for a while, and there is no problem if the refrigeration operation at 3 ° C is performed once or more.

  FIG. 4 is a graph plotting the 23 set temperature in the refrigerator and the change in the product temperature in the first embodiment, but the product temperature of foods such as Chinese cabbage and cabbage is preserved without freezing even when the product temperature is 0 ° C. or less. It was confirmed. In addition, it has been confirmed that foods having a temperature of 0 ° C. or lower as described above are matured and become tasty. In particular, leaf vegetables close in the pores and evaporate initially, but when the temperature stabilizes, the amount of evaporation decreases. .

  Further, since the variable speed compressor 69 and the first and second cold air circulation fans 35 and 55 can be used to change the rotation speed according to the temperature conditions in the refrigerator 23 and the freezer 25, the temperature fluctuation in the refrigerator Therefore, optimal control suitable for the set temperature of each target temperature can be performed, and power saving can be measured.

(Embodiment 2)
FIG. 5 is a cross-sectional view showing the internal structure of the supercooling control refrigerator in Embodiment 2 of the present invention. Note that the same components as those in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

  In FIG. 5, in the first evaporator 33, the heat exchanged cold air is opened and closed by multi-ducts 90 and 92 provided with a plurality of outlets (described later) by the first variable capacity cold air circulation fan 35. 17 is carried forward, discharged from the outlets 94 and 96 into the refrigerator 23, flows through the refrigerator compartment 9 and the vegetable compartment 11 as shown by the arrows, and again passes from the rear cool air passage 41 to the first evaporator 33. It is set so that an appropriate refrigerator temperature can be obtained by repeating the return circulation. The cold air flow path 41 is formed by notching a part of the rear surface of the shelf and providing an opening 43 through the refrigerator 9 to the vegetable compartment 11 on the front side.

  The top surface multi-duct 90 and the side surface multi-duct 92 have the function of carrying the cold air to the vicinity of the door regardless of the size of the storage of the cold storage product in the cabinet, and are cooled to a uniform temperature throughout the room. It can be avoided from spot cooling of cold air, and local freezing can be prevented.

As described above, the present invention comprises a heat insulating box having a door that can be opened and closed, a cooling means for cooling the inside of the heat insulating box, a temperature detecting means for detecting the temperature in the refrigerator of the heat insulating box, The cooling means and the temperature detection means are interlocked to have a control means for controlling the interior to a predetermined temperature set value. Normally, the temperature set value in the refrigerator of the heat insulation box is frozen for the stored cold storage product. It is operated in a refrigerated temperature zone above the point, and is operated in a supercooling temperature zone that is a temperature setting value below the freezing point of the cold insulation product for a predetermined time during the supercooling operation, and is characterized by storing the cold insulation product, Temporarily keep the cooled product below the freezing point, but it will not freeze immediately, so keep it supercooled. Moreover, even if freezing is started, the freezing does not proceed easily because it requires heat of solidification, and the effect of promoting the ripening is exhibited by drawing out the taste of fresh food in a supercooled state. Furthermore, in vegetables and the like, the pores contract and the evaporation of moisture is reduced.

  In addition, when the frozen product is food such as fruits and vegetables, fresh vegetables, cereals, nuts, seafood, meats, pastes, etc., by setting the freezing point to 0 ° C., the freezing point of water, Regardless of the moisture content, it becomes a supercooled control refrigerator that can handle all foods.

  In addition, by detecting the time when the open door is closed by the detection means and starting the supercooling operation, the inside of the refrigerator that has risen due to the opening and closing of the door is lowered at a stretch, and a new cold insulation product is quickly put into the supercooling operation. It effectively confers a freshness-keeping effect and an aging effect on cold-preserved products.

  Also, after finishing the operation in the supercooling temperature zone, when the operation and stop of the cooling means by the temperature set value in the normal refrigeration operation is repeated one or more times, it is set as the start timing of the supercooling operation, Even if foods that have started to freeze locally appear, they can be thawed by performing a cycle in a normal refrigeration operation even once to reliably prevent freezing.

  In addition, when two wet filter papers are placed on a glass plate and the value of the thermometer sandwiched between the two filter papers is the surface temperature of the cold insulation product, the surface temperature of the cold insulation product in the refrigeration temperature zone is 1K. By making the predetermined operation time in the supercooling temperature zone shorter than 80 times the unit time with respect to the unit time required for the decrease, the supercooling operation is performed until the amount of heat of solidification heat is consumed by cooling. By stopping, it is possible to prevent intracellular destruction due to complete freezing.

  In addition, a refrigeration cycle in which the refrigerant passes through the compressor, the condenser, the throttle valve, and the evaporator and returns to the compressor again, and the multi-duct and the cold air that circulates the cold air cooled by the evaporator uniformly in the refrigerator of the heat insulating box. By having a cooling means composed of a circulation fan, the temperature of the discharged cold air is brought as close as possible to the inside temperature, and the temperature inside the refrigerator is made uniform without being affected by the amount of storage in the refrigerator, thereby ensuring supercooling control operation. Can be done.

  Also, the capacity of the cold air circulation fan is variable, and it has a rotation speed control means for controlling the rotation speed of the cold air circulation fan by the temperature detection means. During supercooling operation, the air volume is increased and the supercooling state is made as soon as possible. It is intended to prevent drying and promote aging.

  As described above, the present invention can be applied to a refrigerator that is provided with a cooling means and that keeps and stores fresh food products.

Sectional drawing which shows the internal structure of the supercooling control refrigerator in Embodiment 1 of this invention Refrigerant circuit diagram in Embodiment 1 of the present invention The flowchart which shows the basic operation | movement in Embodiment 1 of this invention. Characteristic chart showing temperature set value in refrigerator and product temperature in Embodiment 1 of the present invention Sectional drawing which shows the internal structure of the supercooling control refrigerator in Embodiment 2 of this invention. Characteristic diagram showing changes in the conventional refrigerator temperature setting value and product temperature

DESCRIPTION OF SYMBOLS 1 Heat insulation box 3 Refrigerator 17,18 Door 21 Cold storage product 23 Inside of refrigerator 33 Evaporator 35 1st cold air circulation fan 55 2nd cold air circulation fan 69 Compressor 71 Condenser 73, 74 Restriction valve 77 Cooling mechanism (cooling means) )
78 Refrigeration cycle 79 Temperature detection mechanism (temperature detection means)
81 Temperature detection mechanism 83 Control device (control means)
90,92 Multi-duct

Claims (4)

Has a heat-insulating main body having an openable door, a cooling means for cooling the inside of the refrigerator, which is formed by the heat-insulating main body, and control means for controlling the said chamber to a predetermined temperature set point, the cooling means Has at least a variable capacity cold air circulation fan and a variable capacity compressor, and the control means is operated so as to operate in a supercooling temperature zone that is a temperature set value that is equal to or lower than the freezing point of the cold-reserved product stored in the storage. When the internal temperature changes due to a change in the outside air temperature or the opening and closing of the door, the rotational speed of the variable capacity compressor is controlled according to the internal temperature. When operating in a cooling temperature zone, the supercooling control refrigerator is controlled differently from the variable capacity compressor so that the variable capacity cold air circulation fan has a constant air volume . The supercooling control refrigerator of Claim 1 provided with the duct which provided the several blower outlet which circulates the cold air cooled with the evaporator in the store | warehouse | chamber. The supercooling according to claim 1, further comprising a temperature detection unit that detects a temperature in the chamber, wherein the cooling unit and the temperature detection unit are interlocked to perform operation so as to control the interior to a predetermined temperature set value. Control refrigerator. The variable capacity cold air circulation fan controls the number of rotations of the cold air circulation fan so as to control the inside of the cabinet to a predetermined temperature setting value in conjunction with the temperature detection means in cases other than the operation in the supercooling temperature zone. supercooling refrigerator according to claim 1, 3 one paragraph or to.