JP4286106B2 - Freezer refrigerator - Google Patents

Description

The present invention relates to a cold freezing refrigerator.

The commercial refrigerator-freezer is divided into a freezer compartment and a refrigerator compartment by dividing the inside of the main body made of a heat insulation box by a heat insulation wall. The freezer compartment is cooled to about -20 ° C and the refrigerator compartment is cooled to about 5 ° C. . Here, for example, in a domestic refrigerator-freezer, a cooling system is adopted in which a single cooling unit is provided and a part of the cold air circulating in the freezer compartment is distributed to the refrigerator compartment. In particular, when the volume of the refrigeration chamber is large, the inefficiency becomes remarkable. Therefore, cooling units are separately prepared and mounted for refrigeration and freezing (see, for example, Patent Document 1).
No. 8-7337

On the other hand, if two types of cooling units for refrigeration and refrigeration can be used in common as described above, it will be possible to significantly reduce the labor required for design, production, management, etc. Could not be realized.
That is, when a capillary tube is used for the expansion mechanism, it cannot be simply made common for refrigeration and freezing. Specifically, the capillary tube for refrigeration is mainly intended to flow a high flow rate particularly in a region where the evaporation temperature of the refrigerant is high. The main purpose of the capillary tube for refrigeration is to keep the low pressure low in a region where the evaporation temperature is low, by narrowing the flow rate. This is because, for refrigeration and freezing, flow characteristics, that is, flow resistance is rather contradictory.
However, if a thermal expansion valve with a large flow rate variable width is used as the expansion mechanism, it may be possible to make it common, but it not only increases the cost significantly but also limits the degree of freedom of design. Cannot be adopted.
The present invention has been completed based on the above circumstances, and an object thereof is to form a cooling unit that can be used for both refrigeration and freezing even if a common capillary tube is used. .

The invention of claim 1 is a refrigerator-freezer in which a freezer compartment and a refrigerator compartment are partitioned and formed in a main body in a heat insulating state, and each of the compartments is independently cooled by an individual cooling unit. as the cooling unit for the refrigerating compartment, a compressor, a condenser, an expansion mechanism and an evaporator is circulated connected by refrigerant pipes, wherein the expansion mechanism is intermediate between those suitable for freezing and suitable for refrigeration And an accumulator is provided on the outlet side of the evaporator, and the first half region of the capillary tube is connected to a refrigerant pipe on the outlet side of the evaporator. The cooling unit is provided with a heat exchanging part capable of exchanging heat , and is characterized in that the same unit is mounted .
The capillary tube of the cooling unit according to the present invention is defined as a capillary tube having an intermediate flow rate characteristic between the flow rate characteristic of the capillary tube suitable for refrigeration and the flow rate characteristic of the capillary tube suitable for freezing. Here, the capillary tube suitable for refrigeration means that when the cooling unit is operated at room temperature in combination with the heat insulation box, the equilibrium temperature in the refrigerator (the cooling capacity of the cooling unit and the heat load of the heat insulation box balance). A capillary tube having a flow rate characteristic in which (temperature) is about 0 to −10 ° C. The capillary tube suitable for freezing is a capillary tube having a flow rate characteristic in which the equilibrium temperature in the cabinet is about −15 to −25 ° C. Therefore, when the cooling unit is operated under the same conditions, the capillary tube having intermediate flow characteristics for refrigeration and refrigeration of the cooling unit according to the present invention has , for example, an equilibration temperature of −10 to − It is preferable to have a flow rate characteristic of about 20 ° C.

The invention of claim 2 is characterized in that, in the invention of claim 1, the compressor in the cooling unit is a variable capacity compressor.
According to a third aspect of the present invention, in the first or second aspect, the accumulator in the cooling unit is provided upstream of a heat exchange portion with the capillary tube in the refrigerant pipe. It has the characteristics .

<Invention of Claim 1>
Regarding the cooling unit, after using a capillary tube with an intermediate flow rate characteristic for refrigeration and freezing, an accumulator is provided on the outlet side of the evaporator to obtain a narrowing effect, thereby adapting to a low flow rate freezing region, In addition, since the heat exchange part in the capillary tube is set in the first half region to reduce the total resistance in the tube, it can be adapted to the refrigeration region with a high flow rate. Can be shared. As a result, the design of the cooling unit itself, production can be simplified numerous steps such as management, it is possible to large widths cost reduction and the like.
In the present invention, in the independent cooling type refrigerator-freezer, since the same cooling unit that can be manufactured at a low cost is used for both refrigeration and freezing, separate cooling units are prepared. Compared with the case where it was doing, the manufacturing cost of a refrigerator-freezer can be reduced significantly.
<Invention of Claim 2>
With respect to the cooling unit, a place where a different cooling capacity is required depending on conditions such as the size of the internal volume can be dealt with by using a variable capacity compressor. The range in which the cooling unit can be shared can be further expanded.

<Invention of Claim 3>
When an accumulator is provided for the cooling unit, if it is provided downstream of the heat exchange part with the capillary tube in the refrigerant pipe, the refrigerant may flow in the gas-liquid mixed state in the heat exchange part of the refrigerant pipe. The liquid refrigerant evaporates. In other words, the evaporation of the liquid refrigerant that should originally be performed in the evaporator is performed as an extra work in the heat exchanging section, which leads to a decrease in cooling capacity when viewed from the entire refrigeration circuit.
In that respect , in the cooling unit according to the present invention , since the accumulator is provided on the upstream side of the heat exchanging portion, only the gas refrigerant flows through the heat exchanging portion of the refrigerant pipe, and therefore, no excessive evaporation occurs in the refrigerant pipe. Thus, it is possible to ensure the original cooling capacity of the entire refrigeration circuit.

Hereinafter, an embodiment of the present invention will be described with reference to FIGS. In this embodiment, the case where the present invention is applied to a commercial refrigerator-freezer is illustrated.
The refrigerator-freezer is a four-door type, and as shown in FIGS. 1 and 2, includes a main body 10 made of a heat insulating box having a front surface opened. The front opening is partitioned by a cross-shaped partition frame 11. In addition, four entrances 12 are formed, and a substantially 1/4 interior space corresponding to the entrance 12 at the upper right portion when viewed from the front is partitioned by a heat insulating partition wall 13 to form a freezer compartment 16. The remaining approximately 3/4 of the area is the refrigerator compartment 15. Each doorway 12 is fitted with a heat insulating door 17 so as to be swingable.

On the upper surface of the main body 10, a machine room 20 is configured by, for example, a panel 19 (see FIG. 4) standing around. A rectangular opening 21 having the same size is formed on the upper surface of the main body 10 serving as the bottom surface of the machine room 20, corresponding to the ceiling wall of the refrigerator compartment 15 and the ceiling wall of the freezer compartment 16. . A cooling unit 30 is individually attached to each opening 21.
As will be described in detail later, the cooling unit 30 includes a compressor 32, a condenser 33 with a condenser fan 33A, a dryer 34, a capillary tube 35, and an evaporator 36 by a refrigerant pipe 37 as shown in FIG. The refrigeration circuit 31 is configured by circulating connection. In addition, a heat insulating unit base 38 that covers the opening 21 described above is provided, and the evaporator 36 among the constituent members of the cooling unit 30 is on the lower surface side of the unit base 38 and the other constituent members are on the upper surface side. It is attached.

On the other hand, as shown in FIG. 4, a drain pan 22 that also serves as a cooling duct is stretched downward on the ceiling of the refrigerator compartment 15 and the freezer compartment 16, and is evaporated between the unit base 38. A chamber 23 is formed. A suction port 24 is provided on the upper side of the drain pan 22, a cooling fan 25 is provided, and a discharge port 26 is formed on the lower side.
Basically, when the cooling unit 30 and the cooling fan 25 are driven, the air in the refrigerator compartment 15 (freezer compartment 16) flows from the suction port 24 into the evaporator compartment 23, as indicated by the arrow in FIG. The refrigeration chamber 15 is circulated in such a manner that cold air generated by heat exchange while being sucked in and passed through the evaporator 36 is blown out from the discharge port 26 to the refrigeration chamber 15 (freezer chamber 16). The inside of the (freezer compartment 16) is cooled.

In the present embodiment, it is intended to share the cooling units 30 to be mounted in the refrigerator compartment 15 and the freezer compartment 16, respectively. Therefore, the following measures are taken.
First, the cooling capacity of the cooling unit 30 is determined by the capacity of the compressor. For example, in a compressor having the same capacity, the refrigeration side having a lower evaporation temperature can cool only a smaller volume than the refrigeration side. If it is 15 or the freezer compartments 16, naturally the one where a capacity | capacitance is large needs a big cooling capacity.
In other words, the required cooling capacity differs depending on conditions such as refrigeration, freezing, or the size of the internal volume, so the compressor has the maximum capacity required and the rotational speed. A controllable inverter compressor 32 is used.

Next, the capillary tube 35 is shared. Specifically, in FIG. 3, the capillary tube 35 corresponds to a portion extending from the outlet of the dryer 34 to the inlet of the evaporator 36, and a spiral portion 35A is formed in the central portion to increase the length. In this embodiment, the total length of the capillary tube 35 is set to 2000 to 2500 mm. Incidentally, the length of the refrigerant pipe 37 from the outlet of the evaporator 36 to the suction port of the inverter compressor 32 is about 700 mm.
As described above, in the present embodiment, the conventional capillary tube has been used with a high flow rate characteristic for refrigeration and a low flow rate characteristic for refrigeration. In addition, those having an intermediate flow rate characteristic between refrigeration and freezing are used.
Here, the capillary tube suitable for refrigeration means that when the cooling unit is operated at room temperature in combination with the heat insulation box, the equilibrium temperature in the refrigerator (the cooling capacity of the cooling unit and the heat load of the heat insulation box balance). A capillary tube having a flow rate characteristic in which (temperature) is about 0 to −10 ° C. The capillary tube suitable for freezing is a capillary tube having a flow rate characteristic in which the equilibrium temperature in the cabinet is about −15 to −25 ° C. Accordingly, when the cooling unit is operated under the same conditions, the capillary tube having intermediate flow characteristics for refrigeration and freezing of the present invention has, for example, an equilibrium temperature of about −10 to −20 ° C. It has the flow characteristic which becomes.

If the capillary tube 35 has an intermediate flow rate characteristic as described above, there is a concern that the flow rate of the liquid refrigerant is insufficient in the refrigerated region. In order to solve this problem, the following measures are taken.
In this type of refrigeration circuit, a heat exchange device is formed by soldering the refrigerant pipe 37 on the outlet side of the evaporator 36 and the capillary tube 35. Although it functions to evaporate the mist liquid refrigerant that has not been completely evaporated, in this embodiment, when the heat exchange device 40 is formed between the capillary tube 35 and the refrigerant pipe 37, the capillary tube 35 side The heat exchange section 40A is set in a predetermined area at the upstream end of the spiral section 35A. The position of the heat exchange part 40A can be said to be a position close to the inlet side when viewed from the full length of the capillary tube 35.

  The capillary tube 35 has a large pressure difference between the inlet and the outlet. As shown in FIG. 5A, the flow resistance is a portion where the liquid refrigerant begins to boil in the tube (approximately the central portion of the entire length). The pressure increases rapidly, and the pressure drops greatly downstream (outlet side) from there. Until now, the heat exchanging part of the capillary tube 35 is set at a position rather close to the outlet in the latter half region of the entire length, and thus heat exchange is performed after starting evaporation (boiling) in the tube. This is because the capillary tube 35 is cooled on the downstream side from the heat exchange position, causing condensation or rusting, so that the heat exchange position is brought to the outlet side as much as possible and exposed in a cooled state. This is to suppress the length of the portion as much as possible.

On the other hand, in this embodiment, as described above, the heat exchanging part 40A of the capillary tube 35 is set at a position close to the inlet, that is, the liquid refrigerant is brought before the position where the liquid refrigerant starts to evaporate. As shown in FIG. 5B, the boiling start point in the tube can be shifted to the downstream side of the capillary tube 35. This results in a reduction in the total resistance of the capillary tube 35 and substantially increases the flow rate of the liquid refrigerant. This eliminates the problem of insufficient flow when the capillary tube 35 having an intermediate flow rate characteristic is used in the refrigerated region.
In order to obtain the effect of shifting the boiling start point in the tube to the downstream side of the capillary tube 35, the heat exchange part 40A on the capillary tube 35 side is moved to the first half of at least the entire length before the position where the liquid refrigerant starts to evaporate. What is necessary is just to provide in an area | region, More preferably, it is the 1/3 area | region (area | region with many liquid states) of an entrance side.
In addition, if the heat exchanging portion 40A of the capillary tube 35 is provided at a position close to the inlet, a long dimension portion thereafter is exposed in a cooled state, and therefore, that portion is separated from the refrigerant pipe 37 as much as possible. And it is desirable to encapsulate with a heat insulating tube (not shown). Thereby, condensation and rust are prevented.

On the other hand, when the capillary tube 35 has an intermediate flow rate characteristic, insufficient throttling in the freezing region is dealt with by providing an accumulator 42 (liquid separator) immediately after the evaporator 36. Providing the accumulator 42 provides an adjustment volume for storing the liquid refrigerant in the refrigeration circuit 31.
In the refrigeration region, the refrigerant pressure in the evaporator 36 is low (the refrigerant evaporation temperature is low) and the density of the refrigerant gas is low compared to the pull-down region (rapid cooling region) and the refrigeration region. The resulting refrigerant circulation is small. As a result, the liquid refrigerant is left in the refrigeration circuit 31, but the excess liquid refrigerant is stored in the accumulator 42, so that the liquid refrigerant does not circulate excessively in the capillary tube 35 and the like, and substantially. The capillary tube 35 has an effect of restricting the flow rate. Thereby, the problem of insufficient narrowing when the capillary tube 35 having an intermediate flow rate characteristic is used in the freezing region is solved.

  Regarding the common use of the capillary tube 35, in other words, the flow rate of the liquid refrigerant is obtained by using the capillary tube 35 having an intermediate flow characteristic and providing an accumulator 42 immediately after the outlet of the evaporator 36 to obtain a narrowing effect. In other words, the flow rate of the liquid refrigerant is increased by reducing the total resistance in the tube by setting the heat exchanging part 40A in the capillary tube 35 to the side closer to the inlet, that is, adapting to the freezing region of low flow rate, It is adapted to high flow pull-down area and refrigerated area.

In addition, when providing the accumulator 42, if it is provided in the refrigerant | coolant piping 37 in the downstream of the heat exchange part 40B, a refrigerant | coolant may flow into a heat exchange part 40B in a gas-liquid mixed state, and a liquid refrigerant evaporates at this time. . In other words, the evaporation of the liquid refrigerant that should originally be performed in the evaporator 36 is performed as an extra work in the heat exchanging unit 40B, which leads to a decrease in cooling capacity when viewed from the entire refrigeration circuit 31.
In this respect, in this embodiment, the accumulator 42 is provided immediately after the outlet of the evaporator 36, that is, on the upstream side of the heat exchanging part 40B in the refrigerant pipe 37, so that only the gas refrigerant flows through the heat exchanging part 40B. Since an excessive evaporation effect does not occur within 40B, the original cooling capacity can be secured for the entire refrigeration circuit 31.

Further, since the heat exchanging portion 40A in the capillary tube 35 is set on the side closer to the inlet, there is a concern that the flow rate of the liquid refrigerant may increase on the refrigeration side, but there is no fear as described below.
In the refrigeration circuit 31 including the capillary tube 35, the refrigerant is basically held in such a manner that the refrigerant is held between the high-pressure side and the low-pressure side. Conceptually, the refrigerant is condensed in the refrigeration region (including the pull-down region). In the evaporator 33 and then in the evaporator 36, in the refrigeration region, the refrigerant is mostly in the evaporator 36 and the accumulator 42, and conversely in the condenser 33, a small amount. Therefore, in the refrigeration region, the refrigerant flows into the capillary tube 35 as a complete liquid flow. However, in the refrigeration region, the flow rate itself is considerably reduced because it flows by gas-liquid mixing, and therefore at a position close to the inlet of the capillary tube 35. Even if it is supercooled by heat exchange, it will not lead to an increase in flow rate.
On the contrary, the provision of the accumulator 42 may cause a decrease in the flow rate even in the refrigerated region (including the pull-down region). However, for the opposite reason, in the refrigerated region (including the pull-down region), compression is performed. It is considered that there is a large amount of refrigerant circulated by the machine 32, there is little liquid refrigerant remaining in the refrigeration circuit 31, and there is little room for storage in the accumulator 42.

As described above, the cooling unit 30 is structurally shared between the refrigeration unit and the freezing unit, while the operation control is performed individually. This is based on the recognition that when the cooling unit 30 is used in common, the temperature characteristics during pull-down cooling, for example, may vary greatly depending on conditions such as refrigeration and freezing, or the size of the internal volume.
In a cooling unit loaded with an inverter compressor, it is normal to perform the maximum allowable high-speed operation at the time of pull-down cooling. However, when pull-down cooling is performed under the same conditions where food is not put in the refrigerator, a heat insulating box ( As shown in FIG. 6, there is a clear difference in the temperature curve in the chamber when the chamber volume is large, intermediate, or small. The difference in the degree of temperature drop is due to the fact that when the temperature difference between the inside and outside of the box is the same, it is proportional to the surface area of the heat insulating box, and the larger the box, the larger the heat capacity of the inner wall material and the shelf network in the box.

On the other hand, in commercial refrigerators (the same applies to freezers and refrigerators), the temperature characteristics of pull-down cooling are regarded as important. For example, for cooling from a high internal temperature of 20 ° C, in addition to initial operation after installation, turn off the power for maintenance, etc., restart several hours later, open the door for several minutes when food is carried in, or hot food If you put it in, etc., it is almost limited, but considering that the doors are frequently opened and closed and the ambient temperature is relatively high, the refrigerator for business use tends to rise in temperature, The temperature drop characteristic is sufficiently taken into consideration as the restoring force at that time.
Therefore, the performance test at the time of pull-down cooling is indispensable. However, as described above, the cooling rate largely depends on the heat insulation box. Therefore, for this performance test, the cooling unit and the heat insulation box on which it is mounted. It is necessary to carry out in a combined state. Therefore, there is a problem that the complexity of the performance test cannot be eliminated even if the corner cooling unit is used in common.

Therefore, in this embodiment, means for controlling the temperature of the inside of the cabinet along a predetermined temperature curve without depending on the heat insulating box at the time of pull-down cooling is taken.
As an example, as shown in FIG. 7, a control unit 45 that includes a microcomputer or the like and executes a predetermined program is provided, and the electrical equipment provided on the upper surface of the unit base 38 on which the cooling unit 30 is mounted. It is stored in the box 39. An internal temperature sensor 46 for detecting the internal temperature is connected to the input side of the control unit 45.
The control unit 45 is provided with a data storage unit 49 together with the clock signal generation unit 48. In the data storage unit 49, as shown in FIG. Is selected and stored. Thus, when the ideal curve is the straight line a, the target internal temperature drop (temperature change per unit time: ΔT / Δt) becomes a constant value A regardless of the internal temperature.
An inverter compressor 32 is connected to the output side of the control unit 45 via an inverter circuit 50.

As the operation, pull-down control is started when the internal temperature exceeds the internal set temperature by a predetermined value or more, and the internal temperature is detected at predetermined time intervals.
As shown in FIG. 9, the actual temperature drop degree B is calculated at each detection timing, and this calculated value B is compared with the target value A read from the data storage unit 49 to calculate the calculated value. If B is less than or equal to the target value A, the rotational speed of the inverter compressor 32 is increased via the inverter circuit 50. Conversely, if the calculated value B is larger than the target value A, the rotational speed of the compressor 32 is decreased. This is repeated at predetermined time intervals to perform pull-down cooling along the ideal curve (straight line a).

After the above-described pull-down cooling, both the refrigeration and the freezing are controlled cooling in which the internal temperature is maintained near a preset temperature, but with the inverter compressor 32 as described above, The following advantages are obtained. That is, when the control cooling is performed so that the speed (the number of rotations) of the inverter compressor 32 is gradually reduced in the vicinity of the set temperature, the temperature drop becomes extremely slow. It becomes overwhelmingly long, in other words, the number of times the compressor is switched on and off is greatly reduced, and since it is operated at a low speed, it leads to higher efficiency and energy saving.
In the above, the cooling capacity when the inverter compressor 32 is operated at a low speed needs to be set so as to exceed the assumed standard heat load. This is because if there is only a cooling capacity that does not satisfy the assumed heat load, the internal temperature does not decrease to the set temperature, and is thermally balanced and stays in front of it. When the cooling unit 30 is shared including the inverter compressor 32 as in the present embodiment, it is necessary to consider the heat insulation amount that is the largest among the heat insulation boxes that are installed as counterparts as the heat load. is there.

By the way, especially in commercial refrigerators (the same applies to freezers), special consideration is given to suppressing variations in the temperature distribution in the refrigerator so that the food can be stored at a constant quality. Since the air circulation function is also achieved, the motor generates a relatively large amount of heat. In addition, when conditions such as the heat capacity of food, ambient temperature, and door opening / closing frequency overlap, sometimes the heat load becomes larger than expected, and the temperature inside the cabinet becomes low despite the inverter compressor 32 being operated at a low speed. There is a possibility that the on-time may become abnormally long due to the minute change even if the temperature stays before the set temperature or even if the temperature drops.
As a function of the refrigerator, it can be said that there is no problem if it stays at a temperature very close to the set temperature. However, in the refrigerator, it is not much that the operation is continued with the inverter compressor 32 turned on. Not good. This is because, while the operation is continued, frost continues to adhere to the evaporator 36 due to intruding air from outside the box accompanying the opening and closing of the door 17 and water vapor coming from the food. On the other hand, when the inverter compressor 32 is appropriately turned off, the evaporator 36 is heated to 0 ° C. or higher to be defrosted. Therefore, having an appropriate off time means that the heat of the evaporator 36 in the refrigerator. It is considered preferable to maintain the exchange function.

Therefore, in this embodiment, during the control cooling, a control means is provided that realizes energy saving by taking advantage of the use of the inverter compressor 32 and further ensures an off time.
Briefly, during the operation of the inverter compressor 32 in the control region, the drive of the inverter compressor 32 is controlled so that the internal temperature follows the ideal temperature curve as in the pull-down region described above. For example, as shown in FIG. 10, this temperature curve is set as a straight line a1 having a gentler slope than the ideal curve (straight line a) during pull-down cooling. Even in the ideal curve a1, the target degree of temperature drop in the cabinet is constant, but is smaller than the ideal curve a.
The ideal curve a1 is similarly stored in the data storage unit 49 and is used when the control cooling program stored in the control unit 45 is executed.

The control operation of the control cooling is basically the same as that during pull-down cooling. When the internal temperature is lowered to the upper limit temperature Tu higher than the set temperature To by the pull-down cooling, the control control is shifted to. Here, the internal temperature is detected at predetermined time intervals, the actual internal temperature drop is calculated at each timing, and the target value of the internal temperature drop in the ideal temperature curve a1 (constant) ), The rotational speed of the inverter compressor 32 is increased if the calculated value is less than or equal to the target value, and conversely, if the calculated value is larger than the target value, the rotational speed of the compressor 32 is decreased and this is a predetermined time. Repeated at intervals, the temperature slowly drops along the ideal curve (straight line a1).
When the internal temperature falls to the lower limit temperature Td lower than the set temperature To by a predetermined value, the inverter compressor 32 is turned off, the internal temperature gradually rises, and when the internal temperature returns to the upper limit temperature Tu, the temperature curve a1 again. The temperature control is performed in accordance with the above, and by repeating this operation, the interior of the cabinet is maintained substantially at the set temperature To.
According to the control during the control cooling, the inverter compressor 32 can be used for energy-saving cooling, and the inverter compressor 32 can be stopped for a certain amount of time appropriately. The frost function can be exhibited to prevent frost formation in large quantities.

Thus, for example, on the refrigeration side, an operation program for controlling the drive of the inverter compressor 32 is provided from the pull-down cooling to the control cooling so that the interior follows the temperature characteristic X (see FIG. 11) including the ideal curves a and a1. It is done.
On the other hand, even if the basic control operation is the same on the refrigeration side, the set temperature in the refrigerator is different, and the operation time of the inverter compressor 32 is shorter than that on the refrigeration side in order to suppress frost formation as much as possible during control cooling. Thus, since the ideal curve is naturally different, on the refrigeration side, for example, an operation program for controlling the drive of the inverter compressor 32 so as to follow the temperature characteristic Y of FIG.
Therefore, the control unit 45 stores separate operation programs including target temperature curves for refrigeration and refrigeration, and in which of the refrigeration room 15 and the freezing room 16 the cooling unit 30 is installed. Thus, the operation program corresponding to each is executed.

The present embodiment has the structure as described above, and the main body 10 made of a heat insulating box and two common cooling units 30 are divided and carried into the installation site, and the refrigerator compartment 15 and the freezer compartment Each of the 16 ceiling openings 21 is mounted. After that, for each of the refrigerator compartment 15 and the freezer compartment 16, the internal set temperature is inputted, and a control attached to the cooling unit 30 attached to the refrigerator compartment 15 side by a switch (not shown) provided in the electrical box 39 or the like. In the unit 45, the operation program for the refrigerator compartment 15 is selected, while in the control unit 45 attached to the cooling unit 30 attached to the freezer compartment 16 side, the operation program for the freezer compartment 16 is selected.
The refrigerator compartment 15 and the freezer compartment 16 are controlled to be cooled based on individual operation programs.

As described above, in the present embodiment, the capillary tube 35 having an intermediate flow rate characteristic between refrigeration and freezing is used, and an accumulator 42 is provided immediately after the outlet of the evaporator 36 to obtain a narrowing effect. Since the heat exchanger 40A in the capillary tube 35 is adapted to the side closer to the inlet by reducing the total resistance in the tube by adapting to the low flow freezing region, The cooling unit 30 for refrigeration and refrigeration, which has been separated separately, can be shared. In addition, in order to obtain an appropriate cooling capacity determined by conditions such as the size of the internal volume, the inverter compressor 32 is used.
Therefore, according to conditions such as refrigeration and freezing, or the size of the internal volume, it is possible to share the cooling units 30 that have been prepared in the past up to a considerable range. As a result, many processes such as the design, production, and management of the cooling unit 30 can be simplified, and a significant cost reduction can be achieved.

<Related technologies>
In the above-described embodiment, on the refrigerator compartment 15 side, the inverter compressor 32 is operated at a low speed near the internal set temperature, and further, the control operation in which the internal temperature is maintained at substantially the set temperature by being repeatedly turned on and off as appropriate. When performed, the cooling fan 25 may be driven at a lower speed than the steady speed even when the compressor 32 is stopped.
That is, when the operation of the compressor 32 is stopped, the cooling fan 25 is decelerated, during which the temperature of the evaporator 36 rises and the attached frost is melted and vaporized. It is blown into the refrigerator compartment 15 and maintained at high humidity.

  If the cooling fan 25 continues to be operated at a steady operation speed even after the compressor 32 is stopped, the evaporator 36 has heat from the inside of the refrigerator compartment 15 (the air temperature in the refrigerator compartment 15 is higher than that of the evaporator 36). ) And the heat from the high-temperature liquid refrigerant flowing into the evaporator 36 immediately after the compressor 32 is stopped, the temperature of the cooling fan 25 is decelerated. The inflowing heat is consumed as latent heat for melting frost and ice adhering to the evaporator 36, and the temperature rise of the evaporator 36 is small. Further, since the cooling fan 25 is decelerated, the heat generation of the motor is reduced, and further, the cool air cooled by the evaporator 36 is not blown onto the inner wall of the warehouse, and the inner wall of the warehouse is not unnecessarily cooled. Heat inflow through is reduced.

As a result, the rise in the internal temperature is delayed, and the stop time of the compressor 32 can be increased accordingly. That is, the operating rate of the compressor 32 can be kept low and contribute to energy saving.
Further, after the compressor 32 is stopped, it takes about 3 to 5 minutes for the high and low pressures of the refrigeration circuit 31 to balance the pressure. If the stop time of the compressor 32 is short, the compressor 32 remains in a state where there is a pressure difference. Although it is restarted, it may not be able to start up well, but as described above, the compressor 32 is restarted after the pressure balance is achieved by taking a long stop time of the compressor 32. This increases the reliability of starting.
In order to obtain the same effect as described above, while the compressor 32 is stopped, the driving of the cooling fan 25 is stopped or decelerated until the frost adhering to the evaporator 36 melts, and then at a steady speed. The driving may be resumed.

<Other embodiments>
The present invention is not limited to the embodiments described with reference to the above description and drawings. For example, the following embodiments are also included in the technical scope of the present invention, and further, within the scope not departing from the gist of the invention other than the following. Various modifications can be made.
(1) In the above embodiment, the case where an inverter compressor is used as a compressor is exemplified as means for adjusting the cooling capacity of the cooling unit. However, the present invention is not limited to this, and the number of cylinders driven according to the load is not limited to this. Other variable capacity compressors such as a compressor with an unload function for adjusting the pressure may be used.
(2) As another means for adjusting the cooling capacity of the cooling unit, the amount of refrigerant in the refrigeration circuit may be controlled. For example, a bypass circuit is provided so that the refrigerant discharged from the condenser can be returned to the compressor without passing through the evaporator, or the refrigerant discharged from the discharge side of the compressor can be returned to the suction side of the compressor without passing through the evaporator. If it is made to return, it is possible to reduce the cooling capacity.

(3) For example, even a cooling unit that can be used separately for refrigeration and freezing may have the same cooling capacity depending on the balance with the volume of the heat insulating box of the other party to be installed. However, since it is sufficient to use a constant speed compressor without using an inverter compressor, such a thing is also included in the technical scope of the present invention.
(4) The position where the accumulator is provided may be on the downstream side of the heat exchange unit.
(5) The present invention is also temperature controlled chamber having other volume ratio can be similarly applied to.

The perspective view of the refrigerator-freezer which concerns on one Embodiment of this invention. The exploded perspective view Refrigeration circuit diagram Partial sectional view with cooling unit installed Graph showing pressure change in capillary tube Graph showing temperature curve in pull-down area Block diagram of the control mechanism of the inverter compressor Graph showing ideal temperature curve during pull-down cooling Flow chart showing control operation of inverter compressor Graph showing temperature change in control area A graph showing comparison of the temperature characteristics in the refrigerator on the refrigeration side and the freezing side

Explanation of symbols

  DESCRIPTION OF SYMBOLS 30 ... Cooling unit 31 ... Refrigeration circuit 32 ... Inverter compressor (compressor) 33 ... Condenser 35 ... Capillary tube 36 ... Evaporator 37 ... Refrigerant piping 40 ... Heat exchange apparatus 40A ... Heat exchange part (of capillary tube 35) 40B ... Heat exchange part (of refrigerant pipe 37) 42 ... Accumulator

Claims (3)

In the refrigerator, the freezer compartment and the refrigeration compartment are partitioned in a thermally insulated state, and each of the compartments is independently cooled by an individual cooling unit.
As the cooling unit for the cooling chamber and for the freezing chamber, a compressor, a condenser, an expansion mechanism and an evaporator is circulated connected by refrigerant pipes, wherein the expansion mechanism is suitable for freezing and suitable for refrigeration And an accumulator is provided on the outlet side of the evaporator, and the first half region of the capillary tube is provided on the outlet side of the evaporator. refrigerator, characterized in that a cooling unit for the heat exchanger to allow heat exchange is provided and the same ones are mounted between the refrigerant pipe. 2. The refrigerator-freezer according to claim 1, wherein the compressor in the cooling unit is a variable capacity compressor. 3. The refrigerator-freezer according to claim 1, wherein the accumulator in the cooling unit is provided on an upstream side of a heat exchange portion with the capillary tube in the refrigerant pipe.

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