DEP0014101DA - Pressure reducing valve for welding systems - Google Patents

Description

The innovation relates to pressure reducing valves for welding systems, in which a spring-loaded membrane acted upon by the gas pressure in the valve outlet line actuates the valve which controls the connection between the gas reservoir and the valve outlet line leading to the consumer.

Such pressure reducing valves have the task of automatically relieving the high pressure pressurized gas flowing from the gas reservoir to the consumer to a lower operating pressure that remains constant regardless of the state of the gas in the reservoir.

Known devices of this type are composed of two housing parts, which have the connecting pieces for the gas supply line and the gas outlet line and the connecting pieces for two pressure gauges for measuring the pressures prevailing in both lines on the outside. An adjusting screw also passed outward through the housing wall is used to change the pretension of the spring loading the membrane and thus to change the operating pressure of the gas flowing through. The valve, its spring and the spring pad, on the other hand, which become dirty when using impure gas and can also wear out due to mechanical influences as moving parts, are only accessible after unscrewing and turning the housing upside down, because they are stored directly in the housing, ie embedded in a housing bore. Each of the parts must be individually inserted into the housing and removed again individually.

In contrast, the subject matter of the invention is structured more expediently. With it, all moving parts that can be contaminated during normal operation are built into a cartridge and fastened in a known manner, e.g. by screwing them into the housing. As a result of this measure, if the device fails, the cartridge, which contains all parts susceptible to failure, can be quickly replaced, making the device operational again.

In a further embodiment of the invention, the cartridge is not screwed into the housing from the inside, but from the outside. This has the advantage that the housing does not have to be disassembled when the cartridge has to be replaced.

In the drawing, an embodiment of the new pressure reducing valve is shown.

Fig. 1 shows a longitudinal section and

Fig. 2 a cross section along line I - I.

The housing of the device is in two parts. On the upper part 1, the connecting piece 1a for the gas supply line, the connecting piece 1b for the gas outlet line, the connecting piece 1c and 1d for the pressure gauges 2 and 3 and the connecting piece 1e for the valve housing 4, and the screw-in nozzle 1f for the membrane 5 are arranged, which has the lower part 6 of the housing as an abutment. The valve housing 4, protected from external influences by a capsule nut 7, contains the valve 8 with valve seal 8a, the spring 9, the spring supports 10 and 11, the sieve 12 and the nuts 13 and 14; Of these parts, the valve housing 4 and the nuts 13 and 14 form the cartridge, which can be replaced together with the valve 8, the spring 9, the spring supports 10 and 11 and the sieve 12 without dismantling the device housing and without removing line connections.

In the valve housing 4 grooves 15 are milled, which directly connect the gas supply channel A with the pressure chamber. The membrane 5, which is acted upon by the pressure in the pressure chamber C and the outlet channel D on the one hand and by the spring 16 and the pressure of the atmosphere on the other, carries the pin 17 which acts on the valve 8 when the device is started up. The preload of the spring can be changed with the adjusting screw 18.

The device works as follows:

the pressure medium is passed through the gas supply channel A and through the grooves 15 into the pressure chamber B. Since there is no operating pressure in space C, only atmospheric pressure, the spring 16 pushes the membrane 5 and the pin 17 upwards, the latter lifting the valve 8 from its seat in the valve housing 4. As a result, the pressure medium can also in the space C and flow into the outlet channel D leading to the welding or cutting torch. The valve 8 remains open as long as the operating pressure is not reached. As the pressure increases in space C, however, the membrane 5 bends more and more downward against the resistance of the spring 16. The valve 8 approaching its seat begins to throttle the amount of pressure medium flowing through. As soon as the pressure in pressure space C has risen to the operating pressure, it completely separates the channel between space B and space C. If the pressure in the pressure chamber C falls below a certain level again, the pin 17, under the action of the spring 16, lifts the valve 8 from the seat again until the pressure medium required to reach the target pressure (operating pressure) has flown again.

Claims (4)

1.) Pressure reducing valve for welding systems, in which a spring-loaded membrane acted upon by the gas pressure in the valve outlet line actuates the valve which controls the connection between the gas reservoir and the valve outlet line leading to the consumer, characterized in that the valve is in a housing (1) The cartridge (4, 13, 14) attached to the pressure reducing valve is installed. 2.) Pressure reducing valve according to claim 1, characterized in that the cartridge (4, 13, 14) is inserted from the outside into the housing (1, 6), preferably screwed. 3.) Pressure reducing valve according to claims 1 and 2, characterized in that the valve (8) loading compression spring (spring 16) is supported against a nut (13) which is held as an abutment for a by a second nut (14), the gas-cleaning sieve (12) is used. 4.) Pressure reducing valve according to claims 1 to 3, characterized in that the outwardly protruding part of the cartridge is surrounded by a cap nut (7) and the annular space formed by these two parts is in communication with the gas reservoir through grooves (15).