JP3995562B2 - refrigerator - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a refrigerator that refrigerates stored items in a warehouse.
[0002]
[Prior art]
In the conventional refrigerator, the inside of the refrigerator is cooled by a cooler of a refrigeration cycle, and stored items are stored in the refrigerator. As the refrigerant for the refrigeration cycle, a fluorocarbon refrigerant is generally used and is liquefied by a condenser. Therefore, in this condenser, the refrigerant has a substantially constant temperature (that is, the condensation temperature).
[0003]
[Problems to be solved by the invention]
By the way, in recent years, the use of CFC-based refrigerants has been reduced, and the use of refrigerants other than CFC-based refrigerants (for example, carbon dioxide) is also considered in refrigerators. If such a refrigerant is used, the refrigerant may change its state in the supercritical region on the high pressure side of the refrigeration cycle and may not be liquefied.In order to increase the expansion of the refrigerant in the decompression device, the compression ratio of the compressor is increased. Yes. As described above, when the compression ratio is increased, the temperature of the compressed refrigerant greatly increases. And the heat of this refrigerant | coolant is discarded outside and is hardly utilized effectively.
[0004]
The present invention is intended to solve the above-described problems, and an object of the present invention is to provide a refrigerator that is optimal for using a refrigerant that is in a supercritical state and does not liquefy on the high-pressure side of a refrigeration cycle. Yes.
[0005]
[Means for Solving the Problems]
In the refrigerator according to claim 1 of the present application, in the refrigerator in which the outer shell is configured by the heat insulating box (1) and the front opening thereof is closed by the heat insulating door so as to be opened and closed, the refrigerator from the first-stage inlet (16d) A primary compression mechanism that compresses the refrigerant and discharges it from the first-stage outlet (16a), and a second compressor that compresses the refrigerant from the second-stage inlet (16b) and discharges it from the second-stage outlet (16c). A compressor (16) having a secondary compression mechanism, and a primary air-cooling heat exchange section (air-cooled from a first-stage discharge port of the compressor, in which the gaseous refrigerant compressed to a high temperature and high pressure by the primary compression mechanism of the compressor is air-cooled) 17a), the first stage refrigeration cycle returning to the second stage inlet of the compressor, and the gaseous refrigerant compressed to a high temperature and high pressure by the secondary compression mechanism from the second stage outlet of the compressor Is the supercritical region A secondary air-cooling heat exchange section (17b) that is air-cooled while changing its state, a decompression device (22, 23), and a cooler (24) that cools the interior with a refrigerant that has been decompressed by this decompression device and has become low temperature Then, the second stage refrigeration cycle returning to the first stage inlet of the compressor, the defrosting means (29) for melting the frost adhering to the cooler, and the drain into which the drain water melted by the defrosting means flows A container (32) and a drain evaporation pipe (26) for allowing the refrigerant in the refrigeration cycle to flow and evaporate the drain water in the drain container, the drain evaporation pipe being a first stage discharge of the compressor in the first stage refrigeration cycle. Installed in the refrigerant circuit from the outlet to the primary air-cooling heat exchanger In addition, a dew prevention pipe (19) for preventing dew from the front of the heat insulation box is provided in the refrigerant circuit from the secondary air-cooling heat exchange part of the refrigeration cycle to the decompression device. It is characterized by that.
[0006]
[0007]
Claim 2 The refrigerator described is In particular, A water detection means (36) for detecting the presence or absence of water in the drain container is provided in the refrigerant circuit from the drain evaporation pipe to the primary air-cooling heat exchange unit, and switches the refrigerant flow to bypass the primary air-cooling heat exchange unit. When the bypass switching valve (27) and the water detection means detect water in the drain container, the bypass switching valve (27) is provided with a control means (41) for switching the bypass switching valve to the bypass side.
[0008]
Claim 3 The refrigerator described is In particular, A primary air-cooling heat exchanger blower (51) for air-cooling the refrigerant in the primary air-cooling heat exchanger, a secondary air-cooling heat exchanger fan (52) for air-cooling the refrigerant in the secondary air-cooling heat exchanger, and water in the drain vessel The water detection means for detecting presence or absence, and the control means for stopping the blower for the primary air-cooling heat exchange unit when the water detection means detects water in the drain container.
[0009]
[0010]
[0011]
[0012]
Claim 4 In the refrigerator described above, the outer shell is formed of a heat insulating box, and the front opening of the refrigerator is closed so that it can be opened and closed by a heat insulating door. The refrigerant from the first inlet is compressed and discharged from the first outlet. And a compressor having a secondary compression mechanism that compresses the refrigerant from the second-stage inlet and discharges it from the second-stage discharge port, and the compressor from the first-stage discharge port of the compressor A first-stage refrigeration cycle that returns to the second-stage inlet of the compressor through a primary air-cooling heat exchange section in which the gaseous refrigerant that has been compressed by the primary compression mechanism and has become high-temperature and high-pressure is air-cooled; A secondary air-cooling heat exchanger, a pressure reducing device, and a pressure reducing device, in which a gaseous refrigerant compressed to a high temperature and pressure by a secondary compression mechanism is air-cooled while changing its state in the supercritical region from the discharge port of the eye. A second-stage refrigeration cycle that returns to the first-stage inlet of the compressor through a cooler that cools the interior with the refrigerant that has been cooled to a low temperature, and a defrosting unit that melts frost adhering to the cooler. A drain container into which drain water melted by this defrosting means flows, and a refrigerant circuit from the second stage discharge port of the compressor of the second stage refrigeration cycle to the secondary air cooling heat exchange unit, The refrigerant evaporates and the drain evaporating pipe evaporates the drain water in the drain container, the primary air-cooled heat exchanger blower that air-cools the refrigerant in the primary air-cooled heat exchanger, and the secondary air that cools the refrigerant in the secondary air-cooled heat exchanger The air-cooling heat exchanger blower, the water detection means for detecting the presence or absence of water in the drain container, and the secondary air-cooling heat exchange fan are stopped when the water detection means detects water in the drain container. With control means And features.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Next, a first embodiment of the refrigerator according to the present invention will be described with reference to FIGS. FIG. 1 is an explanatory diagram of a refrigerant circuit of a first embodiment of a refrigerator according to the present invention. FIG. 2 is a diagram of a specific example of the refrigerant circuit of the refrigerator of FIG. FIG. 3 is a view of the dew prevention pipe in FIG. FIG. 4 is an input / output diagram of the control device. FIG. 5 is an explanatory diagram of the refrigerant circuit according to the first embodiment in a state in which the switching valve is switched to the bypass side. FIG. 6 is a flowchart of the operation of the switching valve.
[0014]
The external refrigerator of the home refrigerator is composed of a heat insulating box 1 (see FIG. 3). The internal space of the heat insulation box 1, that is, the inside of the box, is partitioned into a plurality of rooms (four rooms in this embodiment) having different set temperatures, and the refrigerator room 6, the vegetable room 7, the freezer room 8, and the freezer It is chamber 9. The front surfaces of the cooling chambers 6 to 9 are opened, and the front opening is closed by a heat insulating door (not shown) so as to be freely opened and closed. In addition, the back side of the freezer compartment 9 is a machine room 11.
[0015]
The machine room 11 is provided with devices for cooling the interior, that is, a two-stage compression compressor 16, an air cooling heat exchanger 17, an air cooling heat exchanger blower 18, and the like. The compressor 16 and the air-cooling heat exchanger 17 and the like are connected by a refrigerant pipe 21 to constitute a refrigeration cycle. ₂ (Carbon dioxide) is used. As shown in FIG. 1, this refrigeration cycle starts from the first discharge port 16 a of the compressor 16 through the drain evaporating pipe 26 and the primary air-cooling heat exchanger 17 a of the air-cooling heat exchanger 17 in order. From the first stage cycle returning to the stage inlet 16b and the second stage outlet 16c of the compressor 16, the secondary air cooling heat exchanger 17b of the air cooling heat exchanger 17 and the inlet (front end) of the heat insulation box 1 are sequentially provided. ), The high-pressure side pipe 20 a of the internal heat exchanger 20, the capillary tube 22, the electric expansion valve 23, the cooler 24, and the low-pressure side pipe of the internal heat exchanger 20. A second-stage cycle from 20b to the first-stage inlet 16d of the compressor 16 again.
[0016]
The capillary tube 22 and the electric expansion valve 23 constitute a pressure reducing device. In the internal heat exchanger 20, the high-pressure side pipe 20a and the low-pressure side pipe 20b are in close contact with each other, and the relatively high-temperature refrigerant in the high-pressure side pipe 20a and the low-temperature refrigerant in the low-pressure side pipe 20b exchange heat. To do. In the compressor 16, the first-stage compression mechanism compresses the refrigerant flowing in from the first-stage inlet 16d and discharges it from the discharge port 16a, and the second-stage compression mechanism uses the second-stage inlet. The refrigerant flowing in from 16b is compressed and discharged from the discharge port 16c. Further, a three-way switching valve 27 is provided as a bypass switching valve in the refrigerant circuit between the drain evaporation pipe 26 and the primary air-cooling heat exchanger 17a in the first stage cycle. The air-cooling heat exchange side (the state shown in FIG. 1) for flowing the refrigerant from the primary air-cooling heat exchanging portion 17a and the refrigerant from the drain evaporation pipe 26 bypass the primary air-cooling heat exchanging portion 17a and the second stage of the compressor 16 It is possible to switch to the bypass side (the state shown in FIG. 5) that returns to the inflow port 16b.
[0017]
And the cooler 24 becomes low temperature and reduces the temperature of surrounding air. The cool air around the cooler 24 is blown and circulated by the internal fan 28 to cool the interior. In this way, the inside of the cabinet can be cooled by the cooler 24. Since frost adheres to the cooler 24, the frost is melted and defrosted at appropriate time intervals by a defrost heater 29 as a defrosting means. The drain water that is defrost water from the cooler 24 is received by the dew tray 31 and falls from the dew tray 31 and is stored in the drain container 32. The drain vessel 32 is provided with the drain evaporation pipe 26 described above, and the drain water in the drain vessel 32 is heated by the high-temperature refrigerant in the drain evaporation pipe 26 to evaporate.
[0018]
Further, the discharge port 16c of the compressor 16 to the electric expansion valve 23 is the high pressure side of the refrigeration cycle, and the electric expansion valve 23 to the inlet 16d of the compressor 16 is the low pressure side of the refrigeration cycle. And as a detection means, the water detection sensor 36 as a water detection means which detects the presence or absence of the water of the drain container 32, and the cooling chamber which detects the internal temperature (temperature of the freezer compartment 8 which is a cooling chamber in this Embodiment). An internal temperature sensor 37 is provided as temperature detecting means.
[0019]
As shown in FIG. 4, the refrigerator is provided with a control device 41, and the control device 41 is constituted by a microcomputer or the like. Various electrical components are connected to the control device 41. Especially as electrical components for controlling the three-way switching valve 27 and the like, a water detection sensor 36 and an internal temperature sensor 37 are provided on the input side. On the other hand, the air-cooling heat exchanger blower 18, the electric expansion valve 23, the internal fan 28, the compressor 16, the three-way switching valve 27, and the defrosting heater 29 are connected to the output side. Various setting values are stored in the storage unit (ROM, RAM, etc.) of the control device 41, and a timer (not shown) is built in. In addition to the control of the three-way switching valve 27, the control device 41 performs various controls (for example, temperature control inside the cabinet and control of the defrost heater 29).
[0020]
When the compressor 16 is operated in a state where the three-way switching valve 27 is switched to the air-cooling heat exchange side, the refrigerator according to the first embodiment configured as described above has a gaseous refrigerant (CO ₂ ) Is compressed in the first stage of the compressor 16 to become a high-temperature and high-pressure gaseous refrigerant, passes through the drain evaporation pipe 26, and in the primary air-cooling heat exchanger 17a of the air-cooling heat exchanger 17, the air from the air-cooling heat exchanger blower 18 Air is cooled by (air in the room where the refrigerator is installed), the temperature drops, and the compressor 16 is returned.
[0021]
The refrigerant is further compressed at the second stage of the compressor 16 to become a high-temperature and high-pressure gaseous refrigerant, and is air-cooled with air from the air-cooling heat exchanger blower 18 in the secondary air-cooling heat exchanger 17b of the air-cooling heat exchanger 17. Then, while changing the state in the supercritical region, the temperature of the refrigerant decreases to the vicinity of the atmospheric temperature (that is, room temperature that is the temperature of the room in which the refrigerator is installed). The refrigerant that has fallen to near room temperature flows into the dew prevention pipe 19. As described above, the dew prevention pipe 19 is piped along the opening of the heat insulating box 1. However, the refrigerant in the dew prevention pipe 19 gradually decreases in temperature, and therefore the cooling chambers 6 to 9. The pipes are arranged around the periphery in the order in which the condensation easily occurs (that is, in the order of the low temperature of the cooling chambers 6 to 9). In this embodiment, the freezer compartment 8 and the freezer compartment 9 are the lowest at substantially the same temperature, and in the refrigerator compartment 6, the coldest compartment having the highest temperature is the vegetable compartment 7. Therefore, as shown in FIG. 3, the dew prevention pipe 19 includes, in order from the refrigerant inflow side, the right side of the freezer compartment 8, the right side, the lower side, the left side, the upper side of the freezer compartment 9, the lower side of the freezer compartment 8, The left side, the upper side, and then folded back, the lower side and the left side of the vegetable room 7, the left side, the upper side, the right side, and the lower side of the refrigerator compartment 6, and then folded and passed through the upper side and the right side of the vegetable room 7 to the internal heat exchanger 20. It is flowing out. In this way, the dew prevention pipe 19 circulates around the freezer compartments 8 and 9 first, followed by the refrigerator compartment 6 and then around the vegetable compartment 7, so that the dew at the front of the heat insulating box 1 is exposed. Is effectively prevented.
[0022]
Next, the refrigerant exiting the dew prevention pipe 19 is cooled by the return refrigerant from the cooler 24 in the internal heat exchanger 20, and then depressurized through the capillary tube 22 and the electric expansion valve 23 which are decompression devices. The temperature drops. This low-temperature refrigerant flows into the cooler 24 and lowers the temperature of the air around the cooler 24. The air whose temperature has been lowered by the cooler 24 circulates in the cabinet by the cabinet fan 28 and cools the cooling chambers 6 to 9. The refrigerant flowing out of the cooler 24 exchanges heat with the high-pressure side refrigerant in the internal heat exchanger 20 and returns to the inlet 16d of the compressor 16 after the temperature rises.
[0023]
The control device 41 determines whether or not the internal temperature (cooling chamber temperature), which is the detection value of the internal temperature sensor 37, has reached the cooling chamber set temperature set in the control device 41, and the internal temperature is cooled. When the temperature is lower than the room set temperature, the compressor 16 is stopped. On the other hand, when the inside temperature exceeds the cooling room set temperature, the compressor 16 is operated and the cooler 24 cools the inside. In addition, the control device 41 operates the air-cooling heat exchanger blower 18 and the internal fan 28 substantially in conjunction with the compressor 16, starts operating together with the compressor 16, and slightly delays when the compressor 16 stops. Stopped. Furthermore, the control device 41 operates the defrost heater 29 at a set time interval to melt the frost attached to the cooler 24.
[0024]
The drain water that is defrost water from the cooler 24 is accumulated in the drain container 32. The drain water is heated and evaporated by the high-temperature refrigerant in the drain evaporation pipe 26. At this time, the refrigerant in the drain evaporation pipe 26 is cooled by the drain water. And, in this way, when there is drain water in the drain container 32, and the high-temperature refrigerant of the drain evaporation pipe 26 is cooled by this drain water, the refrigerant temperature may be lower than the atmospheric temperature. On the other hand, there is a possibility that the primary air-cooling heat exchange unit 17a may be warmed. Therefore, the refrigerant passing through the drain evaporation pipe 26 by switching the three-way switching valve 27 to the bypass side bypasses the primary air-cooling heat exchanger 17a and flows into the second-stage inlet 16b of the compressor 16. In addition, when the temperature of the refrigerant flowing into the second-stage inlet 16b is low, the cooling efficiency of the refrigeration cycle is improved as compared with the case where the temperature is high.
[0025]
On the other hand, when there is no drain water in the drain container 32, in order to improve the cooling efficiency of a refrigerating cycle, it is necessary to air-cool a refrigerant | coolant by the primary air-cooling heat exchange part 17a. Therefore, the refrigerant passing through the drain evaporation pipe 26 by switching the three-way switching valve 27 to the air cooling heat exchange side flows into the second inlet 16b of the compressor 16 after passing through the primary air cooling heat exchanger 17a. Yes.
[0026]
The flow of the switching operation of the three-way switching valve 27 will be described based on the flowchart of FIG.
In step 1, the control device 41 determines whether or not there is water in the drain container 32 based on the detection signal from the water detection sensor 36. If there is, the control device 41 goes to step 2 and the control device 41 is in three directions. The switching valve 27 is switched to the bypass side, and the process returns to step 1. On the other hand, when there is no drain water, it goes to step 3 and the control device 41 switches the three-way switching valve 27 to the air cooling heat exchange side and returns to step 1.
[0027]
As described above, in the refrigerator according to the embodiment, the drain water in the drain container 32 can be efficiently evaporated by heating with the high-temperature refrigerant discharged from the compressor 16. Therefore, the volume of the drain container 32 can be reduced. Moreover, the refrigerant | coolant is water-cooled with the drain evaporation pipe 26, and the temperature of a refrigerant | coolant can be reduced more efficiently than the case of air cooling. As a result, the cooling efficiency of the refrigeration cycle can be improved. In particular, the refrigerant can be efficiently cooled by switching the three-way switching valve 27 with or without water in the drain container 32.
[0028]
Next, a second embodiment of the refrigerator in the present invention will be described. FIG. 7 is an explanatory diagram of the refrigerant circuit of the second embodiment of the refrigerator according to the present invention. In the description of the second embodiment, the same reference numerals are given to the components corresponding to the components of the first embodiment, and the detailed description thereof is omitted.
[0029]
In the first embodiment described above, the drain evaporation pipe 26 is provided in the first stage cycle of the refrigeration cycle. In the second embodiment, the drain evaporation pipe 46 is provided in the second stage cycle of the refrigeration cycle. Is provided. The drain evaporation pipe 46 is provided in the refrigerant circuit from the second-stage discharge port 16 c of the compressor 16 to the secondary air-cooling heat exchanger 17 b of the air-cooling heat exchanger 17. Further, instead of the three-way switching valve 27 of the first embodiment, a three-way switching valve 47 as a bypass switching valve is provided on the downstream side of the drain evaporation pipe 46, that is, the refrigerant from the drain evaporation pipe 46 to the secondary air-cooling heat exchanger 17b. An air-cooling heat exchange side (state shown in FIG. 7) for flowing the refrigerant from the drain evaporation pipe 46 to the secondary air-cooling heat exchanging portion 17b by the three-way switching valve 47 provided in the circuit, and from the drain evaporation pipe 46 The refrigerant can be switched to a bypass side that bypasses the secondary air-cooling heat exchange unit 17 b and flows to the dew prevention pipe 19.
[0030]
The drain evaporation pipe 46 and the three-way switching valve 47 of the second embodiment perform substantially the same operation as the drain evaporation pipe 26 and the three-way switching valve 27 of the first embodiment. That is, the drain water accumulated in the drain container 32 is heated and evaporated by the high-temperature refrigerant in the drain evaporation pipe 46. When there is drain water in the drain container 32 and the high-temperature refrigerant in the drain evaporation pipe 46 is cooled by this drain water, the three-way switching valve 47 is switched to the bypass side, and the refrigerant that has passed through the drain evaporation pipe 46 Bypasses the secondary air-cooling heat exchanger 17b.
[0031]
On the other hand, when there is no drain water in the drain container 32, the three-way switching valve 47 is switched to the air-cooling heat exchange side, and the refrigerant that has passed through the drain evaporation pipe 46 passes through the secondary air-cooling heat exchange unit 17b, It flows into the anti-sticking pipe 19. The switching flow by the control device 41 is substantially the same as that of the first embodiment except that the three-way switching valve 27 is replaced with the three-way switching valve 47.
[0032]
Next, a third embodiment of the refrigerator in the present invention will be described. FIG. 8 is an explanatory diagram of a refrigerant circuit according to a third embodiment of the refrigerator according to the present invention. FIG. 9 is a flowchart of the operation of the blower for the primary air-cooling heat exchange unit. In the description of the third embodiment, the same reference numerals are assigned to the components corresponding to the components of the first embodiment, and the detailed description thereof is omitted.
[0033]
In the first embodiment described above, when the drain vessel 32 has water, the three-way switching valve 27 is provided so as not to air-cool the refrigerant in the primary air-cooling heat exchanger 17a. In the third embodiment, the fans 51 and 52 are provided for the primary air-cooling heat exchange unit 17a and the secondary air-cooling heat exchange unit 17b without providing the three-way switching valve 27, respectively. The blowers 51 and 52 are substantially linked to the compressor 16 in the same manner as the air-cooling heat exchanger blower 18 described above. However, when there is water in the drain vessel 32, the blower for the primary air-cooling heat exchange unit 17a. 51 is stopped.
[0034]
The operation flow of the primary air-cooling heat exchanger air blower 51 will be described based on the flowchart of FIG.
In step 11, the control device 41 determines whether or not the compressor 16 is in an operating state. On the other hand, when the compressor 16 is stopped, the process returns to step 11.
[0035]
In step 12, the control device 41 determines whether or not there is water in the drain container 32 based on the detection signal from the water detection sensor 36. If there is, the control device 41 goes to step 13 and controls the control device 41. Stops the blower 51 and returns to Step 11. On the other hand, when there is no drain water, it goes to step 14 and the control device 41 operates the blower 51 and returns to step 11.
[0036]
In this way, the control device 41 stops the blower 51 when the compressor 16 is in an operating state and there is water in the drain container 32, while the compressor 16 is in an operating state and the drain water is If not, the control device 41 operates the blower 51.
[0037]
As described above, the control device 41 (1) means for switching the bypass switching valve to the bypass side when the water detection means detects water in the drain container, and (2) the water detection means is in the drain container. When the water is not detected, means for switching the bypass switching valve to the air-cooling heat exchange side is provided.
As described above, the control device 41 includes means for executing each action corresponding to each action to be executed, in addition to the above means. Moreover, it is not always necessary to have all the means.
[0038]
Although the embodiments of the present invention have been described in detail above, the present invention is not limited to the above-described embodiments, and various modifications can be made within the scope of the gist of the present invention described in the claims. Can be done. Examples of modifications of the present invention are illustrated below.
(1) The refrigerant of the refrigeration cycle can be appropriately selected. However, CO ₂ Is the best.
[0039]
(2) The type and structure of the refrigerator can be selected as appropriate, but is preferably for home use. In addition, the refrigerator can include not only a refrigerator compartment but also a freezer compartment.
(3) The decompression device is composed of an expansion valve and a capillary tube, but other configurations are possible.
(4) In this embodiment, the compressor is a two-stage compression type, but a single-stage compression type is also possible. In the case of the single-stage compression type, the refrigeration cycle has only the second-stage cycle without the first-stage cycle.
[0040]
(5) In this embodiment, the internal heat exchanger 20 is provided, but the capillary tube 22 and the refrigerant pipe 21 on the low-pressure side of the refrigeration cycle are brought into close contact with each other to perform the function of the internal heat exchanger 20. It is also possible to let It is also possible not to provide the internal heat exchanger 20.
(6) If the water detection sensor 36 can detect whether or not the drain container 32 has water, the form can be selected as appropriate. For example, a water level gauge or a water temperature gauge is also possible. In the case of a water thermometer, if water is present, the temperature is lower than the atmospheric temperature. Therefore, it is understood that water is present if the temperature detected by the water thermometer is low.
[0041]
(7) If the drain water in the drain container 32 can be heated by the drain evaporation pipe 26, the heating structure can be appropriately changed. In this embodiment, the drain evaporation pipe 26 is disposed in the drain container 32. However, for example, the drain evaporation pipe 26 can be piped in a state of being in contact with the outside of the drain container 32. Further, it is also possible to heat the drain water in the drain container 32 by sending hot air from the drain evaporation pipe 26 to the drain container 32 by a blower. In addition, it is preferable that the drain evaporation pipe 26 is disposed in the drain container 32 or is piped in contact with the outside of the drain container 32 so that the drain evaporation pipe 26 can be cooled with drain water.
(8) The defrosting means for melting the frost adhering to the cooler 24 can be a means other than the defrost heater 29. For example, it is possible to defrost with hot gas.
(9) In the third embodiment, the drain evaporation pipe 26 is provided between the second-stage discharge port 16c of the compressor 16 and the secondary air-cooling heat exchanger 17b in the same manner as in the second embodiment. It is also possible. And when there exists water of the drain container 32, the control apparatus 41 stops the air blower 52 for secondary air-cooling heat exchange parts instead of the air blower 51 for primary air-cooling heat exchange parts.
[0042]
【The invention's effect】
According to the first aspect of the present invention, the high-temperature refrigerant from the first-stage discharge port of the compressor flows through the drain evaporation pipe to evaporate the drain water in the drain container. Therefore, the drain water in the drain container can be efficiently evaporated by effectively utilizing the heat of the refrigerant that has been compressed to a high temperature. As a result, the capacity of the drain container can be reduced.
In addition, the drain water in the drain container can efficiently cool the refrigerant in the first-stage refrigeration cycle. As a result, the cooling efficiency of the refrigeration cycle can be improved.
[0043]
Furthermore, a dew prevention pipe is provided in the refrigerant circuit from the secondary air-cooling heat exchange part of the refrigeration cycle to the decompression device, and this dew prevention pipe efficiently prevents dew from the front of the heat insulating box. be able to.
[0044]
Claim 2 According to the described invention, further, when the water detection means detects water in the drain container, the bypass switching valve is switched to the bypass side, and the refrigerant cooled by the drain water passes through the primary air cooling heat exchange unit. Bypassing is flowing. Therefore, it is possible to prevent the refrigerant cooled by the drain water from being warmed by the primary air cooling heat exchange unit.
[0045]
Claim 3 According to the described invention, when the water detection means detects water in the drain container, the blower for the primary air-cooling heat exchange unit is stopped, and the refrigerant cooled with the drain water becomes the primary air-cooling heat. Reduces heat exchange with air at the exchange. Therefore, it is possible to prevent the refrigerant cooled by the drain water from being warmed by the primary air cooling heat exchange unit as much as possible.
[0046]
Claim 4 According to the described invention, high-temperature refrigerant from the second-stage discharge port of the compressor flows through the drain evaporation pipe to evaporate the drain water in the drain container. Therefore, the drain water in the drain container can be efficiently evaporated by effectively utilizing the heat of the refrigerant that has been compressed to a high temperature. As a result, the capacity of the drain container can be reduced. Further, when the water detecting means detects water in the drain container, the secondary air cooling heat exchanger blower is stopped, and the refrigerant cooled by the drain water is separated from the air in the secondary air cooling heat exchanger. Heat exchange is reduced. Therefore, it is possible to prevent the refrigerant cooled by the drain water from being warmed by the secondary air cooling heat exchange unit as much as possible.
[Brief description of the drawings]
FIG. 1 is an explanatory diagram of a refrigerant circuit according to a first embodiment of a refrigerator according to the present invention.
FIG. 2 is a diagram of a specific example of the refrigerant circuit of the refrigerator in FIG.
FIG. 3 is a diagram of a dew prevention pipe in FIG. 2;
FIG. 4 is an input / output diagram of the control device.
FIG. 5 is an explanatory diagram of the refrigerant circuit according to the first embodiment in a state in which the switching valve is switched to the bypass side.
FIG. 6 is a flowchart of the operation of the switching valve.
FIG. 7 is an explanatory diagram of a refrigerant circuit according to a second embodiment of the refrigerator according to the present invention.
FIG. 8 is an explanatory diagram of a refrigerant circuit according to a third embodiment of the refrigerator according to the present invention.
FIG. 9 is a flowchart of the operation of the blower for the primary air-cooling heat exchange unit.
[Explanation of symbols]
1 Insulation box
16 Compressor
16a First stage outlet
16b Second stage inlet
16c Second stage outlet
16d first stage inlet
17 Air-cooled heat exchanger
17a Primary air cooling heat exchanger
17b Secondary air cooling heat exchanger
19 Dew prevention pipe
21 Refrigerant piping
22 Capillary tube (pressure reduction device)
23 Electric expansion valve (pressure reduction device)
24 Cooler
26 Drain evaporation pipe
27 Three-way switching valve (bypass switching valve)
29 Defrost heater (defrost means)
32 Drain container
36 Water detection sensor (water detection means)
41 Control device (control means)
47 Three-way switching valve (bypass switching valve)
51 Blower for primary air-cooling heat exchanger
52 Blower for secondary air cooling heat exchanger

Claims (4)

In the refrigerator whose outer shell is composed of a heat insulating box and whose front opening is closed with a heat insulating door so that it can be opened and closed,
Primary compression mechanism that compresses refrigerant from the first-stage inlet and discharges it from the first-stage outlet, and secondary compression that compresses refrigerant from the second-stage inlet and discharges it from the second-stage outlet A compressor having a mechanism;
From the discharge port of the first stage of the compressor, it returns to the second stage inlet of the compressor through a primary air-cooling heat exchange unit in which the gaseous refrigerant compressed to a high temperature and pressure by the primary compression mechanism of the compressor is air-cooled. The first refrigeration cycle,
A secondary air-cooling heat exchange section in which the gaseous refrigerant compressed to a high temperature and high pressure by the secondary compression mechanism is air-cooled while changing its state in the supercritical region, a decompression device, and a second-stage discharge port of the compressor A second-stage refrigeration cycle that returns to the first-stage inlet of the compressor through a cooler that cools the interior with the refrigerant that has been decompressed by the decompression device and has a low temperature,
Defrosting means for melting frost adhering to the cooler;
A drain container into which drain water melted by the defrosting means flows,
A drain evaporating pipe for allowing the refrigerant of the refrigeration cycle to flow and evaporating the drain water in the drain container;
The drain evaporation pipe is provided in the refrigerant circuit from the first stage outlet of the compressor of the first stage refrigeration cycle to the primary air-cooling heat exchange unit ;
A refrigerator characterized in that a dew prevention pipe for preventing dew from the front of the heat insulating box is provided in a refrigerant circuit from a secondary air cooling heat exchange part of a refrigeration cycle to a decompression device . In the refrigerator whose outer shell is composed of a heat insulating box and whose front opening is closed with a heat insulating door so that it can be opened and closed,
Primary compression mechanism that compresses refrigerant from the first-stage inlet and discharges it from the first-stage outlet, and secondary compression that compresses refrigerant from the second-stage inlet and discharges it from the second-stage outlet A compressor having a mechanism;
From the discharge port of the first stage of the compressor, it returns to the second stage inlet of the compressor through a primary air-cooling heat exchange unit in which the gaseous refrigerant compressed to a high temperature and pressure by the primary compression mechanism of the compressor is air-cooled. The first refrigeration cycle,
A secondary air-cooling heat exchange section in which the gaseous refrigerant compressed to a high temperature and high pressure by the secondary compression mechanism is air-cooled while changing its state in the supercritical region, a decompression device, and a second-stage discharge port of the compressor A second-stage refrigeration cycle that returns to the first-stage inlet of the compressor through a cooler that cools the interior with the refrigerant that has been decompressed by the decompression device and has a low temperature,
Defrosting means for melting frost adhering to the cooler;
A drain container into which drain water melted by the defrosting means flows,
A drain evaporating pipe for allowing the refrigerant in the refrigeration cycle to flow and evaporating the drain water in the drain container ;
Water detection means for detecting the presence or absence of water in the drain container;
A bypass switching valve provided in the refrigerant circuit from the drain evaporation pipe to the primary air-cooling heat exchange unit, for switching the flow of refrigerant and bypassing the primary air-cooling heat exchange unit;
A control means for switching the bypass switching valve to the bypass side when the water detection means detects water in the drain container;
The refrigerator, wherein the drain evaporation pipe is provided in a refrigerant circuit from a first-stage discharge port of a compressor of the first-stage refrigeration cycle to a primary air-cooling heat exchange unit . In the refrigerator whose outer shell is composed of a heat insulating box and whose front opening is closed with a heat insulating door so that it can be opened and closed,
Primary compression mechanism that compresses refrigerant from the first-stage inlet and discharges it from the first-stage outlet, and secondary compression that compresses refrigerant from the second-stage inlet and discharges it from the second-stage outlet A compressor having a mechanism;
From the discharge port of the first stage of the compressor, it returns to the second stage inlet of the compressor through a primary air-cooling heat exchange unit in which the gaseous refrigerant compressed to a high temperature and pressure by the primary compression mechanism of the compressor is air-cooled. The first refrigeration cycle,
A secondary air-cooling heat exchange section in which the gaseous refrigerant compressed to a high temperature and high pressure by the secondary compression mechanism is air-cooled while changing its state in the supercritical region, a decompression device, and a second-stage discharge port of the compressor A second-stage refrigeration cycle that returns to the first-stage inlet of the compressor through a cooler that cools the interior with the refrigerant that has been decompressed by the decompression device and has a low temperature,
Defrosting means for melting frost adhering to the cooler;
A drain container into which drain water melted by the defrosting means flows,
A drain evaporating pipe for allowing the refrigerant in the refrigeration cycle to flow and evaporating the drain water in the drain container ;
A blower for a primary air-cooling heat exchange unit that air-cools the refrigerant of the primary air-cooling heat exchange unit;
A blower for a secondary air-cooling heat exchange unit that air-cools the refrigerant of the secondary air-cooling heat exchange unit;
Water detection means for detecting the presence or absence of water in the drain container;
When this water detection means detects the water in the drain container, it comprises a control means for stopping the blower for the primary air-cooling heat exchange unit,
The refrigerator, wherein the drain evaporation pipe is provided in a refrigerant circuit from a first-stage discharge port of a compressor of the first-stage refrigeration cycle to a primary air-cooling heat exchange unit . In the refrigerator whose outer shell is composed of a heat insulating box and whose front opening is closed with a heat insulating door so that it can be opened and closed,
Primary compression mechanism that compresses refrigerant from the first-stage inlet and discharges it from the first-stage outlet, and secondary compression that compresses refrigerant from the second-stage inlet and discharges it from the second-stage outlet A compressor having a mechanism;
From the discharge port of the first stage of the compressor, it returns to the second stage inlet of the compressor through a primary air-cooling heat exchange unit in which the gaseous refrigerant compressed to a high temperature and pressure by the primary compression mechanism of the compressor is air-cooled. The first refrigeration cycle,
A secondary air-cooling heat exchange section in which the gaseous refrigerant compressed to a high temperature and high pressure by the secondary compression mechanism is air-cooled while changing its state in the supercritical region, a decompression device, and a second-stage discharge port of the compressor A second-stage refrigeration cycle that returns to the first-stage inlet of the compressor through a cooler that cools the interior with the refrigerant that has been decompressed by the decompression device and has a low temperature,
Defrosting means for melting frost adhering to the cooler;
A drain container into which drain water melted by the defrosting means flows,
A drain evaporating pipe provided in the refrigerant circuit from the second stage discharge port of the compressor of the second stage refrigeration cycle to the secondary air-cooling heat exchanger, and for allowing the refrigerant of the refrigeration cycle to flow and evaporate the drain water in the drain container; ,
A blower for a primary air-cooling heat exchange unit that air-cools the refrigerant in the primary air-cooling heat exchange unit;
A blower for a secondary air-cooling heat exchange unit that air-cools the refrigerant of the secondary air-cooling heat exchange unit;
Water detection means for detecting the presence or absence of water in the drain container;
And a control means for stopping the blower for the secondary air-cooling heat exchange section when the water detection means detects water in the drain container.

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