DE2462795B1 - Device for regulating the pressures of hydrogen gas and oxygen gas in a fuel cell - Google Patents

Description

The invention relates to a regulation for regulation the pressures of hydrogen gas and oxygen gas in a fuel cell with a spring chamber that extends through two diaphragms formed on the middle part of a housing, a pressure regulating spring, which is in the spring chamber is arranged and acts uniformly on both membranes, two associated with the membranes and from these controlled valves, which are arranged symmetrically on both sides of the spring chamber and control the flow of gases in lines leading to the fuel cell.

A problem with a fuel cell is the need to control the pressure of the hydrogen gas and / or to equilibrate oxygen gas with the pressure of the electrolytic solution, thereby preventing that the gas flows into the chamber containing the electrolytic solution, and vice versa prevent the electrolytic solution from entering the gas chamber for the purpose that Maintain three phase zones. When the pressure equalization between the gas and the solution is destroyed is, each gas flows through the gas chamber into the electrolytic solution-containing chamber or the Electrolytic solution penetrates into the gas chambers through the chamber containing the electrolytic solution so that it becomes impossible to maintain the three-phase zones separately.

In a known device of the aforementioned type (US-PS 30 87 004) is exclusively

ίο the relevant one in the one leading to the fuel cell The pressure prevailing in the gas pipe is used directly for the regulation. However, this is only a comparison slow response of the device to pressure changes in the gas lines leading to the fuel cell possible, which is undesirable. In addition, the control process itself is more difficult and there is the There is a risk of pressure fluctuations in the gas lines leading to the fuel cell.

The object of the invention is to implement a device of the type mentioned in the introduction in such a way that control processes can be done quickly without adverse side effects. This object is achieved according to the invention in that a feedback chamber is formed on the outside of each diaphragm, each with one of the lines leading to the fuel cell is connected

The invention feeds back the pressure prevailing in the lines leading to the fuel cell whereby a quick response of the control device to pressure changes in the for Fuel cell leading gas lines is obtained. The pressure required in the gas lines can thus be achieved very accurately maintained. In addition, there is no risk of pressure fluctuations during the regulation inclen -for gas lines leading to fuel cells appear.

A preferred embodiment of the invention is characterized in that the spring chamber with the Atmosphere.This characteristic is advantageous because this makes control movements of the valve tappets easier, because one that is not negligible Body of liquid does not need to be moved,

. when the valve tappets or the pressure in the feedback chamber affect the diaphragm in question act. In the device according to US-PS 30 87 004, in contrast, such a movement of a non-negligible body of liquid

necessary.. .

Further features of the invention are protected in further claims

The invention is explained below with reference to the drawing, for example

F i g. 1 is a schematic view of a fuel cell equipped with a pressure regulating device according to FIG Invention is equipped

Fig. 2 is a longitudinal sectional view of the pressure regulating device according to FIG. 1.

Fig. 3 is a partial cross-sectional view, on an enlarged scale, of a modified pressure regulating device for the fuel cell according to FIG. 1.

F i g. 1 is a schematic view of a fuel cell provided with a pressure regulating device 50 is about an equilibrium between the pressure of the hydrogen gas and oxygen gas and the pressure to maintain the electrolytic solution. According to FIG. 1 is the fuel cell 1 made up of an oxygen gas chamber 18, a hydrogen gas chamber 19, a chamber 20 for electrolytic solution, a water

Fabric electrode 21 and an oxygen electrode 22 composed. A gas circuit 51 for hydrogen gas and a gas circuit 52 for oxygen gas are symmetrically arranged. The high pressure of the hydrogen gas and the oxygen gas is controlled by a pressure regulator 50, which will be described below is reduced, and the gas is the gas chambers 18 and 19 of the fuel cell via an ejector 53 and 54 supplied and consumed in the cell in an amount corresponding to the generated electrical energy. It is ι ο required here that the pressure in the oxygen gas chamber 18 and the pressure in the hydrogen gas chamber 19 can be kept at a constant and equal value according to the generated energy. The pressure control device 50 is designed to meet these requirements, and it is in the F i g. 2 and 3 shown.

In Figure 2 are again with 51 and 52 of The gas circuit for the hydrogen gas and the oxygen gas is designated, and 55 and 56, respectively, are the Feed device for the hydrogen gas and the oxygen gas respectively. The pressure regulating device 50 is arranged between the two gas circuits 51 and 52 and the two gas supply devices 55 and 56 and designed so that both pressures are controlled at the same time.

The pressure regulating device 50 has a pressure regulating spring chamber 63, which is formed by two diaphragms 62 and 62 'and provided on a central part of a hollow case 61. In chamber 63 a pressure regulating spring 64 is arranged. Two pressure control valve devices for the gas circuit 51 and 52, respectively are arranged symmetrically on both sides of the spring chamber 63.

Exiting gas from outlet 66 of pressure regulating device 50 is via line 51 and the Ejector 53 led to the gas circuit of the fuel cell. This gas cycle, d. H. the gas consumption system, comprises the ejector 53, the gas chamber 19 of the fuel cell and the gas cooler 5. The in Fig.2 Containers shown but not designated are tanks. For example, that is assigned to line 51 Container is a tank into which the nozzle, not shown, of the ejector 53 opens. Also the feedback line is connected to the tank. The in Fig. 2 indicated downstream of the tank in question, in the line switched element is a throttle, which is chosen so that that amount of gas passes through it, which in the fuel cell is consumed during the generation of electrical energy.

One of the pressure regulating valve devices will be described below. The device has a Gas inlet 65, which is connected to the gas supply device 55, and a gas outlet 66, which is connected to the Gas circuit 51 is connected. A valve member 67 opens or closes an opening 68 which corresponds to the gas inlet opening 65 and the gas outlet opening 66 is in communication. The valve member 67 is on a valve tappet 69 attached, which is permanently in contact with the membrane 62 and by means of a spring 70 permanently in Direction against the valve seat of the opening 68 is printed will. Two pressure feedback chambers 71, 7Γ are provided on both sides of the spring chamber 63, and the pressure from the gas circuit 51 is fed to the feedback chamber 71 via an opening 72. An O-ring 73 creates a seal between the gas exit port 66 and the pressure feedback chamber 71, and an O-ring 74 creates a seal between the gas inlet 65 and the atmosphere.

The other pressure control valve device for the The gas circuit 52 and the gas supply device 56 are designed in the same way, and the corresponding ones Reference characters are provided with a "'". At 63a is a hole for introducing atmospheric pressure into the Spring chamber 63 designated. _

The pressure control device 50 described above operates as follows. From the gas supply directions 55 and 56 flows into the housing 61 via the gas inlet 65 'and 65, respectively, when the Valve 67 'or 67 is open, through the opening 68' or 68 and the gas outlet 66 'or, 66 to the relevant Gas circuit 52 or 51. The pressure in the gas circuit 52 and 51 changes with the amount supplied gas, however, it is in the feedback chamber 71 'or. 71 out and regulated therein according to the following description.

If the friction on the O-rings 73 and 74 or 73 'and 74' and on the membrane 62 or 62 'is neglected, since the diameter of the O-ring 73 or 74 is equal to the diameter of the O-ring 73 'or 74', in order to keep the pressure on the gas supply side to balance the pressure on the gas discharge side or gas consumption side, the force of pushing the Valve tappet 69 or 69 'against the spring 70 or 70' the sum of a force that is caused by Multiply the pressure in the spring chamber 63 by the effective area of the diaphragm 72 or 72 'and an opposite force of the pressure regulating spring 64. On the other hand, the opposite force is the sum of one Force caused by multiplying the internal pressure of the pressure feedback chamber 71 and 71 'with the effective area of the membrane 62 or 62' and the force of the spring 70 or 70 '. The difference between the two forces serves as a force for moving the valve tappet 69 or 69 'in the direction against the spring 70 or 70 ', d. H. as a force to open the valve 67 or 67 '. Accordingly, the Pressure in the gas consumption part or gas circuit 51 and 52 determined by the force that the Valve tappet 69 or 69 'actuated, or by the force of the pressure regulating spring 64. If thus with the valve open 67, 68 the pressure behind the gas outlet in the gas circuit 51 rises, so does the pressure in the Feedback chamber 71 so that the counteracting force of the spring 64 increases. Through this the valve member 67 can move under the action of the spring 70 in the direction against the closed position move so that less gas or no gas is supplied through valve 67,68 and the pressure im Gas circuit 51 and thus also in the feedback chamber 71 decreases. So now the force of the spring is acting 64 counteracts a smaller force, and the valve member 67 is under the action of the spring 64 according to FIG. 2 shifted up, d. H. into a position in which again a larger amount of gas through the valve 67,68 flows through it into the gas circuit 51. The effect of the pressure regulation in the gas circuit 52 is the effect the same in the gas circuit 51, so that a separate description is not required.

In the pressure regulating device 50 according to the invention, there are two valves 67, 67 ', each of which is the same Has size and design, symmetrically but arranged as a unit, and it is a single compression control spring 64 is used to automatically generate the force acting on the membrane 62, 62 '. aside from that the pressures in the two gas circuits are 51,52

regulated by the pressure regulating device 50 so that they have the same pressure without other special Funds are used.

In order to make the pressure range of the gas circuits 5.1, 52 controllable, the force of the pressure regulating spring 64 can be made adjustable, as shown in Fig.3. Fig.3 shows an embodiment of the Spring chamber 63 according to FIG. 2, a device being provided to adjust the preset pressure change by changing the compressed length of the spring 64.

The force of the spring is changed by appropriate Change the compressed length of the spring. In this exemplary embodiment, the pressure regulating spring is composed of two springs 75 and 76. The spring 75 is between the diaphragm 62 and one spring seat 77, and the spring 76 is between the other Diaphragm 62 'and a spring seat 78 are arranged. Each spring seat 77,78 is supported such that. he along of guide pins 79 and 80 can move axially. A device 81 which adjusts the spring force has a bolt 82 which is screwed into the spring seat 77; a bolt 83 which, conversely, is screwed into the spring seat 78 is screwed, and a rod that has a flange-like display device 84 on the middle part Has. An actuation opening 85 is provided on the housing 61 and usually through a cover 86 closed. The guide pins 79 and 80 are connected to the valve housing 61.

When the force of the pressure regulating springs changed to 76.75

ι ο is to be, the actuating disc 84 is rotated to thereby displacing the valve seats 77 and 78 axially and relative to one another, with rotation of the rod is prevented by the guide pins 79 and 80. In this way, the force of the pressure regulating spring 75.76 to be changed.

As described above, with the single pressure adjusting valve according to the invention, the pressure of the The hydrogen gas system and the oxygen gas system can be set to the same value, and at the same time this pressure can easily be set to a desired value.

1 sheet of drawings

Claims (5)

Patent claims: 1. Apparatus for controlling the pressures of hydrogen gas and oxygen gas in a fuel cell with a spring chamber, which is through two diaphragms on the middle part of a housing is formed, a pressure regulating spring, which is arranged in the spring chamber and evenly on both diaphragms acts, two valves assigned to the diaphragms and controlled by them, which are arranged symmetrically on both sides of the spring chamber; and the flow of gases in to Control lines leading to the fuel cell, characterized in that on the outside each membrane (62 or 62 ') a feedback chamber (71 or 71') is formed, each of which is in communication with one of the lines (51 or 52) leading to the fuel cell (1) 2. Apparatus according to claim 1, characterized in that the spring chamber (63) is connected to the atmosphere (via 63a). 3. Apparatus according to claim 1 or 2, characterized in that each feedback chamber (71 or 71 ') in the housing of the device (50) opposite the relevant gas flow line . (6! -C §6 ^ ZW. 65 /, 66 '}' "is sealed (by Diclitungsririg ^ or TS ') /'; 4. Device according to one of claims i to 3J characterized in that each valve has a tappet connected to a valve member (67 or 67 ') (69 or 69 '), der.niiit, the relevant Membrane (62 or 62 ') is in constant contact and in the direction against the closed position of the Valve is spring-loaded (by spring 70 or 70 '). 5. Device according to one of claims 1 to 4, characterized in that the spring in the Spring chamber (eaje'inbaren.dst .:: ...!. S. Device according to claim 5, characterized in that the spring has two individual springs (75, 76), in which the vp.n-der. Membrane (respectively 62; 62 ') entfernt.liegende _r En.de to, a fed ^ rsitz (7.7 or 78) arranged ISTJ and that is screwed into each spring seat, a threaded portion (82 or 83) _t the opposite thread, have . , "', ...