KR20110090144A - Refrigerator of a refrigerrating vehicle - Google Patents

Abstract

PURPOSE: A cooling device for refrigerator vehicle which steadily can drive cooling system is provided to stably and efficiently cool a cooling system using direct current. CONSTITUTION: A cooling device for refrigerator vehicle comprises an engine(110), a BLDC generator(111), and a battery(150). The engine offers power to the cooler. The BLDC generator is serially connected to an engine shaft and generates the DC power supplied to the cooling device. The battery stores the electricity generated by the BLDC generator and supplies power to the compressor.

Description

Refrigerator Cooling System {REFRIGERATOR OF A REFRIGERRATING VEHICLE}

The present invention relates to a refrigeration vehicle cooling apparatus, and more particularly, to a refrigeration vehicle cooling apparatus that can supply and store a stable power source capable of driving a cooling system, and more efficiently control a refrigeration system through a DC power source. It is about.

A refrigeration vehicle generally used is used to transport frozen / refrigerated foods, and is provided for transporting or storing foods having a refrigeration device in a loading portion of the insulated vehicle. Like a typical refrigeration cycle, refrigeration vehicles are compressors that compress gaseous refrigerants, condensers that condense and liquefy high-pressure refrigerant gas, expansion valves that expand refrigerants to lower temperatures, evaporators that vaporize refrigerants through heat exchange, and refrigerant piping. It includes. The power source of the refrigeration cycle of a typical refrigeration vehicle is mainly obtained by using engine power.

The principle of power supply of the conventional refrigeration apparatus loaded on the vehicle as described above will be described with reference to FIGS.

The power required for the vehicle refrigeration system is mainly classified into the driving power of the compressor, the fan driving power of the condenser and the evaporator, the solenoid valve and the control device, and the driving power of the compressor occupies more than 80% of the total power. The source of power for driving a refrigerator for a refrigeration vehicle is divided into a method of using the power of the vehicle engine, a method of driving the sub-engine in the refrigerator itself, and a method of using an external power source. Each operation is described below.

1 is a view showing a structure of a conventional cooling device for cooling by using the power of the engine of the vehicle.

Conventionally, the most commonly used method is to attach a compressor 20a having an electronic clutch in the engine room of a refrigeration vehicle using a pulley and a belt 11a to drive the compressor 20a, and the fan uses a DC motor. Use development power of In this method, the compressor is connected to the engine of the refrigerating vehicle by the pulley and the belt, so it is difficult to operate the freezer when the vehicle is stopped, and it is difficult to flexibly cope with the rotational speed of the compressor and the capacity limitation due to the space limitation of the engine room. Have a problem.

2 is a view showing a structure of a conventional cooling apparatus for cooling by using a sub-engine power.

In this method, the diesel engine 10b is separately installed to connect the compressor 20b, the condenser, and the fan by using the belt 11b to the engine. In some cases, fans are driven by generating power. In this case, it is possible to maintain the compressor rotation speed and increase the capacity, but it has disadvantages such as coping with refrigeration load variation and fuel consumption and noise.

3 is a view showing a structure of a conventional cooling apparatus for cooling using external power.

The AC induction motor is used to compensate for the problem in combination with the above methods by driving the refrigerator instead of the engine to operate the refrigerator even when the load is unloaded or at rest.

By the way, the existing structure to obtain the cooling power is only the difference between the rotational direction and the gearbox insertion form according to the direction of the fan almost similarly there is no difference in the way to drive the engine and the compressor through the belt or pulley. In this case, since the load is connected to the engine, the engine load is excessively consumed at the time of initial start-up, and it is disadvantageous in terms of the system control because the rotation speed is fixed according to the pulley ratio. As a result, various control valves have recently been mounted and controlled, but still have limitations.

In addition, an alternator and a lead acid battery are required for a control power source and an engine start, and the power is inevitably reduced as power is transmitted through a pulley or a belt. On the other hand, since the engine output is the output of the AC power supply, problems of configuration, storage and efficiency in accordance with the conversion of the current method is also raised.

The present invention has been made to solve the problems of the prior art, an object of the present invention is to provide a cooling device for a refrigeration vehicle that can stably drive the cooling system by reducing the consumption of engine power and accumulating stable DC power from the engine. .

In addition, an object of the present invention is to provide a refrigeration vehicle cooling apparatus capable of driving a cooling system efficiently and stably using DC power.

A refrigeration vehicle cooling apparatus according to the present invention is a refrigeration vehicle cooling apparatus including a compressor, a condenser, an evaporator, a cooling line, a valve, and a fan, an engine for supplying power to the cooling apparatus, connected in series with the engine shaft, and supplied to the cooling apparatus. A BLDC generator for generating direct current (DC) power, and a battery for storing power generated in the BLDC generator and supplying power for driving the compressor; It provides a cooling device for a refrigeration vehicle to drive. Therefore, the conventional drive connection devices can be omitted, thereby reducing energy loss and providing a cooling device for a refrigeration vehicle that can stably supply a power source.

In addition, the refrigeration vehicle cooling apparatus according to the present invention further includes a controller for distributing power from the battery, the valve is an electronic flow control valve and the refrigeration vehicle cooling apparatus for controlling the amount of refrigerant flowing in accordance with the signal of the controller. To provide. Therefore, the control of the flow rate is made electronic so that it is possible to more precisely reduce power consumption.

In addition, the refrigeration vehicle cooling apparatus according to the present invention provides a refrigeration vehicle cooling apparatus further comprises an inverter for converting the power of the battery into an alternating current supplied to the compressor.

In addition, the refrigeration vehicle cooling apparatus according to the present invention further includes a DCDC converter for outputting the adjusted power from the battery, the power output from the DCDC converter provides a refrigeration vehicle cooling apparatus used for engine startup and control. . Therefore, the power of the cooling system can be stably operated.

In addition, the cooling device for a refrigeration vehicle according to the present invention further includes a controller for receiving the charge information of the battery to send a start signal of the refrigeration vehicle and when the charge amount of the battery is less than the reference amount to start the engine to charge the battery Provided is a refrigeration vehicle cooling apparatus. Thus, there is provided a refrigeration vehicle cooling apparatus that can operate stably by automating the refrigeration system.

Refrigeration apparatus for a refrigeration vehicle according to the present invention has the advantage that the load of the engine is reduced and the cooling system can be operated more efficiently by configuring the refrigeration cycle with a stable DC power by charging the battery through the BLDC generator with power from the engine have.

In addition, it is equipped with a controller that can efficiently control the cooling system, and by arranging electronic components, it is possible to easily build the flow rate of the refrigerant, heat exchange and automatic charging systems to reduce power consumption and make the cooling system more efficient. There is this.

In addition, to prevent the discharge of the battery by monitoring and to be able to automatically charge by the engine power is provided for convenience and reliability of refrigeration vehicle operation.

1 is a view showing a structure of a conventional cooling device for cooling by using the power of the engine of the vehicle.
2 is a view showing a structure of a conventional cooling apparatus for cooling by using a sub-engine power.
3 is a view showing a structure of a conventional cooling device for cooling using external power.
4 is a view showing the structure of a refrigeration vehicle cooling apparatus according to the present invention.
5 is a front view showing an embodiment of a refrigeration vehicle assembly for a refrigerator vehicle according to the present invention.
Figure 6 is a rear view showing an embodiment of a refrigeration vehicle cooling apparatus assembly according to the present invention.

Hereinafter, with reference to the accompanying drawings an embodiment according to the present invention will be described in detail.

4 is a view showing the structure of a refrigeration vehicle cooling apparatus according to the present invention. The main part of the refrigeration system is composed of a compressor 120, a condenser 121, an evaporator 122, a heater 123, and a plurality of fans 121a and 122a. When the refrigerant in the compressor 120 is compressed to high temperature and high pressure and moves to the condenser 121 through a pipe, the refrigerant is cooled and phase-changed into a high pressure low temperature liquid refrigerant. When the refrigerant reaches the expander (not shown) in the condenser 121, the volume expands and the temperature is lowered to change into a refrigerant gas of low pressure and low pressure, and when introduced into the evaporator 122, the refrigerant absorbs heat inside the freezer and changes into a refrigerant gas of low pressure. do. The refrigerant is recovered to the compressor 120 again, and one refrigeration cycle is completed. On the other hand, the heater 123 using the power is used for deicing, defrosting and heating the evaporator, the fans 121a, 122a are used for the heat exchange efficiency of the condenser 121 and the evaporator 122.

As described above in the prior art, the cooling device for a refrigeration vehicle uses the engine of the vehicle as the main power source, so that the efficiency and installation space of the power source is important, unlike the cooling device used at home or in a fixed place. In view of this, in the present invention, the power of the engine 110 additionally arranged to provide a power source of the refrigeration system is not directly used as the power of the compressor 120 or other components, but is primarily stored as a battery. do. In order to store the power of the engine 110, a generator for converting a mechanical rotational force into electric power is required to be arranged. In the present invention, the shaft of the BLDC generator 111 is connected in series with a driving unit of the engine to directly convert the rotational force of the engine to a DC voltage. Convert to output

On the other hand, the cooling line of the cooling system can be used for cooling the BLDC generator 111 or the engine 110, of course.

The DC voltage output converted as described above is not directly input to drive the cooling system, but is stored in the battery 150. The battery 150 is preferably a lithium ion battery. However, in the case of components using low power, such as the fans 121a and 122a and the heater 123, the power of the BLDC generator 111 may be directly used. In the case of the condenser fan 121a or the evaporator fan 122a, a BLDC motor having an excellent function for DC power is preferably used.

As described above, when the power source of the cooling system is not directly obtained from the engine 110, and is used by accumulating the battery 150, unnecessary power and load can be reduced, and an overload of the initial engine power can be prevented. have. In addition, when using a DC power charged in the battery, it is possible to supply a stable high-pressure DC power, it is possible to significantly reduce the burden on the rotational speed control and the flow optimization of the compressor.

In addition, the compressor 120 preferably uses a hermetic cmpressor using an AC power source. More preferably, the compressor 120 uses a hermetic inverter screw compressor. In this case, since the DC output from the battery 150 must be converted into alternating current, a DC-AC inverter 130 is disposed between the compressor 120 and the power line of the battery 150. In addition, as described above, it is preferable that the fans 121a and 122a use a BLDC motor. The selection of the motor can be freely made according to the blowing amount of the fans 121a and 122a. In this case, a DCDC converter for adjusting the voltage and power of the battery 150 is further configured. In general, the voltage of the lithium ion battery used in the cooling device is formed between 340V and 270V, but of course, other voltages may be used. Therefore, since a voltage drop is required to drive the BLDC motor, a DCDC converter is required to be additionally configured.

According to the concept of the present invention, a lead acid battery generally used for starting and controlling a vehicle can be integrally formed in a refrigeration system. When the engine 110 starts up, a high load is applied, thereby utilizing a conventional lead acid battery. Accordingly, when the refrigeration system and the lead acid battery are integrated, the lead acid battery can be utilized only for starting the engine 110. On the other hand, if the capacity of the lithium ion battery 150 is secured, the alternator and lead-acid battery for starting and controlling the engine of the refrigeration vehicle and the cooling system are omitted, the BLDC generator 111 and the lithium ion battery ( 150). In this case, since the battery 150 can be used in various ways such as starting of the vehicle and operating signals, the configuration of the vehicle can be further simplified by minimizing the entire system. As described above, since a cell motor is required for engine start, a DCDC converter 140 for driving the cell motor is further configured. In general, since 12V is used for a cell motor of a vehicle, a DC voltage converter is used.

In addition, according to another concept of the present invention, a configuration for solving the problem of the discharge of the battery 150 is derived. For reference, when the power of the engine is directly transmitted to the power of the compressor using a belt or a pulley, when the cooling is required even during the stop, the engine must be left in a state of being started. The same applies to a cooling system equipped with a separate engine, in which the engine must always be started to operate the cooling system. In the case of the cooling device for a refrigeration vehicle according to the present invention has a significant advantage in terms of noise because it drives the cooling system using a battery. However, there is a problem when the battery is discharged. To solve this problem, the controller 160 for monitoring the situation of the battery 150 is disposed. The controller 160 identifies not only the signals for the engine 110 and the battery 150 but also identifies the situation of components such as the fans 121a and 122a, the heater 123 or the electronic valve, and sends a control signal. do. The controller 160 monitors the power of the battery 150. When the charge amount is less than a predetermined reference, the controller 160 sends a start signal to the engine 110. The engine 160 which receives the start signal charges the battery 150 through the BLDC generator 111 in the idling state. On the other hand, when the battery 150 is fully buffered by sending a signal to stop the engine 160 to operate the cooling system again with only the battery 150.

Figure 5 is a front view showing an assembly according to an embodiment of a refrigeration vehicle cooling apparatus according to the present invention, Figure 6 shows a rear view.

The above configuration is coupled to the frame 170 is made more compact in appearance. As described above, the mechanical power output from the engine 110 is stored in the battery 150 by the BLDC generator 111 connected in series with the drive shaft. Power from the battery 150 is converted into AC power through an inverter to drive the compressor 120, and more particularly, the scroll compressor. The high pressure refrigerant compressed from the compressor is introduced into the condenser through a pipe and cooled to phase change into a high pressure low temperature liquid refrigerant. When the refrigerant reaches the expansion device in the condenser 121, the volume expands and the temperature decreases to change into a refrigerant gas of low temperature and low pressure. When the refrigerant flows into the evaporator 122, the refrigerant absorbs heat inside the freezer and changes into a refrigerant gas of low pressure. The refrigerant is recovered to the compressor 120 again, and one refrigeration cycle is completed. On the other hand, the heater 123 using the power is used for deicing, defrosting and heating the evaporator, the fans 121a, 122a are used for the heat exchange efficiency of the condenser 121 and the evaporator 122.

In addition, the assembly 100 is coupled to a controller 161 for controlling the power and the signal, the controller 161 distributes the power from the battery 150 to drive the fans (121a, 122a), the compressor 120 ) And the heater 123.

On the other hand, the electronic valve is formed in the cooling line according to another concept of the present invention. Expansion valve 124 is configured electronically, when the controller 161 calculates the flow rate of the appropriate refrigerant in the system and sends a signal to the valve, the electronic expansion valve 124 is to control the flow rate, optimized for refrigeration system By allowing the flow rate to flow, cooling capacity can be maintained while reducing power consumption. Preferably, the expansion valve used for flow control is driven through the step motor.

In addition, an evaporation pressure control valve 125 is disposed at the outlet side of the evaporator 122 and the input refrigerant line of the compressor 120. Like the expansion valve 124, the evaporation pressure regulating valve 125 is driven by a signal from the controller 161. The engine load is controlled by reducing the power consumption by controlling the flow rate of the refrigerant flowing into the compressor 120. It can play a role of reducing.

Accordingly, the present invention provides an advantage that the load of the engine is reduced and the cooling system can be operated more efficiently by configuring the refrigeration cycle with stable DC power by charging the battery through the BLDC generator with power from the engine. In addition, by monitoring to prevent the discharge of the battery to be automatically charged by the engine power to provide convenience and reliability of refrigeration vehicle operation.

In addition, by operating the electronic valve through the controller to properly control the flow of the refrigerant it is possible to reduce the power consumption of the entire cooling system.

In the above, the present invention has been described in detail based on the embodiment and the accompanying drawings. However, the scope of the present invention is not limited by the above embodiments and drawings, and the scope of the present invention will be limited only by the contents described in the claims below.

Cooling assembly 110 Engine
111 ... BLDC Generator 120 ... Compressor
121 ... condenser 121a ... condenser fan
122 ... Evaporator 122a ... Evaporator Fan
123 Heater 124 Electronic expansion valve
125 Electronic evaporation pressure control valve 150 Battery
161 Controller 170 Frame

Claims (5)

A refrigeration vehicle cooling apparatus including a compressor, a condenser, an evaporator, a cooling line, a valve, and a fan,
An engine for powering the chiller;
A BLDC generator connected in series with the engine shaft and generating DC power supplied to a cooling device; And,
And a battery for storing power generated by the BLDC generator and supplying power for driving the compressor.
The power of the battery is a refrigeration vehicle cooling apparatus for driving a fan of the compressor, the fan of the condenser and the evaporator.
The method of claim 1,
A controller for distributing power from the battery;
The valve is an electronic flow control valve for refrigeration vehicle cooling device for adjusting the amount of refrigerant flowing in accordance with the signal of the controller.
The method of claim 1,
And an inverter for converting power of the battery into alternating current and supplying the battery to the compressor.
The method of claim 1,
And a DCDC converter for adjusting and outputting power from the battery, wherein the power output from the DCDC converter is used for starting and controlling the engine of the refrigerator vehicle.
The method according to any one of claims 1 to 4,
And a controller for receiving a charge amount information of the battery and sending a start signal of the refrigeration vehicle.

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