DE2903187A1 - Gas appliance control valve - gives thermo-mechanical or electromechanical actuation in same housing using preloading spring on main valve - Google Patents

Abstract

A change-over valve for a servo-controlled gas appliance includes a main gas valve which is preloaded by a spring in the closing direction and lies between the gas inlet and outlet to the burners in a housing. Its diaphragm actuator is controlled by a pressure control valve. The housing also contains a recess. In the version shown, this recess accepts a mechanical drive for the rocker with the closing elements. This is controlled by a liq-filled temp. probe which acts through a capillary on the diaphragm actuator for a snap spring.

Description

The invention relates to a switchover valve

pneumatic module according to the preamble of claim 1, such as it can be used in particular in servo-controlled gas regulators. the end DE-OS 27 03 438 is a gas regulator with one of a. Pressure regulator over a diaphragm drive controlled main valve influencing the gas flow to the consumer as well as a switch-on solenoid valve controlled by a temperature sensor known, which connects the pressure regulator to the gas supply side of the gas regulator. This The gas regulator is equipped with a second pressure regulator1 and it is a gas path switch provided, which one or the other pressure regulator to the diaphragm drive of the main valve connects. According to Figure 3 of DE-OS 27 03 438, an expansion temperature sensor acts Via a membrane capsule on a closing body support designed as a two-armed rocker one facing two valve seats, which are connected to the two pressure regulators are. Fig. 6 of DE-OS 27 03 438 shows a gas regulator1 in which the gas path switch is formed by an electrically excitable switchover solenoid valve.

The object of the invention is to provide a gas regulating device suitable for such gas regulating devices To create a building block that can be used in conjunction with various other components can be used and designed in such a way that at least its base body is both in connection can be used with an electromagnetic as well as a thermal-mechanical drive is.

This object is achieved by what is characterized in claim 1 Invention. Advantageous refinements result from the subclaims. the Invention leads to a clearly arranged assembly phases that are consecutive to one another verifiable structure of a switching valve and cheaper to manufacture such Blocks especially in that for electrically controlled and for mechanically controlled Changeover valves of the same base body1 are used, for example, made of die-cast aluminum will. In the case of an electromagnetically operated changeover valve, ever Depending on the application, either a low-voltage DC voltage or an on the mains AC voltage can be connected to the electromagnet as a drive. In the case of a mechanically operated changeover valve, either a drive can be used use with a membrane capsule that is connected to a liquid-filled tube via a capillary tube Temperature sensor is connected; or it becomes one on the thermal expansion a sensor rod based temperature sensor connected, as it is from DE-GBM 78 13 579 is known. Instead, a bimetal can also be used as the drive or the valve can be switched over by hand. But not only On the drive side there is a multitude of design options, but the same also applies to the output side of the switchover valve, in particular when the common base body is also a connection device for one has switchable pressure regulator for the switching valve. Then you can for example either a manually adjustable conventional diaphragm pressure regulator or a Step pressure regulator according to DT-AS 15 50 293 or one of an expansion temperature sensor Controlled pressure regulator with a wide modulation range according to DT-AS 26 46 310 put on or vein separate connection plate several pressure regulators optionally via the Switch on the switching valve.

The invention is illustrated below with the aid of exemplary embodiments shown in the drawings explained. 1 shows a servo-controlled gas regulator with a main valve, a standard pressure regulator and a changeover valve controlled by an expansion sensor; Fig. 2, on an enlarged scale, the structure of the switching valve including the drive in easy modified form; 3 shows a corresponding representation of an electromagnetic Drive for the switching valve; and FIG. 4 in one of FIG. 1 corresponding illustration of a gas control device with two switching valve modules according to the invention 1 of which one is connected to a room thermostat, for example connected electromagnetic drive and the other one, for example thermal / mechanical drive controlled by a boiler temperature sensor and a standard pressure regulator to control the servo pressure in the diaphragm chamber of the Has main valve.

As FIG. 1 shows, the base body 1 of the pneumatic module a substantially cuboid shape with a smooth underside 2 and a stepped Upper side, on the slightly lower part 3 of which a pressure regulator 4 is placed is, while the slightly higher part 5 carries the drive 6 and immediately the Enclosing housing chamber 7 for the switching valve.

The pressure regulator 4 is sandwiched by an annular seal 8 placed on a circular recess 9 of the top surface 3; its valve seat 30 is sealed off from the bottom surface of the recess 9 by a sealing ring 11 and is connected to a line groove 12 in the bottom surface 2 of the base body 1. The control pressure acting on the membrane 13 reaches the chamber below the Membrane. For this purpose, the plate 14, which at the same time forms the valve seat 10, has at least an opening 15 through which the chamber below the membrane 13 with a Line groove 16 is in connection, which is also in the bottom surface 2 of the base body 1, the better overview chain in the drawing, however, as the inner one Channel is shown.

The slightly higher part of the base body 1 encloses a chamber 7, in which a rocker 18 is tiltably mounted about an axis 17.

It carries a closing body 19 or 20 at each of its two ends and is under the bias of a return spring 21. On a shoulder 22 of the Chamber wall is on the one hand an angled bracket 23 and on the other hand by means of a rivet a snap spring 24 attached, its arched dead center spring 25 is inserted into a notch in the central part of the bracket 23. On the two side legs 26 of the snap spring 24 acts an actuator bridge 27, which is in two lateral Guides 53 of the housing chamber 7 is guided. The base plate 6 of the drive holds in a nozzle 28 a membrane capsule 29, which is under the action of a spring 30 is supported on an adjusting screw 31. This allows the support point fixed to the housing the membrane capsule 29 can be adjusted. The membrane capsule 29 is via a capillary tube 32 connected to a liquid-filled temperature sensor 33. The one with the Movable membrane of the capsule 29 connected actuator pin 34 adjusted via a lever 35 fixed to the housing, the actuator bridge 27.

Two valve seats 36 and 37 are provided in the bottom of the housing chamber 7, which work together with the closing bodies 19 and 20. The housing chamber is also available 7 via the channel 12 with the valve seat 10 of the pressure regulator 4 in connection.

This is also via a channel 38 in the housing 39 of the to be controlled Gas valve, the diaphragm chamber 40 below the membrane controlling the main valve 41 connected. The closing body 42 of the main valve works with an intermediate Inlet 43 and outlet 44 of the gas valve arranged valve seat 45 together and is biased by a spring 46 in the closing direction.

In Fig. 1, the gas regulator is shown with the main valve 42/45 open. This means that the temperature measured by the temperature sensor 33 is below the desired setpoint and consequently the burner connected to the outlet 44 Gas is supplied. The pressure regulator regulates the amount of gas flowing through. The pressure regulator 4 receives its inlet pressure via the channel 47 and the throttle 48, the valve seat 37 and the channel 12 from the inlet side 43 of the gas control device here. If the pressure on the outlet side 44 increases, this increased pressure occurs via the channels 49 and 16 as well as the hole 15 in the valve seat plate 14 in the space below the pressure regulator membrane 13, so that this against the force of the spring 50 is lifted from the valve seat and the closing body 51 connects between the control chamber 40 below the membrane 41 on the one hand and the outlet 44 on the other hand so that the control pressure in the chamber 40 to the outlet 49, 44 is reduced is and the closing spring 46 the closing body 42 in the direction of the valve seat 45 moves. When the outlet pressure drops, the process runs in the opposite direction, i.e. the valve 42/45 is opened further.

If the temperature measured by the temperature sensor 32 exceeds, for example the room temperature or boiler water temperature using the adjusting screw 31, the expansion liquid expands and presses over the lower membrane and the actuator pin 34 and the lever 35, the actuator bridge 27 downwards, so that the snap spring 24 is under the influence of its dead center spring 25 turns. The dead center spring 25 pivots over the rocker attachment 52, the Rocker 18 clockwise so that valve 20,37 closes and valve 19,36 opens. The pressure regulator 4 is thus switched off. Pressure equalization takes place between the pressure in outlet 44 via channel 49, housing chamber 7, channels 12 and 38 to the diaphragm chamber 40, so that the closing spring 46 closes the valve 42, 45.

If the temperature measured by the temperature sensor drops and pulls the membrane capsule 29 together, the actuator bridge 27 releases the snap spring 24 free, so that the return spring 21 the closing body support 18 again in the The position shown in the drawing swivels back.

In FIG. 2, those parts which have already been shown on the basis of FIG. 1 have been given the same reference numerals. The actuator bridge 27 is slidable on both sides in a rail 53 fixed to the housing. Included the actuator bridge 27 is attached to the transmission lever 35 by means of a leaf spring 54, permanent deformation in the event of an excessive rise in temperature the To prevent leaf spring 24 by the force exerted by the pin 34. In Fig. 2 is the pivot axis zers rocker 18 rotated by 900 so that the leaf spring 24 andV rocker 18 extending in mutually perpendicular directions and thus the space requirement for accommodating these parts in the housing chamber 7 is further reduced. A seal 55 ensures that the chamber 7 is sealed in a gas-tight manner.

In FIG. 3 there is a leaf spring 60 on the shoulder 22 of the housing chamber wall attached, which at its free end has an armature 61 made of magnetizable material wearing. This stands for the pole pieces 62 of an electromagnet serving as a drive opposite the excitation coil 63 as well as the magnetic core 64 in a synthetic resin block 65 is cast and via also cast connection pins 66 to an outer Power source can be connected. The cast resin block 65 covers, if necessary with the interposition of a seal 1, the housing chamber 7 is gastight. In the shown In the switching position, the electromagnet 62/64 has attracted the armature 61. So has a Return spring, not shown, pivoted the rocker 18 in such a way that the closing body 20 from the yentilsitzl37 lifted off. If the power supply to the excitation coil 63 is interrupted, the magnet 61 falls off and presses the rocker 118 via the leaf spring 60 that bears it in the opposite position so that now the valve 120, 137 closes and that which is not shown other valve opens.

Fig. 4 shows an example of the versatility of the Switching module according to the invention. Here is a first gas valve 39 Module consisting of base body 101 and electromagnetic drive 63,64 as well as on top of this a second module consisting of base body 1, thermal / mechanical Drive 6 and pressure regulator 4 attached. The individual connection channels are the For the sake of clarity again within the individual base bodies or within shown lying on an intermediate plate. Run in practice However, they largely act as open grooves in the bottom sides of the base body and are outwardly through sealing plates 170 hzw .. 171 covered. In the embodiment shown, the main valve 42, 45 is separated by two Controlled by a temperature sensor, for example, the boiler water temperature measuring hydraulic temperature sensor or acts on a membrane capsule 29, as well as by a not shown to the connecting pins 66 of the solenoid drive 63,64 room thermostats connected via a voltage surge. Only if both the room thermostat means the room temperature has dropped below that on the room thermostat set setpoint reports, as well as the boiler water thermostat 33 indicates that the measured boiler water temperature does not lead to the desired heating of the room is sufficient, the main valve 42,45 is opened so that gas through the outlet 44 to Burner flows and the boiler water is heated. In Figure 4, the gas regulator is in this position is shown with the main valve open.

Since the room temperature is below the desired value, the room thermostat has its contact closed, and the current flowing through the coil 63 leads to that the armature 61 rests on the magnet core 64 and the return spring 121 rests against the rocker 118 pivots until valve 120/137 is open and valve 119/136 is closed is. Since the measured boiler temperature is also below the setpoint, the Membrane capsule 29 compressed so far that the snap spring 24 is in the upper Discharge is located and the rocker 18 opens the valve 20/37 and the valve 19/36 closes. The inlet pressure thus passes from inlet 43 via channel 47 and the throttle 48 into the housing chamber 107, from there via the channel 172 and the valve 20/37 in the housing chamber 7, which in turn via the channel 173 with the output 12 of the Pressure regulator 4 and via the channel 38 with the membrane chamber 40 of the drive for the main valve is in communication. The input 16 of the pressure regulator is via the Channel 49 connected to outlet 44 of valve 39. The pressure is thus regulated in the manner described above with reference to FIG.

If the boiler water temperature rises above the setpoint, it switches the membrane capsule 29 turns the rocker 18 and blocks the control gas connection to the Pressure regulator 4 through valve 20f37. This closes in the manner described above the main valve 42J45.

The same thing happens when the room temperature exceeds the setpoint and thus the armature 61 drops and the rocker 118 switches all the more. Then that closes Valve 120/137; that in turn no control gas pressure can reach the diaphragm chamber 40. If both rockers 18 and 118 are in the opposite switching position 4, then t4 membrane chamber 40 stands over channels 38, 173, 174, 175 and 49 with outlet 44 in connection. Only the temperature sensor 33 reports an exceedance of the setpoint, the same applies. However, only the room temperature has the setpoint exceeded without the boiler water temperature having reached the setpoint, see above the connection from the diaphragm chamber 40 to the outlet 44 takes place via the channels 38, 173, chamber 7, valve 20/37, channel 176, chamber 107, channel 49 to the outlet; and thus In this case, too, the closing spring 46 can be the main valve.

Close 42/45 and cut off the gas supply to the burner.

The invention leads to a versatile building block which, like In particular, Figure 4 shows the assembly of gas control devices which disassociate Sensors are controlled via different drives, with such a gas control device characterized by a particularly compact design.

As already mentioned at the beginning, the pressure regulator 4 can also be operated by others Types of pressure regulators may also be replaced by a pressure regulator, which is controlled by a temperature sensor. In addition, with the help of suitable Connection plates of gas regulators with multiple pressure regulators can be expanded like this is described in DE-OS 27 03 438 mentioned. The switchover module according to the The invention can be used both as a switch for various pressure regulators and as a solenoid switch-on valve are used to start up the gas control device and also for connection different condition sensors can be used.

In the exemplary embodiments according to FIGS. 3 and 4, the electromagnetic Drive constructed in such a way that the cast resin block 65, the magnet 64 and the coil 63 encloses, while the armature 61 with the help of the spring plate 60 on the approach 122 of the housing chamber 107 is attached. The arrangement can be developed in the Invention also be made so that the armature 61 is also with the cast resin block 65 is attached, for example with the help of a similar ensuring its mobility Spring plate or a tilting bearing. In this case the entire electromagnetic Drive including armature exchangeable on the upper edge 5 of the housing chamber 107 attachable.

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Claims (10)

Pneumatic module, especially for servo-controlled gas regulators Claims: Module designed as a switching valve, especially for servo-controlled ones Gas regulators with a housing chamber that is open to the outside and can be sealed off on one side; three connections opening into the housing chamber, two of which are designed as valve seats are; a closing body that can be tilted about an axis fixed to the housing and which has two with each one of the valve seats cooperating closing body carries; one the closing body carrier in the one switching position biasing spring; and one counteracting the spring force Drive device for the steel body carrier c h n e t that on the open side of the housing chamber (7,107) optionally an electromagnetic (65) or a mechanical (6) drive for the closure element carrier (18,118) is sealed can be placed and in the housing chamber or on the side of the sealing it Drive a receptacle (22, 122) for the optional attachment of one of the electromagnets (63,64) movable armature (61) or one of the movement of the mechanical drive (6) on the closing body (18) transmitting snap spring (24) is provided. 2. Module according to claim 1, d a d u r c h g e k e n n -z e i c h n e t that the receptacle in the housing chamber (7,107) is designed as a shoulder (22,122) and mounting holes for optionally mounting one of the anchor (61) the Spring plate (60) or one as a support and end stop for the snap spring (24) has serving bracket (23). 3. Module according to claim 1 or 2 with electromagnetic m drive d u r c h e k e n n n z e i c h n e t that on the open side of the housing chamber (107) one surrounding the excitation coil (63) and the magnetic core (64) of the electromagnet, Cast resin block (65) can be attached, from which electrical connections X66) for the Take out the bobbin (63) 4. Building block according to claim 1 or 2 with a mechanical drive D u r c h e k e k e n n n e i c h n e t that the on the open side of the housing chamber (7) attached drive (6) via a capillary tube (32) to a temperature sensor (33) connected membrane capsule (29) contains. 5. Building block according to claim 4, d a d u r c h g e k e n n -z e i c h n e t that the support point fixed to the housing (31) of the membrane capsule (29) against the Can be adjusted by force of a spring (30). 6. Building block according to claim 4 or 5, d a d u r c h g e -k e n n z e i c h n e t that on the drive (6) that can be placed on the housing chamber (7) Transmission lever (35) is mounted pivotably about an axis, on the one hand a pin (34) acted upon by the membrane of the membrane capsule (29) engages and which, on the other hand, acts on the snap spring (24). 7. Building block according to claim 6, d a d u r c h g e k e n n -z e i c h n e t that on the transmission lever (35) one of the force transmission to the snap spring (24) serving leaf spring (54) is attached. 8. Building block according to claim 6 or 7, d a d u r c h g e -k e n n z e i c h n e t that as an actuator for the snap spring (24) on the side leg (26) the Schappfeder acting bridge-like actuator (27) in the housing fixed Guide rails (53) is displaceable. 9. Building block according to one of claims 1-6, d a d u r c h g e k e n n z e i c h n e t that the base body (1,101) of the module next to the housing chamber (7,107) a circular recess (9) for the sealed attachment of a diaphragm pressure regulator (4) and the opposite bottom surface of the base body with gas line grooves (12,16) is provided, which on the one hand the output of the pressure regulator (4) with the a valve seat (36) of the switching valve (19, 36; 20,37) and on the other hand the input of the pressure regulator with the housing chamber connection of the switching valve. 10. Building block according to claim 9, d a d u r c h g e k e n n z e i c h n e t that the base body (1, i07) is essentially cuboidal shape with a continuous Has bottom surface (2), while the top is stepped in height, where Qer the lower part (3) the pressure regulator (4) and the higher part (5) the drive (6,65).