KR20110133155A - Cooling system for motor vehicle - Google Patents

Abstract

PURPOSE: A cooling system for a vehicle is provided to simplify a production process and reduce the size of the entire device since electrical equipment and a water-cooling condenser whose operating temperatures are different are cooled through a pump, a radiator, and a system cooling line, which are integrated. CONSTITUTION: A cooling system for a vehicle comprises a cooling water line(L1), a pump, and a radiator(200). The cooling water line is formed to pass through electrical equipment and a water cooling condenser. The pump is installed in the cooling water line. The pump receives cooling water from one side and sends it to the other side. The radiator is installed in the cooling water line. The radiator receives and cools cooling water from one side and sends it to the other side. The other side of the radiator comprises a first tank(221) and a second tank(222). The first tank supplies hot cooling water.

Description

Cooling System for Motor Vehicle

The present invention relates to a vehicle cooling system, and more particularly, to a vehicle cooling system that can be applied to a fuel cell vehicle or a hybrid vehicle by cooling components having different operating temperatures through a single radiator.

The fuel cell vehicle is a next-generation vehicle for reducing exhaust gas and improving fuel efficiency, and is equipped with front-end modules (FEMs) in which various components are modularized in the engine room, that is, the front end space.

At least three types of heat exchangers are combined in the front end module as a cooling system.

The heat exchanger may include a water-cooled condenser for cooling the room, a lower temp radiator (LTR) for cooling it, and an electric field radiator for cooling the electrical components such as a stack and a drive motor. Forced convection fan for forced convection of the air and the like is further included.

The water-cooled condenser is a heat exchanger for cooling a passenger room, and is cooled by using an LTR because the proper holding temperature is lower than that of the electric equipment.

The electrical component is cooled through a separate electric field radiator because the proper holding temperature is higher than the water-cooled condenser.

A conventional fuel cell vehicle or hybrid vehicle cooling system includes an electric field cooling system 10 including a pump 11 and an electric field radiator 30 for cooling the motor 12 and the stack 13 as shown in FIG. 1A. And a water-cooled condenser cooling system 20 including a pump 21 for cooling the water-cooled capacitor 22 and a lower temp radiator 40 as shown in FIG. 1B.

As shown in FIG. 2, the conventional radiator receives the coolant having a predetermined temperature through the inlets 31a and 41a formed in the first header tanks 31 and 41 and receives the tubes 35 and 45 and the heat dissipation fin 36. This is because the coolant is cooled to a predetermined temperature through 46 and discharged through the discharge holes 32a and 42a formed in the second header tanks 32 and 42.

Therefore, in order to cool a plurality of components having different proper holding temperatures, the cooling system having the above-described configuration must double the pump, the radiator and the system line.

As a result, despite the product having the same function, the production process is complicated due to the existence of a plurality of products, and the size of the product is increased, and the production cost is increased.

The present invention has been made to solve the above problems, an object of the present invention is to discharge the cooling water in the high-temperature region and the cooling water in the low-temperature region from a single radiator for the vehicle to unify the pump, radiator and system cooling line In providing a cooling system.

In the vehicle cooling system of the present invention, in the vehicle cooling system for cooling the electrical equipment (120, 130) and the water-cooled condenser 140 mounted on the vehicle, so as to pass through the electrical equipment (120, 130) and the water-cooled condenser 140. Cooling water line (L1) provided; A pump 110 installed on the cooling water line L1 and receiving the cooling water to one side to flow the cooling water to the other side; And a radiator 200 installed on the cooling water line L1 and receiving and cooling the cooling water to one side and discharging the cooling water to the other side. It is made, including, the other side of the radiator 200 is composed of a first tank 221 for supplying high temperature cooling water, and a second tank 222 for supplying low temperature cooling water, the first tank (221) ) Is connected to one side of the electrical appliance (120, 130), the second tank 222 is characterized in that connected to one side of the water-cooled condenser (140).

In addition, the radiator 200, the first header tank 210, the inlet 210a is formed so that the coolant flows; The first header tank 210 is formed to be spaced apart from each other, and the first tank 221, the second tank 222, and the first tank 221 and the second tank 222 are partitioned. A second header tank 220 including a baffle 223, a first discharge port 221a formed in the first tank 221, and a second discharge port 222a formed in the second tank 222; A plurality of tubes 230 having both ends fixed to the first header tank 210 and the second header tank 220 to form a cooling water flow path; It is made, including, the diameter of the first discharge port (221a) is characterized in that formed larger than the diameter of the second discharge port (222a).

In addition, the baffle 223 partitions the second header tank 220 such that the volume of the second tank 222 becomes 20% to 25% of the total volume of the second header tank 220. It is done.

In addition, the first discharge port (221a) is characterized in that formed in a lower position than the inlet (210a).

Vehicle cooling system of the present invention by the configuration as described above is to cool the electrical equipment and water-cooled condenser with different operating temperature through a unified pump, radiator and system cooling line, simplifying the production process, size reduction, production cost reduction effect In particular, it is easy to apply to fuel cell vehicles or hybrid vehicles.

1 is a schematic view of a conventional cooling system
Figure 2a is a front view of a conventional full length radiator
Figure 2b is a conventional LTR front view
3 is a schematic representation of a cooling system of the present invention.
4 is a front view of the radiator of the present invention

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

As shown in FIG. 3, the cooling system 100 of the present invention includes a cooling water line L1, a pump 110, a radiator 200, electrical components 120 and 130, and a water-cooled condenser 140.

The cooling water line (L1) has a tubular shape so that the cooling water flows into the inside, and one side and the other side may be connected to the reservoir tank in which the cooling water is stored. The cooling water line (L1) may be configured to circulate through the components to heat exchange with the radiator 200, electrical equipment (120, 130) and the water-cooled condenser 140.

The pump 110 is provided on the cooling water line L1 to allow the cooling water to flow inside the cooling water line L1.

The electrical appliances 120 and 130 include a motor 120 and a stack 130. The motor 120 and the stack 130 are essential components of a fuel cell electric vehicle (FCEV) and a hybrid electric vehicle (HEV), and the motor 120 drives the vehicle. The stack 130 serves to drive the motor 120. Since the motor 120 and the stack 130 generate heat during driving, the motor 120 and the stack 130 maintain a proper temperature through the cooling line L1. Typically, the best conditions are satisfied when the temperature of the motor 120 and the stack 130 is maintained at 70 to 80 degrees.

The water-cooled condenser 140 constitutes a cooling cycle together with the expander 150, the evaporator 160, and the compressor 170 as a configuration for an air conditioning apparatus for cooling a vehicle. Therefore, the water-cooled condenser 140 plays a role of releasing heat absorbed through the evaporator 160. The condenser mounted on the vehicle may be configured in an air-cooled type, but in the case of a water-cooled type, the heat dissipation effect is excellent, and thus the heat exchange efficiency may be increased even with a small size. The temperature of the water-cooled condenser 140 satisfies the best conditions when maintained at 60 to 70 degrees.

Therefore, the radiator 200 of the present invention receives the heated cooling water, and part of the radiator 200 is cooled to about 65 degrees to exchange heat with the electronic device 300, and part of the radiator 200 is cooled to about 60 degrees to exchange heat with the water-cooled condenser 400.

Common sense can be considered that the lower the temperature of the cooling water, the higher the heat exchange efficiency, but in this case, since the heat exchange is lower than the appropriate temperature, there is a problem that the mechanical properties and performance due to the low temperature. Therefore, the electrical components 300 and the water-cooled condenser 400 must be heat exchanged to maintain the optimum operating temperature required.

In order to perform the above task, the radiator 200 of the present invention has the following configuration.

4, the radiator 200 of the present invention includes a first header tank 210 and the second header tank 220 are provided side by side with a predetermined distance apart; Both ends are fixed to the first and second header tanks 210 and 220 to form a heat exchange medium flow path, the tube having heat; It comprises a pin 50 interposed between the tube 230.

An inlet 210a may be formed in the first header tank 210 to receive the heat-exchanged cooling water. Cooling water stored in the first header tank 210 through the inlet 210a is cooled while flowing the tube 230, and is stored in the second header tank 220. At this time, the fin 50 is interposed between the tubes 230 to increase the heat radiation area to further increase the heat radiation effect of the cooling water.

The second header tank 220 is divided into a first tank 221 and a second tank 222. The first tank 221 and the second tank 222 may be partitioned through the baffle 223. A first discharge port 221a is formed in the first tank 221 to discharge relatively high temperature cooling water to the other side, and a second discharge port 222a is formed in the second tank 222 to provide a relatively low temperature. The cooling water is discharged to the other side. The height of the first discharge port (221a) is formed lower than the height of the inlet (210a).

At this time, the present invention has the following configuration in order to discharge the cooling water of different temperatures through the first discharge port (221a) and the second discharge port (222a). In order to discharge the cooling water having different temperatures through the first discharge port 221a and the second discharge port 222a, the present invention measures the flow rate of the cooling water flowing from the first header tank 210 to the first tank 221. Implemented faster than the flow rate of the cooling water flowing from the header tank 210 to the second tank 222. Accordingly, the diameter of the first discharge port 221a may be larger than the diameter of the second discharge port 222a. In addition, in order to make the volume of the first tank 221 larger than that of the second tank 222, the baffle 223 has a volume of the second tank 222 of the total volume of the second header tank 220. The second header tank 220 may be partitioned to be 20-25%.

Due to the configuration described above, the temperature of the cooling water discharged through the second tank 222 having a high heat exchange rate due to the high flow rate of the cooling water discharged through the first tank 221 having a low heat exchange rate due to the high flow rate of the cooling water is low. It will be higher.

The coolant of 65 degrees discharged through the first discharge port 221a exchanges heat with the motor 120 and the stack 130, and the coolant of 60 degrees discharged through the second discharge port 222a is the water-cooled condenser 14. By heat exchange with, a single radiator heats a plurality of components to an appropriate temperature.

The technical idea should not be construed as being limited to the above-described embodiment of the present invention. Various modifications may be made at the level of those skilled in the art without departing from the spirit of the invention as claimed in the claims. Therefore, such improvements and modifications fall within the protection scope of the present invention, as will be apparent to those skilled in the art.

100: cooling system
110: pump 120: motor
130 stack 140 water-cooled condenser
150: expander 160: evaporator
170: compressor
200: radiator 210: the first header tank
220: second header tank 221: first tank
222: the second tank 223: baffle
230: tube 240: pin

Claims (4)

In the vehicle cooling system for cooling the electrical equipment (120, 130) and the water-cooled condenser 140 mounted on the vehicle,
A cooling water line (L1) provided to pass through the electrical appliances (120, 130) and the water-cooled condenser (140);
A pump 110 installed on the cooling water line L1 and receiving the cooling water to one side to flow the cooling water to the other side; And
A radiator (200) installed on the cooling water line (L1) and receiving and cooling the cooling water to one side to discharge the cooling water to the other side; Including but not limited to,
The other side of the radiator 200 is composed of a first tank 221 for supplying high temperature cooling water, and a second tank 222 for supplying low temperature cooling water, wherein the first tank 221 is the electrical equipment 120 , 130 is connected to one side, the second tank 222 is connected to one side of the water-cooled condenser 140, characterized in that the vehicle cooling system.
The method of claim 1,
The radiator 200,
A first header tank 210 in which an inlet 210a is formed so that the coolant is introduced;
The first header tank 210 is formed to be spaced apart from each other, and the first tank 221, the second tank 222, and the first tank 221 and the second tank 222 are partitioned. A second header tank 220 including a baffle 223, a first discharge port 221a formed in the first tank 221, and a second discharge port 222a formed in the second tank 222;
A plurality of tubes 230 having both ends fixed to the first header tank 210 and the second header tank 220 to form a cooling water flow path; Including but not limited to,
The diameter of the first discharge port (221a) is a vehicle cooling system, characterized in that formed larger than the diameter of the second discharge port (222a).
The method of claim 2,
The baffle 223,
The second header tank (220) is partitioned so that the volume of the second tank (222) is 20% to 25% of the total volume of the second header tank (220).
The method of claim 2,
The first discharge port (221a) is a vehicle cooling system, characterized in that formed in a lower position than the inlet (210a).

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