KR101417115B1 - Thermal management system for fuel cell vehicle - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heat and water management system of a fuel cell vehicle, and more particularly, to a cooling and heating system for a power electronic part (PE part) mounted on a fuel cell vehicle, And a heat and water management system in which heat generated from power electronic components can be used to heat the cooling water of the fuel cell while consuming power of the fuel cell. In the present invention, the function of the existing COD / heater is substituted for the function of the existing load consuming device such as the driving system including the electric power part or the heating / cooling part, thereby securing the space of the TMS line and reducing the number of parts, .

Fuel cell, heat and water management system, TMS, cooling loop, power electronic components, PE parts, cooling water, COD, heater

Description

Technical Field [0001] The present invention relates to a thermal management system for a fuel cell vehicle,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heat and water management system for a fuel cell vehicle, and more particularly, to a heat and water management system for removing the reaction heat of a stack outside a system in a fuel cell vehicle and controlling an operating temperature of the fuel cell stack .

Fuel cells are a kind of power generation system that converts chemical energy of fuel into electrical energy by reacting electrochemically in the fuel cell stack without converting it into heat by combustion. It is not only supplying power for industrial, household and vehicle driving, It can also be applied to the electric power supply of electric / electronic products, especially portable devices.

As a fuel cell, a polymer electrolyte membrane fuel cell (PEMFC), which has been most studied as a power source for driving a vehicle, has a structure in which hydrogen ions move on both sides of an electrolyte membrane A membrane electrode assembly (MEA) having a catalyst electrode layer on which an electrochemical reaction takes place, a gas diffusion layer (GDL) acting to distribute reaction gases evenly and to transmit the generated electrical energy, A gasket and a fastening mechanism for maintaining the airtightness of the reaction gases and the cooling water and proper tightening pressure, and a bipolar plate for moving the reaction gases and the cooling water.

In the fuel cell, hydrogen as a fuel and oxygen as an oxidant (air) are supplied to an anode and a cathode of a membrane electrode assembly through a flow path of a separator plate, respectively. The hydrogen is supplied to the anode Oxygen (air) "or" oxygen electrode "or" reduction electrode "), and oxygen (air) is supplied to the cathode.

Hydrogen supplied to the anode is decomposed into hydrogen ions (proton, H ⁺ ) and electrons (electron, e ^- ) by the catalyst of the electrode layer formed on both sides of the electrolyte membrane. Only hydrogen ions selectively pass through the electrolyte membrane And the electrons are transferred to the cathode through the gas diffusion layer, which is a conductor, and the separator plate.

In the cathode, hydrogen ions supplied through the electrolyte membrane and electrons transferred through the separator meet with oxygen in the air supplied to the cathode by the air supplying device to generate water. At this time, the flow of electrons through the external conductor occurs due to the movement of hydrogen ions, and a current is generated by the flow of electrons.

On the other hand, a fuel cell system mounted on a vehicle mainly includes a fuel cell stack for generating electric energy, a fuel supply device for supplying fuel (hydrogen) to the fuel cell stack, a fuel supply device for supplying oxygen And a thermal management system (TMS) that removes reaction heat from the fuel cell stack to the outside of the system and controls the operating temperature of the fuel cell stack.

In such a configuration, in the fuel cell system, electricity is generated by an electrochemical reaction between hydrogen as fuel and oxygen in the air, and heat and water are discharged as reaction byproducts.

In the above-described fuel cell system, heat is generated as a reaction by-product, and therefore, a device for cooling the stack is necessary to prevent the temperature of the stack from rising. In addition, the most urgent and difficult problem in the fuel cell system is the strategy of securing cold - freeness, so the role of heat and water management system is more important than anything else.

As is well known, the cooling water of the TMS line serves as a coolant (coolant) for cooling the stack, and at the same time as the coolant is rapidly heated by the heater, it is supplied to the stack, thereby serving as a heat medium to rapidly thaw the stack.

A conventional solution for securing cold freezing in a fuel cell vehicle was the rapid thawing of pure water using a heater inside a Rapid Thaw Accumulator (RTA). However, if pure water is used, pure water will freeze below the freezing point, and the cooling water loop will become complicated and additional drain valves will be required.

In order to solve these problems, there is a method of using cooling antifreeze as a cooling fluid for the stack and rapid cooling of the cooling water to smooth the power generation of the stack at a temperature below the freezing point. To do this, the heater must be attached to the stack cooling water line.

In addition, in the fuel cell vehicle, COD (Cathode Oxygen Depletion) is connected to both terminals of the stack to prevent degradation of stack durability due to corrosion of the catalyst-carrying carbon when the fuel cell starts up / shutdown, The power generation by the reaction of the heat energy is consumed by the heat energy.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a schematic diagram of a prior art heat and water management system (TMS), showing the configuration of a TMS line constructed around a fuel cell stack. As shown in the figure, there are provided a water pump 22 for cooling water circulation, a radiator 24 for heat exchange between the outside air and the cooling water, a thermostat 23, a COD having a function of load exhaustion, In this case, the COD and the heater can be integrated and provided in the same cartridge form.

These COD / heater cartridges are expensive, and in particular CODs are made up of a plurality of heater rods built-in, and their volume is considerably large, so they occupy a significant portion of the total TMS volume. This large volume of CODs is very disadvantageous in terms of layout.

Essentially, both the heater and the COD are resistive heaters, which can be integrated into one heater only when they are used and intended for use. Such a COD integrated heater has been used to heat all the heat generated by the stack cooling water circuit to raise the temperature of the stack cooling water. In addition, the COD integrated heater is used to prevent the carbon burning of the electrode and the anode flooding of the electrode when the fuel cell is started and shut down, and the load of the coaxial stack is rapidly increased to the self-heating temperature of the cryogenic cold simultaneous stack. Were separately attached to the TMS line.

If the function of the COD integrated heater is replaced by the other driving system including the electric power component of the fuel cell vehicle or other load consuming device, it is possible to secure the space of the TMS line and to greatly reduce the number of parts, There will be.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a cooling loop for replacing the functions of existing COD / The present invention is intended to provide a heat and water management system for a fuel cell vehicle that can secure space of the entire system and reduce the number of parts, cost, and layout.

In order to achieve the above object, the present invention provides a heat and water management system for a fuel cell vehicle comprising a water pump and a radiator provided on a cooling water line of a stack,

A coolant line of the stack is provided so as to pass through the power electronic component for cooling the power electronic components mounted on the vehicle so that the cooling water line of the power electronic component and the cooling water line of the stack are integrated into one integrated structure, The cooling water circulating between the parts and the stack cools the power electronic parts and warms up the stack with the heat supplied thereto.

The present invention also provides a heat and water management system for a fuel cell vehicle, comprising a water pump and a radiator provided on a cooling water line of a stack,

A cooling water line for cooling power electronic components mounted on the vehicle is provided separately from a cooling water line of the stack, an intermediate heat exchanger is provided between both cooling water lines, and cooling water in the stack passes through the power electronic component in the intermediate heat exchanger And the heat is supplied from one cooling water and the stack is warmed up.

Here, the power electronic part is used as a load consuming device that consumes current in the stack while receiving power through a cable connected from the stack when load consumption of the stack is required.

Accordingly, according to the heat and water management system of the present invention, the function of the existing COD / heater is substituted for the function of other load consuming devices such as a driving system including an electric power component or a heating and cooling component, , Cost reduction, and layout improvement can be obtained.

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

In the present invention, the power electronic components (PE (Power Elecronics) parts) mounted on the fuel cell vehicle are used as the conventional COD (the power consumption of the fuel cell is the main function) and the heater (the cooling water heating of the fuel cell and the cold- The cooling loop is improved so that the power electronic component consumes the power of the fuel cell and the heat generated in the power electronic component can be used to heat the cooling water of the fuel cell. Water management system.

In a fuel cell vehicle, power electronic components such as a motor (vehicle driving motor, radiator fan motor, etc.) and a DCDC converter (LDC (Low Voltage DCDC Converter) Is provided with a water tube to cope with its own heat generation, and then a cooling system is provided for supplying cooling water through the water tube to absorb the heat that the cooling water exits from the component.

The present invention improves the TMS line so that the role of a COD / heater can be replaced by a power electronic component that is a heat generating component. In the present invention, the function of a conventional COD / heater in a driving system including an electric power component, It is possible to secure the space of the TMS line, reduce the number of parts, reduce the cost, and improve the layout.

As in the present invention, if the power electronic part receives the power of the stack and serves as a load device consuming current, the COD / heater of the TMS line can be deleted if the stack is warmed up by heat generated at that time However, at this time, considering the cold start of the stack, the cooling water circuit of the TMS line should be configured in an optimum arrangement.

FIG. 2 is a configuration diagram of a heat and water management system for a fuel cell vehicle according to an embodiment of the present invention, and FIG. 3 is a configuration diagram of a heat and water management system according to another embodiment of the present invention.

Referring to FIG. 2, a cooling water line of a power electronic part (PE part) and a cooling water line of a stack are integrated into a thermal and water management system composed of one cooling loop. A water pump 22 for circulating cooling water, a radiator 24 and a thermostat 23 for exchanging the cooling water and the outside air are provided in the cooling water line 20 of the stack in the same manner as in the prior art, Absorbing the heat of the stack 10 while circulating between the stack 10 and the radiator 24 by the radiator 24 and radiating the heat from the radiator 24.

At this time, the cooling water line of the power electronic component is integrated with the cooling water line of the stack to constitute one cooling water line 20, and the cooling water circulating between the stack 10 and the radiator 24 is generated in the electric power electronic part 31 To be supplied to the stack. It is also possible to radiate the heat generated by the power electronic component 31 to the radiator 24 after the cooling water absorbs the heat.

As described above, one cooling loop is formed for the power electronic part 31 and the stack 10, at which time the power electronic part 31 is capable of supplying power generated in the stack through the cable 11 connected from the stack 10 The power electronic component 31 can supply power to the stack 10 through the cable 11 to consume current while driving.

Of course, the driving of the electric power electronic components is controlled by each controller that controls them. For example, in the case of a motor, the fuel cell system controller is driven as an upper controller and under the control of the MCU. In the case of LDC, its own controller (LDC controller) controls its driving.

If the power electronic component 31 appropriately consumes the power of the stack 10 in the single cooling loop configuration as described above and the cooling water supplied to the stack is heated by the heat generated at that time to increase the stack, It is possible to reduce the power consumption of the stack and to improve the freezing uniformity.

2, it is also possible to separately control the electric conductivity by attaching an electric conductivity sensor or the like to the cooling water line in order to match the condition of the cooling water ion conductivity of the stack.

3, a cooling water line 40 of a power electronic part (PE part) and a cooling water line 20 of a stack are separately provided, and an intermediate heat exchanger 50 for heat exchange between both cooling water is added Heat and water management systems. That is, the cooling water line 40 of the electric power electronic component and the cooling water line 20 of the stack are each provided with two cooling loops, and an intermediate heat exchanger 50 is installed between the two cooling loops.

A water pump 22 for circulating cooling water is provided in the cooling water line 20 of the stack as well as a radiator 24 and a thermostat 23 for heat exchange between the outside air and the cooling water. 22 to circulate between the stack 10 and the radiator 24 so as to absorb the heat of the stack 10 and radiate the heat from the radiator 24.

A water pump 41 for circulating cooling water is provided in the cooling water line 40 of the power electronic component and the power electronic component 31 is connected to the cooling water line 40 through the cable 11 connected from the stack 10, It is supposed to be supplied. Accordingly, when necessary, the power electronic component 31 can supply power to the stack 10 through the cable 11 and can consume current while driving.

The intermediate heat exchanger 50 is for transferring heat between the cooling water line 40 of the power electronic component and the cooling water line 20 of the stack and the cooling water circulating the cooling water line 40 of the power electronic component 31 and transfers the heat to the cooling water in the stack in the intermediate heat exchanger 50 and the cooling water in the stack heated in the intermediate heat exchanger 50 flows into the stack 10 to warm up the stack .

As a result, the cooling water flowing through the cooling water line 40 of the power electronic component basically cools the electric power electronic component 31, but the cooling water cools the power electronic component and is heated to be cooled in the intermediate heat exchanger 50, And at this time, the cooling water in the heated stack wakes up the stack 10, so that the power electronic part 31 can replace the function of the existing heater.

Also, after the stack 10 is worn, the heat absorbed by the power electronic component 31 can be discharged along the path of the cooling water, the intermediate heat exchanger 50, the cooling water of the stack, and the radiator 24.

In the above configuration, the power electronic component 31 appropriately consumes the power of the stack 10, and the cooling water supplied to the stack is heated by the heat generated at that time to wake up the stack. Thus, without using the conventional COD and heater, And improvement in cold rolling can be achieved.

In this way, in the present invention, by improving the cooling line so that the power electronic part (PE part) replaces the function of the existing COD / heater, it is possible to secure the space of the TMS line and reduce the number of parts, In particular, COD, which occupies the largest portion of the total volume of the TMS module box, can be eliminated, which is advantageous in terms of volume reduction and space securing of the entire system.

As in the present invention, even if the COD is directly applied to the cooling water line in the TMS using the heat of power electronic components, the number of heater rods of the COD can be reduced and the capacity can be reduced.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a schematic diagram illustrating a prior art thermal and water management system (TMS)

2 is a configuration diagram of a heat and water management system for a fuel cell vehicle according to an embodiment of the present invention;

3 is a configuration diagram of a heat and water management system according to another embodiment of the present invention;

Description of the Related Art

10: Fuel cell stack 20: Cooling water line of the stack

21: COD / heater 22: water pump

24: radiator 30: cooling water line of power electronic parts

31: Power electronic parts (PE parts) 32: Water pump

40: intermediate heat exchanger

Claims (4)

A heat and water management system for a fuel cell vehicle, comprising a water pump (22) and a radiator (24) installed in a cooling water line (20) The cooling water line 20 of the stack is provided so as to pass through the power electronic part 31 for cooling the power electronic part 31 mounted on the vehicle so that the cooling water line of the power electronic part and the cooling water line of the stack are integrated And the cooling water circulating between the power electronic component 31 and the stack 10 cools the power electronic component 31 and warms up the stack 10 with the heat supplied thereto And the heat and water management system for the fuel cell vehicle. The method according to claim 1, The power electronic part 31 is used as a load consuming device which consumes current of the stack while receiving power through the cable 11 connected from the stack 10 when load consumption of the stack is required Fuel cell vehicle heat and water management system. delete delete

Images