JP2013133981A - Refrigeration system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To solve the problem that a refrigeration container makes much operation noise when used as a stationary cold store in a residence area or the like and the problem that a standby unit of a vehicle-mounted refrigerator is installed under a floor in a conventional freezer and thereby the use of a cold store is hindered by any underfloor parts when only the cold storage of a refrigerator vehicle is used as the cold store.SOLUTION: Because a refrigerator unit 5 and the standby unit 7 are tightly installed at the face 9 of a front wall of the cold store 1 (concentrated arrangement), it is possible to eliminate underfloor parts from an underfloor space of the cold store 1. Owing to this, it is possible to shorten a wire harness 6 for wiring between the refrigerator unit 5 and a power control unit PU and refrigerant pipelines 16, 17 connecting the refrigerator unit 5 and a motor unit MU. As a result, a refrigeration capacity of the refrigerator 2 is increased and the refrigerator unit 5 and standby unit 7 are well arranged in the cold store 1.

Description

  The present invention relates to a refrigeration apparatus that cools air in a cold storage warehouse (refrigerated warehouse) placed at a place of use.

As a social need, refrigerated warehouses are urgently needed to recover from the earthquake disaster at fisheries establishments where cold storage warehouses (frozen warehouses) have collapsed due to the earthquake. However, it takes a lot of money and time to build a new refrigerated warehouse.
As a conventional technique, there is a refrigerated container for transporting vehicles that can be used simply as a refrigerated warehouse (see, for example, Patent Document 1).
This is mainly used for low-temperature transport on ships and railroads, so transport and temperature management can be easily performed. For example, a refrigerated container is used as a refrigerated warehouse placed in a use place such as a residential area. Therefore, there is a problem that driving noise, particularly fan noise is large, and the place of use is limited.

Therefore, it is possible to use a vehicle-mounted refrigerator unit designed for use in low noise environments such as residential areas and a vehicle-mounted freezer as a freezer warehouse. The unit and the in-vehicle freezer cannot be used.
As shown in FIG. 4, the freezing vehicle 100 is used for the purpose of transporting an object to be frozen such as frozen food without increasing the temperature, and obtains power from an internal combustion engine (engine) to drive the compressor 101. During pre-cooling before loading, when the engine is stopped and the engine is stopped, the stand-by unit is used for freezing operation.
The standby unit includes a motor unit 102 including an electric motor that drives a standby compressor, and a power control unit that supplies DC power obtained by converting and rectifying commercial AC power to the motor unit 102 and the refrigerator unit 103. 104.
However, since the standby unit is an underfloor component mounted under the floor of the freezer 105, the freezer 105 cannot be used as a stationary freezer warehouse with the current mounting position and mounting method.

In addition, when the freezer 105 is used as a freezer warehouse, it is necessary to transport to a place of use, and there is a legal height restriction during transportation, and the size of the freezer 105 is limited. For this reason, in the structure where the standby unit is mounted under the floor of the freezer 105, the capacity in the height direction of the freezer 105 is greatly limited.
Furthermore, since the mounting position of the standby unit varies depending on the mounted vehicle, such as between the wheel bases and the rear end of the vehicle, the refrigerator vehicle 100 with the standby unit is mounted at a position farthest from the refrigerator unit 103. There is a problem that the wire harness 106 that connects the refrigerator unit 103 and the power supply control unit 104, the refrigerant pipe 107 that connects the motor unit 102 and the refrigerator unit 103, and the like become very long.
Therefore, the pressure loss of the refrigerant flow passing through the refrigerant pipe 107 connecting the evaporator in the refrigerator unit 103 to the standby compressor in the motor unit 102 increases, and the refrigerating capacity of the refrigerator (refrigeration cycle) in the freezer 105 is increased. There is a problem of lowering.
Further, there is a problem that the refrigerator unit 103 and the standby unit for the refrigeration warehouse are poorly mounted.

Japanese Utility Model Publication No. 6-2076 Japanese Patent No. 4462039

An object of the present invention is to provide a refrigeration apparatus that can eliminate underfloor parts by installing a compressor unit, an evaporator unit, and a power supply control unit all on one side of a warehouse and in the vicinity thereof.
In addition, by eliminating the underfloor parts, a refrigeration system that can shorten the electrical wiring and refrigerant piping from the refrigerator to the compressor unit and the power supply control unit, and improve the refrigeration capacity and bodywork of the refrigerator. It is to provide.

The invention (refrigeration apparatus) described in claim 1 includes a refrigerator that cools air in a warehouse placed at a place of use.
The refrigerator has an evaporator that evaporates the refrigerant and cools the air in the warehouse, and an evaporator blower that blows air to the evaporator, and the air cooled by heat exchange with the refrigerant in the evaporator is stored in the warehouse. It has an evaporator unit for forced circulation inside.
Refrigerator uses a compressor that compresses and discharges refrigerant sucked from the evaporator, a compressor unit having an electric motor that drives the compressor, and a commercial power source for the evaporator unit and the compressor unit And a power supply control unit for supplying the generated power.
The evaporator unit, the compressor unit, and the power supply control unit are concentrated on one side surface of the polyhedral warehouse and the vicinity thereof.

According to the first aspect of the present invention, the evaporator unit, the compressor unit, and the power supply control unit are centrally installed (centrally arranged) on one side surface of the polyhedral warehouse and in the vicinity thereof. Underfloor parts mounted under the floor of the in-vehicle freezer can be eliminated. As a result, the electrical wiring (wire harness) that electrically connects the power supply control unit and the evaporator unit and the refrigerant piping that connects the evaporator unit and the compressor unit are significantly shortened compared to conventional in-vehicle freezers. can do. Therefore, since the pressure loss of the refrigerant flow passing through the refrigerant pipe connecting the evaporator and the compressor can be reduced, the refrigeration capacity of the refrigerator can be improved, and the evaporator unit, the compressor unit and the power supply control for the warehouse The mountability of the unit can be improved.
In addition, even if there is a legal height restriction when transporting the warehouse, as described above, by arranging the evaporator unit, the compressor unit and the power supply control unit centrally on one side of the warehouse and in the vicinity thereof, Since there are no underfloor parts from the bottom of the warehouse, a sufficient capacity in the height direction of the cold insulation space formed in the warehouse can be secured.

According to invention of Claim 2, the commercial alternating current power supply which can supply alternating current power is used as a city power supply. Moreover, the electric power using a commercial power supply is the electric power obtained by converting a commercial AC power supply.
The object of the invention described in claim 3 is to use a vehicle-mounted refrigerator originally designed for low noise in consideration of use in a low noise environment such as a residential area as a warehouse refrigerator. It is an object of the present invention to provide a refrigeration apparatus that can be used as a stationary warehouse.
According to the invention described in claim 3, by using a vehicle-mounted refrigerator driven by DC power obtained by converting the voltage of a commercial AC power supply and rectifying it as a refrigerator, low noise in a residential area or the like. Under the environment, it can be used as a cold storage warehouse such as a freezing warehouse or a refrigerated warehouse.

According to the invention described in claim 4, as a warehouse, for example, as a cold storage warehouse such as a freezer warehouse or a refrigerated warehouse, in a low noise environment such as a residential area, by using a cold box equipped with an in-vehicle refrigerator. Can be used.
For example, an in-vehicle cooler with a medium size refrigerator has a length of 20 feet (6 m) in the longitudinal direction and a volume of 26.18 m ³ , so a large evaporator blower with a large operating noise is not used. However, the refrigeration capacity in the warehouse can be fully demonstrated.
Therefore, by using an in-vehicle refrigerator as a refrigerator and using an in-vehicle cold storage as a cold storage, it is possible to construct a cold storage warehouse that is less expensive and has a shorter delivery time than a new cold storage building. It becomes possible.

According to the fifth aspect of the present invention, a polyhedral cold storage warehouse in which a rectangular parallelepiped cold storage space is formed is used as the warehouse. Further, one side surface of the warehouse is a wall body located on one side in the longitudinal direction of the cold insulation space (for example, the forward side of the vehicle during vehicle transportation, that is, the front side).
Note that one side of the warehouse may be a single wall body that is not provided with an opening / closing door that opens and closes when a frozen object such as frozen food is carried in and out of the cold storage space. In this case, the refrigerator unit and the standby unit do not interfere with carrying in / out the frozen object such as frozen food.
According to the invention described in claim 6, the compressor unit and the power supply control unit are supported (mounted) on the frame additionally installed in the warehouse. Thereby, since the underfloor parts can be abolished, even if the cold storage is removed from the freezer and used as it is as a warehouse, the underfloor parts do not get in the way and the capacity in the height direction in the warehouse can be secured. In addition, the standby unit can be easily installed in the warehouse.

According to the invention described in claim 7, the frame additionally installed in the warehouse has a protruding frame attached to one side of the warehouse so as to protrude from one side of the warehouse toward one side. .
The compressor unit and the power supply control unit are mounted on the projecting frame in a state of being suspended from the projecting frame. As a result, the standby unit (compressor unit and power supply control unit), which has conventionally been an underfloor component, can be suspended from the protruding frame and installed without changing the design. Moreover, it becomes easy to install the standby unit (compressor unit and power supply control unit) in the warehouse.

According to invention of Claim 8, it has the several base frame installed in the downward direction of a warehouse in the flame | frame additionally installed in the warehouse.
A warehouse is mounted on the plurality of pedestal frames. Accordingly, when the polyhedral warehouse is stationaryly installed at the use place, the warehouse can be easily installed horizontally even if the use place is not flat.
According to the ninth aspect of the present invention, each of the plurality of pedestal frames has a protruding portion that protrudes from one side surface of the warehouse toward one side.
The frame additionally installed in the warehouse has a connecting frame that connects the protruding portions of the plurality of pedestal frames.
A compressor unit and a power supply control unit are mounted on the connection frame. Accordingly, when the polyhedral warehouse is stationaryly installed at the use place, the warehouse can be easily installed horizontally even if the use place is not flat. In addition, it is easy to install the standby unit (compressor unit and power supply control unit) on the connecting frame as it is without changing the design of the standby unit (compressor unit and power supply control unit) which has conventionally been underfloor parts.

According to the invention described in claim 10, the evaporator unit may be fixed (installed) on one side surface of the warehouse so as to protrude from one side surface of the warehouse toward one side. In this case, since the evaporator unit of the in-vehicle refrigerator can be used as it is, it is not necessary to newly install the evaporator unit, and the cost is reduced.
According to the invention of claim 11, as a refrigerator in a warehouse, a condenser unit having a condenser for condensing refrigerant discharged from the compressor and a condenser fan for blowing air to the condenser is installed. May be.
According to the invention described in claim 12, a refrigerator unit in which an evaporator unit and a condenser unit are integrated may be used as a refrigerator in a warehouse. In this case, a frame for supporting the condenser unit is not necessary, and the cost is reduced.

According to the invention described in claim 13, the refrigerator unit may be fixed (installed) on one side surface of the warehouse so as to protrude from one side surface of the warehouse toward one side. In this case, since the vehicle-mounted refrigerator unit in which the evaporator unit and the condenser unit are integrated can be used as they are, it is not necessary to newly install the refrigerator unit and the cost is reduced.
According to the fourteenth aspect of the present invention, the commercial AC power source, which is a commercial power source, is converted into a voltage for the evaporator unit, the condenser unit, and the compressor unit as a standby unit for a warehouse refrigerator, and is rectified. A power supply control unit for supplying DC power obtained in this way is provided.
In this case, after converting the AC voltage supplied from the commercial AC power source to the AC voltage used in the evaporator unit, the condenser unit and the compressor unit, the AC power is full-wave rectified to obtain DC power. May be.
Alternatively, the AC power supplied from the commercial AC power source may be frequency converted to drive the evaporator unit, the condenser unit, and the compressor unit.
Moreover, you may make it drive an evaporator unit, a condenser unit, and a compressor unit using the alternating current frequency supplied from commercial alternating current power as it is.

It is the perspective view which showed the freezing apparatus of the freezer warehouse (Example 1). It is sectional drawing which showed the freezing apparatus of the freezer warehouse (Example 1). (Example 2) which is the perspective view which showed the freezing apparatus of the freezer warehouse. It is the perspective view which showed the freezer car (conventional technique).

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
The present invention pays attention to the fact that the in-vehicle refrigerator is designed with low noise in consideration of use in a low noise environment such as a residential area. By using it as a refrigerator to be cooled (a refrigerator in a refrigeration warehouse), it solves problems related to operational noise.
In addition, for the purpose of solving the installation problem that the stand-by unit of the in-vehicle freezer is mounted under the floor and the underfloor parts get in the way to use only the cold storage from the freezer as a freezer warehouse, Provided is a refrigeration apparatus which can secure the capacity in the height direction of the cold storage by eliminating the underfloor parts and can be easily installed without changing the design of the standby unit.
The on-vehicle refrigerator is a DC power obtained by rectifying commercial AC power, which is a commercial power source such as an external power supply facility, or a DC power obtained by rectifying the commercial AC power after voltage conversion. Refrigeration equipment for each unit to be driven.
As refrigeration equipment, there are an electric motor for driving a compressor, an electric motor for an evaporator fan, and an electric motor for a condenser fan.

[Configuration of Example 1]
1 and 2 show a refrigeration apparatus (Example 1) of a refrigeration warehouse to which the present invention is applied.

As shown in FIG. 1, the refrigeration apparatus of the present embodiment is a refrigerator that cools air in a multi-sided (six-sided) body-shaped freezing warehouse 1 placed in a use place such as a residential area. (Refrigerator) 2 is provided.
The inside of the freezer warehouse 1 is a rectangular parallelepiped-shaped cold storage space (hereinafter referred to as cold storage) that stores frozen objects such as frozen foods and keeps them cold (frozen or refrigerated) for the purpose of storing frozen objects such as frozen foods for a long period of time. Chamber) is formed.
The freezer warehouse 1 has a ceiling wall that closes the upper opening of the cold storage room, a bottom wall (floor) that closes the lower opening of the cold storage room, front and rear walls respectively installed on both sides in the longitudinal direction of the cold storage room, It is comprised by the right-and-left side wall each installed in the both sides of the transversal direction of a cold storage room.

The freezer warehouse 1 is configured by a heat insulating wall (heat insulating panel) that blocks heat entering from the outside. That is, the ceiling wall, the bottom wall, the front and rear walls, and the left and right side walls are all heat insulating panels in which a heat insulating material (for example, hard urethane foam) is sandwiched between an aluminum metal outer plate and an aluminum metal inner plate. It is constituted by.
The front wall corresponds to one aspect of the warehouse of the present invention. When the freezer warehouse 1 is transported to a place of use by a vehicle such as a truck, the front wall is on the front side of the vehicle (the front side in the longitudinal direction of the freezer warehouse 1). It is a wall body (a wall of a warehouse) to be placed. Moreover, the opening part (opening part of the front wall of a warehouse) 3 in which the refrigerator unit mentioned later is inserted is opened in the upper part of the front wall.
The rear wall is a wall body located on the rear side of the vehicle when the refrigerated warehouse 1 is transported to a place of use by a vehicle such as a truck. Further, one side surface of the rear wall is an outer surface of the rear wall (hereinafter referred to as a rear surface).
The rear wall is provided with an open / close door that opens and closes in the form of a double door. The frozen warehouse 1 opens and closes the door to carry in the frozen room such as frozen food into the cold room and carry out the frozen object such as frozen food from the cold room.

As shown in FIGS. 1 and 2, the refrigerator 2 mounted in the freezer warehouse 1 of the present embodiment includes a control panel 4 having a temperature setting unit that sets the internal temperature of the freezer warehouse 1 to a desired temperature, The refrigeration unit 5 forcibly circulates the air cooled by heat exchange with the refrigerant circulating in the refrigeration cycle in the refrigeration warehouse 1 and the DC power obtained by rectifying the commercial AC power source that is a commercial power source, A standby unit 7 that supplies electric motors (described later) of the refrigeration equipment via a harness (electrical wiring) 6 and a unit mounting frame 8 that supports the standby unit 7 are provided.
The control panel 4 is installed on the front surface 9 of the front wall of the freezer warehouse 1. The control panel 4 is provided with an operation switch for instructing start and stop of the refrigeration apparatus and a temperature display unit for displaying the internal temperature of the freezer warehouse 1.
In the refrigerator unit 5, an evaporator (evaporator) unit EU and a condenser (condenser) unit CU are integrated.
The standby unit 7 includes a compressor unit (hereinafter referred to as a motor unit) MU and a power supply control unit PU.

The refrigerating cycle of the refrigerator 2 includes a compressor 11 that compresses and discharges the refrigerant, a condenser 12 that condenses the refrigerant discharged from the compressor 11, and a liquid receiver that separates the refrigerant that has flowed out of the condenser 12 into gas and liquid. , An expansion valve 14 which is a decompression means for decompressing and expanding the liquid refrigerant flowing out from the liquid receiver 13, an evaporator 15 for evaporating the gas-liquid two-phase refrigerant flowing out from the expansion valve 14, and an annular connection thereof The refrigerant pipes 16 and 17 are provided.
The motor unit MU is provided with a compressor 11 and an electric motor 21 that is an electric motor that rotationally drives the rotation shaft of the compressor 11.

The condenser unit CU is provided with a condenser 12, a condenser blower, and a liquid receiver 13. The condenser blower includes a condenser fan 18 that blows air to the condenser 12, an electric motor 22 that is an electric motor that rotationally drives the rotating shaft of the condenser fan 18, and the like.
In the evaporator unit EU, an expansion valve 14, an evaporator 15 and an evaporator fan are installed. The evaporator blower includes an evaporator fan 19 that blows air to the evaporator 15, and an electric motor 23 that is an electric motor that rotationally drives the rotating shaft of the evaporator fan 19.
The details of the refrigeration cycle of the refrigerator 2, the refrigeration equipment, and the electric motors 21 to 23 that are power sources will be described later.

The standby unit 7 is mounted on the unit mounting frame 8 while being suspended from the unit mounting frame 8. As described above, the standby unit 7 converts the commercial AC power supply into voltage for the evaporator unit EU, the condenser unit CU, and the motor unit MU, and rectifies the AC power that has been converted into voltage. Is provided with a power supply control unit PU.
The power supply control unit PU is a power supply control box including a power supply conversion device 25 that is electrically connected to a commercial AC power supply via a power supply cable 24, a power supply control device 26 that controls the power supply conversion device 25, and the like. .
A plug 27 that can be inserted into an outlet capable of supplying commercial AC power is provided at the tip of the power supply cable 24.

The power converter 25 includes a transformer that adjusts an AC voltage (AC: 200 V) supplied from a ground power supply (commercial AC power supply), and a rectifier that converts an AC current supplied from the commercial AC power supply into a DC current. Etc. The power converter 25 converts an AC voltage supplied from a commercial AC power source into a DC voltage (DC: 24V) used in the electric motors 21 to 23 using a transformer and a rectifier.
The power supply control device 26 includes a microcomputer that includes functions such as a CPU, a ROM, and a RAM. The power supply control device 26 receives a switch signal (set temperature signal) from the temperature setting unit of the control panel 4 and a sensor output signal (internal temperature signal) from the internal temperature sensor 28 by an A / D converter. After being / D converted, it is configured to be input to a microcomputer.
The temperature setting unit of the control panel 4 is temperature setting means for setting the internal temperature of the freezer warehouse 1.
The internal temperature sensor 28 is a temperature detection unit that detects the internal temperature of the freezer warehouse 1.

While the operation switch is turned on, the microcomputer outputs a control signal to the control panel 4 so that the internal temperature detected by the internal temperature sensor 28 is displayed on the temperature display unit.
The microcomputer starts the electric motors 21 to 23 when the internal temperature detected by the internal temperature sensor 28 is higher than the set temperature (target refrigeration or refrigeration temperature) set by the temperature setting unit (energization: ON). (Motor starting means)
When the internal temperature detected by the internal temperature sensor 28 is lower than the set temperature set by the temperature setting unit, the microcomputer stops energization of the electric motors 21 to 23 (motor stop means). .
As described above, the internal temperature of the freezer warehouse 1 is managed by repeating ON-OFF control of the electric motors 21 to 23.

The motor unit MU includes a rectangular parallelepiped unit case. Inside the unit case are housed an electric motor 21 driven by using a commercial AC power source and a compressor 11 for compressing the refrigerant.
The electric motor 21 is a DC motor (DC motor) that generates power (torque) for rotationally driving the compressor 11 when DC power is supplied from the power converter 25 via the wire harness 6.
The compressor 11 constitutes a refrigeration cycle together with the refrigeration equipment (the condenser 12, the liquid receiver 13, the expansion valve 14, and the evaporator 15).
The compressor 11 is a compressor that is belt-driven by the electric motor 21 and compresses the refrigerant sucked from the outlet portion of the evaporator 15 through the refrigerant pipe (low-pressure pipe) 16 and discharges high-temperature and high-pressure refrigerant gas. The compressor 11 has a compressor pulley that is connected to a motor pulley fixed to the output shaft of the electric motor 21 via a transmission belt.

The refrigerator unit 5 includes a heat insulating box (refrigerator case) 33 that is a partition section that hermetically partitions the internal space 31 that stores the evaporator unit EU and the external space 32 that stores the condenser unit CU. A refrigerator cover 34 detachably attached to the refrigerator case 33 so as to cover the front surface of the refrigerator case 33 is provided.
Similar to the freezer warehouse 1, the refrigerator case 33 is configured by a heat insulating panel or the like in which a heat insulating material (for example, hard urethane foam) is sandwiched between an aluminum-based metal outer plate and an aluminum-based metal inner plate. ing.

The refrigerator case 33 is fitted and fixed in an airtight manner in the opening 3 of the front wall of the freezer warehouse 1. Inside the refrigerator case 33, an internal space 31 that houses the expansion valve 14, the evaporator 15 and the evaporator blower and communicates with the cold storage chamber is formed. In addition, the heat insulation panel on the cold room side of the refrigerator case 33 is provided with an inlet 35 for sucking air from the cold room into the interior space 31 and an outlet 36 for blowing the air that has passed through the evaporator 15 to the cold room. It has been.
The above-described internal temperature sensor 28 is installed in the vicinity of the suction port 35 of the refrigerator case 33.
The refrigerator cover 34 is made of synthetic resin. Inside the refrigerator cover 34, an outside space 32 that houses the condenser 12, the condenser fan, and the liquid receiver 13 and communicates with the outside (atmosphere) is formed. In addition, a suction port 37 for sucking air from the outside into the external space 32 is provided on the front surface of the refrigerator cover 34. In addition, an air outlet 38 that blows air that has passed through the condenser 12 to the outside is provided on the inclined surface (lower surface) of the refrigerator cover 34.

The condenser unit CU is a group of refrigeration equipment housed in the external space 32, and is a condenser 12 that condenses the refrigerant discharged from the discharge unit of the compressor 11, and a condenser that blows air to the condenser 12. And a liquid receiver 13 for gas-liquid separation of the refrigerant flowing from the outlet of the condenser 12 and the outlet of the condenser 12.
The condenser 12 is an external heat exchanger (condenser) that heats and exchanges the refrigerant that has flowed from the discharge portion of the compressor 11 via the refrigerant pipe (high-pressure pipe) 17 with air.
The liquid receiver 13 is installed in the middle of the refrigerant pipe connecting the outlet portion of the condenser 12 and the inlet portion of the evaporator 15, temporarily stores the refrigerant flowing in from the outlet portion of the condenser 12, It is a gas-liquid separator (receiver tank) that supplies only the liquid refrigerant to the evaporator unit EU according to the load. If the refrigerant is completely liquefied at the outlet of the condenser 12, the liquid receiver 13 need not be provided. Further, as a gas-liquid separator, an accumulator may be disposed between the outlet portion of the evaporator 15 and the suction portion of the compressor 11 instead of the liquid receiver 13.

The condenser blower has a condenser fan 18 and the like that are rotationally driven by an electric motor 22 that is a condenser fan motor.
The condenser fan 18 sucks outside air from the outside of the refrigerator cover 34, passes the sucked outside air through the condenser 12, and again discharges the outside air from the refrigerator cover 34.
The electric motor 22 is a DC motor (DC motor) that generates power (torque) for rotationally driving the condenser fan 18 when DC power is supplied from the power converter 25 via the wire harness 6.

The evaporator unit EU is a group of refrigeration equipment housed in the internal space 31 and is air cooled by heat exchange with the refrigerant in the evaporator 15 that evaporates the refrigerant discharged from the discharge unit of the compressor 11. Is forcibly circulated in the cool room. The evaporator unit EU has an expansion valve 14 which is a decompression means for decompressing and expanding the liquid refrigerant flowing from the outlet of the liquid receiver 13, and an evaporation for evaporating the gas-liquid two-phase refrigerant flowing from the outlet of the expansion valve 14. And an evaporator blower for blowing air to the evaporator 15.
The expansion valve 14 is installed in the middle of the refrigerant pipe connecting the outlet portion of the condenser 12 and the inlet portion of the evaporator 15, and adiabatic expansion of the liquid refrigerant flowing from the outlet portion of the receiver 13 is performed at low temperature and low pressure. Use a gas-liquid two-phase refrigerant. A fixed throttle such as a capillary tube or an orifice may be used instead of the variable throttle valve such as the expansion valve 14 as the pressure reducing means.

The evaporator 15 is an in-compartment heat exchanger (evaporator) that exchanges heat of the refrigerant flowing from the outlet of the expansion valve 14 with air to evaporate it.
The evaporator blower has an evaporator fan 19 and the like that are rotationally driven by an electric motor 23 that is an evaporator fan motor.
The evaporator fan 19 sucks the air in the cool chamber from the suction port 35 of the refrigerator case 33, passes the sucked air through the evaporator 15, and blows it out from the outlet 36 of the refrigerator case 33 into the cool chamber.
The electric motor 23 is a DC motor (DC motor) that generates power (torque) for rotationally driving the evaporator fan 19 when DC power is supplied from the power converter 25 via the wire harness 6.

[Features of Example 1]
The unit mounting frame 8 includes a protruding frame member 41 attached to the front surface 9 of the front wall of the freezer warehouse 1 so as to protrude forward from the front surface 9 of the front wall of the freezer warehouse 1.
The protruding frame material 41 is fixed to both left and right ends of the front surface 9 of the front wall of the freezer warehouse 1, and a pair of vertical base frame materials extending in the vertical direction of the front wall of the freezer warehouse 1. And a pair of horizontal base frame members extending in the horizontal (left and right) direction of the front wall of the freezer warehouse 1.
The projecting frame member 41 includes four upper and lower frame members projecting forward from the connecting portion of the vertical and horizontal base frame members, a connecting frame member connecting the tip portions of the four upper and lower frame members, and a pair of vertical base frame members. And an inclined frame member extending inclinedly from the lower end portion of the lower extension portion to the tip end portion of the lower frame member.

The standby unit 7 (power control unit PU, motor unit MU) is arranged between the horizontal base frame material and the lower frame material between the horizontal base frame material on the lower side of the protruding frame material 41 and the lower frame material of the protruding frame material 41. In a suspended state, it is mounted on the protruding frame member 41. Thereby, the standby unit 7 (power control unit PU, motor unit MU) is installed in the lower part of the front surface 9 of the front wall of the freezer warehouse 1.
The refrigerator unit 5 includes a refrigerator case 33 fixed to the upper portion of the front surface 9 of the front wall of the refrigerator warehouse 1 and a refrigerator cover 34 attached so as to cover the front surface of the refrigerator case 33.

The refrigerator unit 5 is fitted and fixed (installed) in the opening 3 of the freezer warehouse 1 so as to protrude forward from the upper part of the front surface 9 of the front wall of the freezer warehouse 1.
The condenser unit CU is accommodated and held in an external space 32 formed between the refrigerator case 33 and the refrigerator cover 34. The evaporator unit EU is accommodated and held in the internal space 31 of the refrigerator case 33.
Therefore, the standby unit 7 and the refrigerator unit 5 are concentrated on the front surface 9 of the front wall of the freezer warehouse 1.

[Operation of Example 1]
Next, the operation of the refrigeration apparatus in the refrigeration warehouse according to the present embodiment will be briefly described with reference to FIGS.

The refrigeration warehouse 1 needs to be in a frozen state at all times when storing the object to be frozen, and it is necessary to keep each refrigeration device (refrigeration cycle, condenser fan, evaporator fan) of the refrigeration apparatus in an operating state. is necessary.
A DC current or a DC voltage is applied to each of the electric motors 21 to 23 by turning on the operation switch. Thereby, the compressor 11, the condenser fan 18, and the evaporator fan 19 are rotationally driven.

When the compressor 11 is started, high-temperature and high-pressure refrigerant gas is discharged from the discharge portion of the compressor 11 and is sent to the condenser 12 through the refrigerant pipe 17.
The refrigerant gas that has flowed into the condenser 12 is taken into the external space 32 from the outside of the refrigerator cover 34 by the condenser fan 18, and is condensed by exchanging heat with the air blown to the condenser 12. Becomes a refrigerant.
The liquid refrigerant once flows into the liquid receiver 13 and then flows into the expansion valve 14. When the liquid refrigerant passes through the throttle portion of the expansion valve 14, the liquid refrigerant is decompressed and expanded into a low-temperature and low-pressure gas-liquid two-phase refrigerant. 15 is sent.
The refrigerant gas that has flowed into the evaporator 15 takes air in the cold storage chamber 31 into the interior space 31 from the suction port 35 of the refrigerator case 33 by the evaporator fan 19 and exchanges heat with the air blown to the evaporator 15. Evaporates into refrigerant gas.
Then, the refrigerant gas is sucked into the compressor 11 again through the refrigerant pipe 16.

As described above, the refrigerant circulates in the refrigeration cycle when each refrigeration device of the refrigeration apparatus is activated (started up).
Further, the air cooled to the set temperature by heat exchange with the refrigerant when passing through the evaporator 15 by the evaporator fan 19 is forcibly circulated in the cold storage chamber of the freezer warehouse 1, thereby Air is cooled. Thereby, since the inside of the cold-reserved room is frozen or refrigerated, an increase in the temperature of an object to be frozen such as frozen food is prevented.
Further, as described above, when the internal temperature detected by the internal temperature sensor 28 becomes higher than the set temperature, each refrigeration device of the refrigeration apparatus is activated (energization: ON), and the internal temperature sensor 28 is also activated. When the internal temperature detected in step S3 becomes lower than the set temperature, the energization control of each electric motor 21 to 23 is performed so that the operation of each refrigeration apparatus of the refrigeration apparatus is stopped (OFF). By repeating ON-OFF control of the motors 21 to 23, temperature control is performed so that the inside temperature of the freezer warehouse 1 becomes a desired temperature (set temperature).

[Effect of Example 1]
As described above, in the refrigeration system of the refrigeration warehouse of this embodiment, the in-vehicle refrigeration unit installed on the upper portion of the front surface 9 of the front wall of the refrigeration warehouse 1 is used as the refrigeration unit 5 of the refrigeration warehouse 1 as it is. Further, a unit mounting frame 8 is additionally installed so as to protrude forward from the front surface 9 of the front wall of the freezer warehouse 1, and the standby unit 7 is mounted (installed) by being suspended from the unit mounting frame 8. Has been. That is, since the refrigerator unit 5 and the standby unit 7 are centrally installed (concentrated arrangement) on the front surface 9 of the front wall of the freezer warehouse 1, an underfloor component (standby unit) mounted under the floor of the conventional freezer 105. ) Can be abolished.

Moreover, since the underfloor parts can be abolished (eliminated) from the underfloor of the freezer warehouse 1, the wire harness 6 wired between the refrigerator unit 5 and the power supply control unit PU, and the refrigerator unit 5 and the motor unit MU. The refrigerant pipes 16 and 17 that connect the two can be significantly shortened as compared with the conventional in-vehicle freezer.
Further, the standby unit 7 which is an underfloor component in the conventional refrigerator can be installed as it is suspended from the unit mounting frame 8 without changing the design.
Further, the standby unit 7 can be easily installed in the freezer warehouse 1.
Therefore, the pressure loss of the refrigerant flow passing through the refrigerant pipe 16 connecting the evaporator 15 and the compressor 11 can be reduced, so that the refrigeration capacity of the refrigerator 2 can be improved and the refrigerator unit 5 for the refrigerator warehouse 1 can be improved. And the mountability of the standby unit 7 can be improved.

Here, the in-vehicle refrigerator is originally designed for low noise in consideration of use in a low noise environment such as a residential area. Therefore, as the refrigerator 2, a vehicle-mounted refrigerator driven by DC power obtained by voltage conversion and rectification of a commercial AC power source is used, and a refrigerator equipped with the vehicle-mounted refrigerator is used as the freezer warehouse 1. By doing so, it becomes possible to use as the freezer warehouse 1 provided with the refrigerator 2 in a low noise environment such as a residential area.
For example, an in-vehicle cooler with a medium size refrigerator has a length of 20 feet (6 m) in the longitudinal direction and a volume of 26.18 m ³ , so a large evaporator blower with a large operating noise is not used. However, the freezing capacity in the freezer warehouse 1 can be sufficiently exhibited.

Therefore, by using an in-vehicle refrigerator as the refrigerator 2 and using an in-vehicle cold storage as the freezer warehouse 1, a low-cost and short delivery time freezer warehouse compared to the case of newly constructing the freezer warehouse 1. 1 construction is possible.
In addition, by using an in-vehicle freezer and a refrigerator for a freezer car, it is possible to construct the refrigerator warehouse 1 at a lower cost and in a shorter delivery time than when a new refrigerator warehouse 1 is constructed. By installing it at the front position of the front wall, it is possible to provide a stationary refrigeration warehouse 1 that can eliminate the underfloor parts and can be easily installed and moved.

Moreover, the floor unit can be eliminated by installing the refrigerator unit 5 and the standby unit 7 which is the floor component all at the front wall position of the freezer warehouse 1.
Thus, even if there is a legal height restriction when transporting the freezer warehouse 1, as described above, the refrigerator unit 5 and the standby unit 7 are centrally arranged on the front wall of the freezer warehouse 1. Therefore, a sufficient capacity in the height direction of the cold storage chamber formed in the freezer warehouse 1 can be ensured.

[Example 2]
FIG. 3 shows a refrigeration apparatus (Example 2) of a refrigeration warehouse to which the present invention is applied.
Here, the same reference numerals as those in the first embodiment indicate the same configuration, and the description thereof is omitted.

The unit mounting frame 8 of this embodiment includes a plurality of pedestal frame members 43 that are installed below the bottom wall of the freezer warehouse 1. The pedestal frame member 43 on one side of the plurality of pedestal frame members 43 extends straight in the longitudinal direction of the freezer warehouse 1 along the left side wall. The pedestal frame member 43 on the other side of the plurality of pedestal frame members 43 extends straight in the longitudinal direction of the freezer warehouse 1 along the right side wall.
The refrigeration warehouse 1 is mounted on the plurality of pedestal frame members 43 such that the bottom wall contacts the upper surface (mounting surface) of each pedestal frame member 43.

The plurality of pedestal frame members 43 each have a protruding portion 44 that protrudes forward from the front surface 9 of the front wall of the freezer warehouse 1.
Further, the unit mounting frame 8 has a connecting frame member 45 that connects the tips of the projecting portions 44 of the plurality of pedestal frame members 43. A standby unit 7 is mounted on the connecting frame member 45. That is, the connecting frame member 45 becomes a unit support frame that supports the standby unit 7.
As described above, in the refrigeration apparatus of the refrigeration warehouse of the present embodiment, the refrigerator unit 5 and the standby unit 7 are concentrated on the front surface 9 of the front wall of the refrigeration warehouse 1, and thus the same effects as those of the first embodiment. Play.

[Modification]
In this embodiment, the rotary shaft of the compressor 11 is belt-driven by the electric motor 21, but the rotary shaft of the compressor 11 may be directly connected by the electric motor 21. For example, an electric compressor in which a compressor and an electric motor are integrated may be used.
In this embodiment, the refrigerator unit 5 in which the evaporator unit EU and the condenser unit CU are integrated is used as the refrigerator unit. However, as the refrigerator unit, the evaporator unit EU and the condenser unit CU However, a separately installed refrigerator unit may be used. For example, the evaporator unit EU is fixed to a wall of a warehouse, and the condenser unit CU is supported by a condenser frame.

1 Refrigerated warehouse 2 Refrigerator in refrigerated warehouse 5 Refrigerator unit 6 Wire harness (electrical wiring)
7 Standby unit 8 Unit mounting frame 9 Front of the front wall of the freezer warehouse (one side of the polyhedral warehouse)
11 Refrigerating cycle compressor 12 Refrigerating cycle condenser 14 Refrigerating cycle expansion valve (pressure reduction means)
15 Refrigerating cycle evaporator 16 Refrigerating cycle refrigerant piping (low pressure piping)
17 Refrigerant cycle refrigerant piping (high pressure piping)
18 Condenser fan (condenser blower)
19 Evaporator fan (blower for evaporator)
21 Compressor electric motor (electric motor)
22 Condenser fan electric motor (electric motor)
23 Evaporator Fan Electric Motor (Electric Motor)
25 Power converter 26 Power supply controller CU Refrigerator unit condenser unit EU Refrigerator unit evaporator unit MU Standby unit motor unit (compressor unit)
Power supply control unit for PU standby unit

Claims (14)

In a refrigeration apparatus equipped with a refrigerator that cools air in a polyhedral-shaped warehouse placed at a place of use,
The refrigerator is
(A) an evaporator that evaporates the refrigerant to cool the air in the warehouse, and an evaporator fan that blows air to the evaporator;
An evaporator unit that forcibly circulates air cooled by heat exchange with a refrigerant in the evaporator in the warehouse;
(B) a compressor for compressing and discharging the refrigerant sucked from the evaporator, and a compressor unit having an electric motor for driving the compressor;
(C) a power supply control unit that supplies electric power using a commercial power supply to the evaporator unit and the compressor unit;
The evaporator unit, the compressor unit, and the power supply control unit are concentrated on one side of the warehouse and in the vicinity thereof. The refrigeration apparatus according to claim 1,
The city power supply is a commercial AC power supply capable of supplying AC power,
The electric power using the commercial power supply is electric power obtained by converting the commercial AC power supply. The refrigeration apparatus according to claim 2,
As the refrigerator, a vehicle-mounted refrigerator that is driven by DC power obtained by converting the voltage of the commercial AC power supply and rectifying it is used. The refrigeration apparatus according to claim 3,
A refrigeration apparatus comprising a cold storage provided with the in-vehicle refrigerator as the warehouse. The refrigeration apparatus according to any one of claims 1 to 4,
The warehouse is a polyhedral cold storage warehouse in which a rectangular parallelepiped cold storage space is formed,
One side surface of the warehouse is a wall body located on one side in the longitudinal direction of the cold insulation space. The refrigeration apparatus according to any one of claims 1 to 5,
The said warehouse has the flame | frame which supports the said compressor unit and the said power supply control unit, The freezing apparatus characterized by the above-mentioned. The refrigeration apparatus according to claim 6,
The frame has a protruding frame attached to one side of the warehouse so as to protrude from one side of the warehouse toward one side;
The refrigeration apparatus, wherein the compressor unit and the power control unit are suspended from the projecting frame in a state of being suspended from the projecting frame. The refrigeration apparatus according to claim 6,
The frame has a plurality of pedestal frames installed below the warehouse,
The refrigeration apparatus, wherein the warehouse is mounted on the plurality of pedestal frames. The refrigeration apparatus according to claim 8,
The plurality of pedestal frames each have a protruding portion that protrudes from one side surface of the warehouse toward one side;
The frame includes a connection frame that connects the projecting portions of the plurality of base frames, and the compressor unit and the power supply control unit are mounted on the connection frame. The refrigeration apparatus according to any one of claims 1 to 9,
The refrigeration apparatus, wherein the evaporator unit is fixed to one side of the warehouse so as to protrude from one side of the warehouse toward one side. The refrigeration apparatus according to any one of claims 1 to 10,
The refrigerator is provided with a condenser unit having a condenser for condensing the refrigerant discharged from the compressor and a condenser fan for blowing air to the condenser. The refrigeration apparatus according to claim 11,
The refrigerator is provided with a refrigerator unit in which the evaporator unit and the condenser unit are integrated. The refrigeration apparatus according to claim 12,
The refrigeration apparatus, wherein the refrigerator unit is fixed to one side of the warehouse so as to protrude from one side of the warehouse toward one side. The refrigeration apparatus according to any one of claims 11 to 13,
The power supply control unit supplies the DC power obtained by voltage-converting and rectifying the commercial AC power source that is the commercial power source to the evaporator unit, the condenser unit, and the compressor unit. Refrigeration equipment characterized.

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