AT399768B - Device for controlling the supply of gas to a gas burner - Google Patents

Abstract

Device for controlling the supply of gas to a gas burner, with a first throttle 3 which is located upstream of the burner in the gas-supply line 1 and which is assigned a bypass line 4 provided with a switching means for cutting in the bypass line 4 during the ignition operation when there is a temporarily increased supply of gas to the burner. In order to speed up the ignition operation, there is provision, when the burner is designed as a pilot gas burner, for the switching means to consist of a valve body 9 which is capable of being actuated counter to the action of a restoring spring 7 and which is assigned to at least one passage 8 having a larger cross section than the first throttle 3, the throughput of which corresponds to the minimum requirement of the pilot gas burner, said passage opening the bypass line 4 when the valve body 9 is in the position of rest and blocking the bypass line 4 when said valve body is in the working position. <IMAGE>

Description

AT 399 768 B

The invention relates to a device for controlling the gas supply to a gas burner according to the preamble of patent claim 1.

Such a device, as it emerges from DE-PS 9 53 903, has the effect that the full gas quantity is always released to the burner when the gas burner is started up. First of all, the gas supply line must be vented, which essentially determines the time required for the ignition. In the known device, the switching device for the bypass line consists of an electric motor-adjustable throttle valve.

From DE-GM 84 36 738 it is also known to increase the gas throughput of a gas burner during the ignition phase, so that the air located in the idle state after a long period of inactivity in the pilot burner 10 can be expelled more quickly.

Finally, AT-PS 2 70 938 shows a pilot gas burner with a pre-throttle, which has an invariable gas passage cross section that is smaller than the passage cross section of the exchangeable ignition nozzle. As a result, the ignition gas quantity is fixed.

The object of the invention is to reduce to a minimum the time required for venting the gas supply line after a break in operation when the pilot gas burner is put into operation when the burner is designed as a pilot gas burner in order to thereby start the ignition process to accelerate.

This object is achieved by the characterizing features of patent claim 1. At the beginning of the ignition process, a larger, unthrottled amount of gas can be supplied via the bypass line at the beginning of the ignition process in order to rapidly displace the air contained in the gas supply line instead of the throttled gas amount in the gas feed line.

The invention enables significant savings in ignition gas consumption because the throttle contained in the gas supply line can be dimensioned for a low throughput corresponding to the actual minimum requirement of the ignition gas burner, whereas for the ignition process, even with manual actuation of the slide against the pressure of the return spring, the larger cross section is temporarily temporary the bypass line is available.

The larger amount of gas supplied to the pilot gas burner during the ignition process also results in a considerable reduction in the holding time of the thermoelectrics during each starting process. On the other hand, due to the lower throughput of the ignition gas to be supplied in normal operation, the closing time until the pilot flame is extinguished is considerably shortened.

Finally, the device according to the invention can also be used for all types of heating devices without the need for additional devices, such as a venting ignition burner. The ignition gas supply can be monitored in the simplest way.

Embodiments of the invention emerge from the subclaims. 35 So it is possible in the formation of the device according to claim 2 or 3, the ventilation of the gas supply line to automatically occur without further action during the ignition process. For this purpose, the bypass line, which is initially open and serves to temporarily increase the gas supply to the pilot gas burner, can be closed by means of the thermostatic valve or diaphragm valve, in order thereby to limit the time span of the increased supply of pilot gas which serves to displace air. According to an advantageous development of the invention, a chamber of the diaphragm valve is connected to the gas supply line via a second, preferably controllable throttle. This second throttle causes the diaphragm valve and thus the bypass line to slowly close when the supply valve opens. The amount of gas supplied to the pilot gas burner is thereby determined by the cross section of the throttle contained in the gas supply line. 45 Furthermore, a third throttle can be arranged in the bypass line or in the gas supply line, the throughput of which is greater than the throughput of the first throttle, but smaller than that of the gas supply line itself. As a result, a comparatively large amount of gas reaches the pilot gas burner both via the gas supply line and via the bypass line, so that the air present there is quickly displaced. Devices according to the invention can be designed in various variants, some of which are explained below, for example, with reference to the drawings which show such variants in section in FIGS. 1 to 4.

It is essential in the context of the invention that the bypass line is closed immediately as soon as the ignition process has ended. 55 According to a variant shown in FIG. 1, a bypass line 4 branches off from the pilot gas supply line 1, which leads directly to the pilot gas burner 2 and contains a throttle 3, and contains a throttle 5 with a cross section which can be larger than that of the throttle 3 Bypass line 4 is in the cold state, that is, with the pilot gas flame not yet ignited, 2

AT 399 768 B open thermal valve 6, consisting of the valve body 9, which is influenced by a spring 7 and is assigned to the valve seat 8, and a temperature-sensitive element 10 formed by an Invar rod guided in a copper or brass guide, as well as the plunger 11 which can be actuated by it.

The temperature-sensitive element 10 is located in the area of the pilot flame 12, and its thermal expansion in the event of heat radiation from this flame 12 results in the bypass valve 4 being blocked by the valve 6 against the pressure of the spring 7.

The function of this pilot burner ventilation is therefore as follows:

After opening a pilot gas valve (not shown) arranged in the pilot gas supply line 1, pilot gas initially reaches the pilot gas burner 2 and displaces it via the supply line 1 and the bypass line 4 in a predetermined, i.e. comparatively large amount, predetermined by the summed cross sections of the throttles 3 and 5 the air available in this area comparatively quickly after a break in operation.

After the burner 2 has been vented in this way and the ignition flame 12 has been ignited by the ignition device 13, the temperature-sensitive element 10 is heated by this ram 12, expands and closes the bypass line 4 with the valve body 9. From this moment, the gas is only supplied with gas still on the gas supply line 1 alone, and in a determined by the throughput of the throttle 3 alone, just sufficient for the need of the pilot flame.

According to FIG. 2, instead of the temperature-sensitive element 10 in the bypass line 4, a membrane valve with the valve body 14 held by a membrane and the valve seat 15 is provided. The valve body 14 is adjusted by a plunger 16 against the action of a spring. The chamber in which the plunger 16 moves is under atmospheric pressure. The plunger 16 is connected to a diaphragm plate 18 held by the diaphragm 17, this diaphragm 17 delimits a chamber 19 which is connected to the ignition gas supply line 1 via a throttle 20, which can be regulated. If - after opening the pilot gas supply valve - the pressure in this chamber 19 increases gradually with a controllable delay by the throttle 20, the valve 14, 15 and thus the bypass line 4 is closed, and the total amount of gas supplied to the pilot burner 2 is now reduced by Cross-section of the throttle 3 contained in the pilot gas supply line 1 is limited to the minimum quantity required for supplying the pilot flame 12. The throttle 5 with the larger cross section is also arranged in the ignition gas supply line 1 in this embodiment, but it could - as indicated in FIG. 2 - also be arranged in the bypass line 4. This throttle 5 limits the amount of gas-air mixture supplied to the pilot flame as long as the diaphragm valve 14, 15 is not yet closed.

According to FIGS. 3 and 4, the organs serving to vent the pilot gas burner 2 are integrated into the pilot gas supply valve which regulates the pilot gas supply in the supply line 1.

In this embodiment, the pilot gas supply line 1 opens into the valve chamber 21, in which the valve body 22 moves, which is sealed against the valve seat 24 by means of a seal 23. is under the pressure of a spring 26 which is supported against the wall 25 of the valve chamber 21 and has in its interior a coaxial guide for a plunger 27 which in turn is influenced by a spring 28 and is sealed off from the chamber 21.

This valve body 22 is mechanically adjustable by means of the displacement sensor 31 guided in the guide 29 with the seal 30 in order, if necessary, to release the gas supply from the chamber 21 into a supply line 32 in which the throttle 3 is located, the flow cross section of which corresponds to the minimum requirement of the pilot burner 2 . The gas reaches the gas feed line 33 leading to the pilot burner via this throttle 3.

The above-mentioned tappet 27 of the valve body 22 is assigned a valve plate 14, which cooperates with the valve seat 15 via a seal and is pressed against this valve seat 15 under the pressure of a spring 16. This valve plate 14 is further influenced by this spring 16 from the diaphragm plate 18 of a diaphragm 17 which delimits a chamber 19 which is connected to the gas supply line 1 via the line 4a and an adjustable throttle 20.

If the main gas valve (not shown) is now opened, this results in a gas pressure in the chamber 19 with a delay which can be regulated by the throttle 20.

If the pilot gas burner valve 22 - 24 is now opened to ignite the pilot burner 2, gas first arrives from the pilot gas supply line 1 via the chamber 21 and via the line 32 to the pilot burner 2, in a manner limited by the pilot burner throttle 3 and corresponding to the minimum requirement of the pilot burner 2 Amount via line 33. Pressure builds up in the chamber 19 - delayed by the adjustable throttle 20, and the valve plate 14 is pressed by this pressure and by the spring 16 against the valve seat 15 and thus acts on the pressure of the displacement sensor 31 moving plunger 27 so that when the counter pressure increases, the pilot burner 2 in addition to the minimum load 3

Claims (6)

AT 399 768 B may gradually reduce the amount of gas supplied via the bypass line 4 and the supply line 33. As soon as the air in the pilot gas burner 2 is completely displaced, the pilot gas flame is ignited and a venting phase has ended, the valve 14, 15 serving for the venting can remain closed and the gas supply to the pilot flame then only takes place via the line 32, the throttle 3 and the line 33. 5 In order to ensure the proper function of this ventilation device, the following conditions must be met: In the open position of the valve 14, 15, the force of the spring 28 acting on the tappet 27 must be greater than the force of the spring 16 acting on the valve plate 14 ; in the closed position of this valve, however, it is - with the valve 22, 24 open - the reverse, the force of the spring 28 must be less than the sum of the spring force 16 and the gas pressure acting on the surface of the membrane 17. The force of the spring 26 is to be dimensioned in accordance with the requirement for gas tightness of the valve 22, 24 when the thermoelectrics have dropped or the current provided by the thermocouple in the open position. Here are also the stuffing box friction u. Similar forces to be taken into account. While the embodiment of the pilot gas valve according to FIG. 3 only provides one gas supply line to pilot gas burner nozzle 2, in the embodiment according to FIG. 4, which is otherwise largely similar to that of FIG. 3, two separate lines 33 and 34 are provided, namely a line 33 to the burner itself and a line to an ignition gas ventilation nozzle 5 for a temporarily increased gas supply which serves to displace the air. The line 33 starts from the valve chamber 21, the line 34 from the chamber 35 in which the valve 14, 15 is arranged. This vent nozzle 5 therefore only receives gas when the valve 14, 15 is still open at the start of the ignition process. 1. Device for controlling the gas supply to a gas burner with a first throttle upstream of the burner in the gas supply line, which is assigned a bypass line which is provided with a switching device for switching on the bypass line during the ignition process with a temporarily increased gas supply to the burner, thereby characterized in that · when the burner is designed as a pilot gas burner, the switching device consists of a valve body (9) which can be actuated against the action of a return spring (7) and which is assigned to at least one passage (8) which has a larger cross section than the first throttle (3 ), the throughput of which corresponds to the minimum requirement of the pilot gas burner, and which opens the bypass line (4) in the rest position of the valve body (9) and blocks it in the working position (FIG. 1). 35 2. Device according to claim 1, characterized in that a thermal valve (10, 9, 8) influenced by the pilot light (12) is provided in the bypass line (4), by means of which the latter can be closed after the ignition process has ended (FIG. 1). 3. Apparatus according to claim 1, characterized in that a diaphragm valve (14, 15) influenced by the pressure in the gas supply line (1) is provided in the bypass line (4), by means of which it can be closed after the ignition process has ended (FIG. 2). 4. The device according to claim 3, characterized in that a chamber (19) of the diaphragm valve 45 (14, 15) via a second, preferably adjustable throttle (20) with the gas supply line is in communication (Fig. 2). 5. Device according to one of claims 1 to 4, characterized by a in the bypass line (4) or in the gas supply line (1) arranged third throttle (5), the throughput greater than the throughput of the first throttle (3), but smaller than that of the gas supply line (1) itself (Figs. 1 and 2). 6. Device according to one of claims 3 to 5, characterized in that coaxially with the diaphragm valve (14, 15) influenced by the pressure in the gas supply line (1) in the gas supply line (1) a 55, the gas supply controlling pilot gas supply valve (22 - 24) is arranged such that the first throttle (3) is connected during the ignition process via a supply line (33) to that valve chamber (21) in which the valve body (22) of the pilot gas supply valve (22 - 24) moves (Fig. 3 and 4). 4 AT 399 768 B Device according to claim 6, characterized in that the bypass line (4) is connected to that valve chamber (21) (Fig. 3). Apparatus according to claim 7, characterized by a valve plate (14) of the diaphragm valve (14, 15) in the bypass line (4) (FIGS. 3 and 4) which can be actuated by the valve body (22) of the pilot gas supply valve (22-24). Apparatus according to claim 8, characterized in that the valve plate (14) can be actuated by a plunger (27) guided axially axially in the valve body (22) of the pilot gas supply valve (22-24) and even with a spring (16) against a diaphragm plate (18 ) the membrane (17) of the membrane valve (14, 15) is supported (Fig. 3 and 4). Including 4 sheets of drawings 5