KR101372195B1 - Solenoid valve for fuel cell and method for controlling the same - Google Patents

Abstract

The present invention relates to a solenoid valve device for a fuel cell and a method of controlling the operation thereof. More particularly, the plunger is operated with a large instantaneous force by using a peak coil, so that freezing of the valve of the fuel cell can be always performed. A fuel cell solenoid valve and its operation control method.
That is, the present invention incorporates a separate peak coil in addition to the hold coil in the solenoid valve which is adopted in the fuel cell system to drain water, and applies a current to the peak coil at the time of freezing, so that the plunger eliminates the freezing state of the valve. It is an object of the present invention to provide a solenoid valve device for a fuel cell and a method of controlling the operation thereof so that a smooth operation of the valve can be achieved even in a frozen state by linear movement with a large instantaneous force.

Description

Solenoid valve device for fuel cell and its operation control method {Solenoid valve for fuel cell and method for controlling the same}

The present invention relates to a solenoid valve device for a fuel cell and a method of controlling the operation thereof. More particularly, the plunger is operated with a large instantaneous force by using a peak coil, so that freezing of the valve of the fuel cell can be always performed. A fuel cell solenoid valve and its operation control method.

The fuel cell system includes a fuel cell stack for generating electric energy, a fuel supply system for supplying fuel (hydrogen) to the fuel cell stack, an air supply system for supplying oxygen in the air, which is an oxidant for the electrochemical reaction, A heat and water management system for controlling the operating temperature of the fuel cell stack, and the like.

In the operation of such a fuel cell system, since the nitrogen or water accumulates on the hydrogen electrode (fuel electrode) side of the fuel cell stack and degrades the performance of the stack during cold startup, stable performance of the stack must be ensured through periodic purging.

As shown in FIG. 3, a water trap 102 is installed in the fuel supply line to remove water generated or condensed in the fuel cell stack 100. It is a kind of water discharging device that drains the water when the water reaches a predetermined level by receiving the stack water, and a solenoid type discharge valve 104 is mounted on the discharge port to open and close the water.

Therefore, when a certain amount of water or more is stored in the water trap 102, the water level detection sensor 106 detects this and at the same time the discharge valve 104 of the bottom of the water trap 102 is opened, the water is discharged .

Meanwhile, as shown in FIG. 4, the cooling system of the fuel cell vehicle includes a first cooling water circulation route through which the coolant circulates through the radiator 1 and the heat exchanger 2, and the pump 4 in the fuel cell stack 3. And a second coolant circulation route through which coolant is circulated through the reservoir (5) and the heat exchanger (2), and the fuel cell stack and the second coolant circulation route have separate rapid thaw assemblies (6) and drains. It is connected through the passage.

In this case, each of the drain passages is provided with a solenoid valve-type drain valve 7 so that when the outside temperature drops below zero, the drain valve 7 is opened to drain the second coolant circulation route and the coolant in the fuel cell stack. In order to prevent freezing of the coolant, on the other hand, when the vehicle is restarted, the drain valve 7 is closed and the coolant stored in the quick thaw assembly 6 is pumped through the pump to fill the second coolant circulation route. have.

As described above, various valves are installed in the fuel cell system. As described above, the discharge valve mounted at the outlet of the water trap and the drain valve mounted at the drain passage of the cooling water circulation line are all adopted as solenoid valves.

As the solenoid valve performs the opening and closing function for the discharge of water, there is a problem that the plunger operation in the solenoid valve is not smoothly performed according to the freezing of water during the winter season.

As a conventional method for solving the icing problem, a separate heater (PTC, Cartridge, Silicone rubber heater, etc.) is mounted on the valve body of the solenoid valve as shown in FIG. The method of smoothly operating the valve by eliminating the problem has been applied, but it takes a long time until the freezing state is resolved through the heater operation, and power consumption for the heater operation is inevitable.

As another conventional method, as shown in FIG. 6, an inclined plunger is installed in the valve body, and surface treatment is performed to prevent moisture from forming on the plunger surface, thereby preventing the plunger from sticking due to water condensation. Although one operation is induced, there is a problem that the plunger portion may freeze because it is difficult to completely remove the moisture, which may cause the valve not to open when a signal is input, which may cause a trouble during cold start up. .

The present invention has been made in view of the above, and a separate peak coil is incorporated in a solenoid valve that is adopted in a fuel cell system and functions to drain water, and a large current is applied to the peak coil during freezing. Accordingly, an object of the present invention is to provide a solenoid valve device for a fuel cell and a method of controlling the operation thereof, in which a plunger linearly moves with an instantaneous large force for releasing a freezing state of a valve so that a smooth operation of the valve can be performed even in a freezing state.

One embodiment of the present invention for achieving the above object is a fuel including a plunger embedded in the valve body of the solenoid valve to be lowered, a hold coil disposed on the outer peripheral portion of the plunger, and a core embedded in the upper end of the plunger A battery solenoid valve device comprising: a peak coil for operating the plunger upon freezing between the plunger and the hold coil, wherein the peak coil is adopted to have an increased coil diameter and number of turns compared to the hold coil. Provided is a battery solenoid valve device.

The solenoid device of the present invention is characterized in that it further comprises a relay mounted to a power supply line for applying a current to the peak coil.

Another embodiment of the present invention for achieving the above object comprises the steps of: determining the freezing state of the solenoid valve; Upon freezing of the solenoid valve, applying a large current to the peak coil relative to the hold coil such that the plunger operates while releasing the freezing; Releasing the frozen state, releasing the current applied to the peak coil by controlling the relay mounted in the power supply line of the peak coil off from the controller; In determining the icing state of the solenoid valve, it is characterized in that the solenoid valve is determined to be frozen if the temperature of the fuel cell is sensed below the reference temperature.

Preferably, the time that the current is applied to the peak coil is characterized in that it can be adjusted according to the intrinsic value of the resistor and the capacitor which is an internal element of the controller.

In addition, the plunger is operated by the current applied to the hold coil after the releasing of the solenoid valve.

Through the above-mentioned means for solving the problems, the present invention provides the following effects.

According to the present invention, the plunger performs freezing by installing a peak coil in which a large current is applied when the ice is separated from the original hold coil in the solenoid valve, and applying current to the peak coil in the state where freezing occurs in the solenoid valve of the fuel cell. By eliminating the linear motion with a large instantaneous force while solving, smooth operation of the valve can be achieved even in a frozen state, and the cold start time of the fuel cell vehicle can be minimized.

In addition, since the peak coil is selectively operated according to the frozen state of the solenoid valve, the power consumption of the valve can be minimized.

In addition, only a peak coil may be additionally added to the solenoid portion without changing the solenoid valve body or the plunger structure, that is, without increasing the overall valve size.

1 is a cross-sectional view showing a solenoid valve device for a fuel cell according to the present invention;
2 is an operating circuit diagram of a solenoid valve device for a fuel cell according to the present invention;
3 and 4 is a schematic diagram illustrating a position where the solenoid valve is mounted in the fuel cell system,
5 and 6 are schematic views showing a conventional solenoid valve.

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

The present invention focuses on the fact that, when the solenoid valve applied to the fuel cell system is frozen, the valve can be operated smoothly while releasing the frozen state.

As shown in FIG. 1, the solenoid valve 10 includes a plunger 12 which is built in a valve body 11 so as to be lowered and a hold coil 13 disposed at an outer circumference of the plunger 12. Including a core 14 embedded in the upper end of the plunger 12, when the current is applied to the holding coil 13 as usual, as the core 14 is magnetic and pulls the plunger 12 upwards When the current applied to the hold coil 13 is released, the plunger 12 is lowered by the elastic restoring force of the spring 18 when the flow path 17 formed at the lower end of the plunger 12 is opened. ) Is closed.

In this way, if the solenoid valve is frozen (fixed), that is, the plunger in the valve is frozen (fixed), smooth operation of the valve does not occur, affecting cold startability and affecting the overall fuel cell system. The operating efficiency will be reduced.

The present invention is to operate the plunger 12 with a momentary large force in order to solve the icing (fixed) state of the solenoid valve 10, that is, the icing (fixed) state of the plunger in the valve can be raised and lowered, Between the plunger 12 and the hold coil 13 there is embedded a peak coil 15 for operating the plunger 12 upon freezing.

The peak coil 15 is adopted to increase the diameter and the number of turns compared to the hold coil 13 so that a large current can flow.

In this case, as shown in FIG. 2, a power supply line for supplying current to the peak coil 15 is equipped with a relay 16 controlled on / off by the controller 19.

Thus, by additionally installing a peak coil so that a large current can be applied to the solenoid valve, the freezing state of the valve can be quickly eliminated, and the operation process thereof will be described in more detail as follows.

First, the step of determining the icing state of the solenoid valve 10 is preceded, in determining the icing state of the solenoid valve 10, if the temperature of the fuel cell is detected to be below the reference temperature, the solenoid valve 10 is frozen. It is determined that it has been done.

When it is determined that freezing is generated by using the outside temperature of the vehicle or the operating temperature of the fuel cell stack, the current is applied to the peak coil, and when it is determined that the freezing does not occur, the current is not applied to the peak coil.

Thus, upon freezing of the solenoid valve 10, a large current is applied to the peak coil 15 so that the plunger 12 operates while releasing the freezing.

 That is, since the peak coil 15 has an increased diameter and number of turns compared to the hold coil 13, a current larger than the current applied to the hold coil 13 is applied to the peak coil 15.

In this case, the time that the current is applied to the peak coil 15 can be adjusted according to the intrinsic values of the resistor and the capacitor, which are internal elements of the controller 19, and after the plunger is released from the frozen state, the peak coil 15 is supplied with power. The relay 16 mounted in the line is controlled by the controller 19 to release the current applied to the peak coil 15, thereby minimizing the power consumption of the valve.

Therefore, when a large current is applied to the peak coil 15, as the core 14 becomes magnetic and pulls the plunger 12 with an instantaneous large force, the plunger 12 moves up and down while eliminating a freezing state. The flow path 17 is opened.

On the other hand, after the freezing of the solenoid valve 10, the relay 16 mounted on the power supply line of the peak coil 15 is controlled by the controller 19 to release the current applied to the peak coil 15. Then, after the current is applied to the hold coil 13 of the solenoid valve 10, the plunger 12 is operated normally.

10: Solenoid valve
11: valve body
12: plunger
13: hold coil
14: core
15: peak coil
16: relay
17: Euro
18: spring
19: Controller

Claims (6)

delete delete Determining an icing state of the solenoid valve 10;
When the solenoid valve 10 is frozen, the solenoid is supplied with a current larger than the current applied to the hold coil 13 disposed at the outer circumference of the plunger 12 of the solenoid valve 10 so that the plunger 12 is operated while releasing the freezing. Applying to a peak coil (15) embedded between the plunger (12) of the valve (10) and the hold coil (13);
After releasing the freezing state, controlling the relay 16 mounted on the power supply line of the peak coil 15 from the controller 19 to release the current applied to the peak coil 15;
Solenoid device operation control method for a fuel cell comprising a.
The method of claim 3,
In determining the icing state of the solenoid valve (10), when the temperature of the fuel cell is sensed, if the reference temperature is less than the solenoid valve (10) operating control method characterized in that it is determined that the icing.
The method of claim 3,
The method of controlling the operation of the solenoid device for a fuel cell, characterized in that the time for which the current is applied to the peak coil (15) is adjustable according to the intrinsic values of the resistor and the capacitor which are internal elements of the controller (19).
The method of claim 3,
After releasing the freezing of the solenoid valve (10), the plunger (12) is operated by the current applied to the hold coil (13) operating control method for a fuel cell.

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