DE2759358C2 - Device for controlling the control valve for the gas flow for firing a heating boiler or a hot water device - Google Patents

Description

The invention relates generically to a device for controlling the control valve for the Gas supply for firing a heating boiler or a hot water device with a temperature error signal supplying thermostatic element for actuating the valve.

In a known generic device (DE-OS 17 51 431) is a rotatable adjusting knob with a cam arranged thereon is provided. A certain heating power can be set via this, to which a defined flow rate is assigned. With the set heating power, the flow rate reduced, the thermostatic element leads to an adjustment of the closure member between the opening and closed position. By oscillating the closure member between the open and closed position brought about a reduction in heating power. But that also mostly has annoying temperature fluctuations when drawing off service water. If the flow rate is increased, the desired The temperature cannot be reached due to the set heat output.

The invention is based on the object of developing a device of the generic type in such a way that the gas flow is steady according to the respective requirements, and not as in the case of the one described above Device can be regulated by only two switching positions of the valve closure member.

To solve this problem, the invention teaches that an eddy current coupling is provided, its receiving element is constantly driven by a motor and its braked by a return spring Output element is connected to the control valve via a cam, the output torque the eddy current coupling is controlled by the error signal generated by the thermostatic F.lcmcnt. - Further advantageous basic and advanced training courses are shown in claims 2 to 10.

The advantages achieved are primarily to be seen in the fact that the device according to the invention is guaranteed is. that for a once set temperature a getuuie regardless of the respective flow rate The assigned heating output is set.

In the following the invention is based on a few Exemplary embodiments illustrated drawing explained in more detail; it shows

Fig. 1 is a section through a device for Control of the regulating valve for a Heizkcssclfcucrung along the in F i g. 2 drawn cutting line;

2 the device from FIG. 1 seen from above on a reduced scale;

FIG. 3 shows a diagram of the generator of the eddy currents when training with a conductive bell;

4 shows the arrangement of a pair of control levers in schematic representation;

F i g. 5 is a plan view of the support plates of the reduction gear. for return actuation of the cam and the bell for the eddy currents;

6 shows an operating diagram of one with one according to the invention Furnishing equipped boiler control;

FIG. 7 shows a section corresponding to FIG. 1 by a modified embodiment of a device;

F i g. 8 shows a variant of the control lever actuation in a perspective illustration; and

9 shows a section through the drive device of the magnet, which with the arrangement according to FIG. 8 is coupled, on a different scale.

As Fig. 1 shows, the device has a base plate 1, which is suitably reinforced by ribs and in which by raised edges edged openings 2 are formed. With this plate, two covers 3 are elastic or plastic Seals liquid- and / or gas-tight connected, which on the top or the bottom of this Lay the base plate 1 firmly. In the illustrated embodiment the top lid has two smaller lids that can be removed to to achieve free access to two facilities arranged under these partial covers.

A first part 3a of the lower cover forms a connection for the feed line and surrounds the corresponding opening 2a in the base plate I and covers two subsequent openings 2b and 2c . A part 3 £> of the upper cover, which contains a head part of a thermal fuse element, a magnetic fuse and an ignition system 4 for the pilot flame, covers the exit of the opening 2a and the entrance to the opening 2b, with a seat 5 for a double valve in lctzcrem is inserted with a toric seal. The plunger 6 for igniting the pilot flame protrudes from this first cover into part 3a of the lower cover.

A cover part 3c of the upper cover, which forms a housing for a classic gas flow regulator 7, covers the opening 2c through the base plate 1 and an adjacent opening 2d from above. Under this last opening, a part 3d of the lower cover is arranged, which encloses the mechanical actuation of the inflow control 8 to be described, this cover part covering the opening 2d and a valve seat 2c connected to it. This cover part 3d also covers with an approach a separate chamber; ib, which reveals a membrane 9, a corresponding seat 10 as a raised opening and an outlet 11 for the heating gas for the furnace to be fed.

On the top of the base plate I, the valve seat 2e is covered by a cover 3c, which forms the valve housing for regulating the inflow. Ils here is a double valve having an outer spherical valve body 14 which cooperates with a corresponding valve seat 2e and thereby in turn inside a seat for the conical part 15 a ^r Brennstoffnade! to regulate the lower inflow. The support rod 16 for this fuel needle 15 is made thicker below this needle and is acted upon by a corresponding spring in the seat direction. It slides in the spherical valve body 14 and carries an attachment which is arranged at a certain distance from the support attachment for the fuel needle 15 and from the valve body itself in order to be able to lift this valve body 14. The valve body 14 is urged in the direction of the closed position by a special spring.

At its end protruding into the cover part 3d, the rod 16 has a crosspiece, the ends of which extend over Rolls in parallel on identical curve parts that are symmetrically repeated in relation to the axis drum-shaped cam 17 rest.

Following the cover part 3c, a cover part 3f is formed which covers the seat of the membrane 9 and, in the case of a boiler firing for mixed operation, also a membrane with hydraulic actuation 18, which is actuated when the membrane is opened when domestic water is consumed. This arrangement is used when the gas circuit for heating is to provide a lower heat output than when domestic water is to be heated.
A cover part 3g of the lower cover covers the membrane 9 and its seat and forms a connection to the outlet 11.

This results in a control and distribution circuit, which is shown in FIG. 1 as a section through the axis A of the inlet connection, the axis B of the thermal fuse, the axis C of the regulator, the axis of the valve for regulating the gas / flow and the axis E of the outlet port (FIG. 2), the actual control devices not needing to be described here.

F i g. 1 also shows, in a section through the lower cover along the line FG from FIG. 2, a control device in the lower extension of the lower cover part 3Λ. This cover part is enclosed by means of compensating springs 20a. 21a on connecting rods 20, 21 of two support plates 22, 23 of a reduction gear 24 (see also FIG. 5), an eddy current coupling 25 with a motor 26, a magnet 27 as a receiving element and a field closure member 28 is displaceably arranged. Between this magnet 27 and this field closing element 28, the edge of a very conductive bell 29 dips as an output element, which forms the eddy current coupling when the magnet 27 is rotated. This bell 29 is wedged on the axis 29a of an input pinion of the reduction gear 24, one intermediate shaft 17a of which carries the cam disk 17 and the output shaft 30 (FIG. 5) of which carries a wheel which is attached to the end hook of a return spring 31 through an opening. The base is designed in such a way that the displacement of the hooking point of the return spring 31 is very small and runs in the direction of an extension of the lever arm when the return spring is excluded in order to compensate the return torque of the cam disk 17 and the bell 29 constant / hold u.

The eddy current coupling 25 rests on a linden tree of two I lcbel 32, 3X . Each lever 32, 33 lies with its other linden tree on a cutting edge 34

which it is pivotable with respect to a stationary holder 35, and on a cutting edge 36 which forms the outermost end of the piston rod of a cylinder piston arrangement 38 which can be axially displaced in a stationary holder 39 (sliding surface in the wall of the cover part 3h). The cylinder piston arrangement 38 is connected via a capillary tube to a thermometric ball 40, which is influenced by the temperature of a heated liquid, which can be service water or heating water. The cylinder rests on a control device, not shown, which has a cam for lifting the lever, which is, for example, firmly connected to the axis of an indicator button. The temperature which the ball 40 thermostatically maintains via the blade 36 of the lever by regulating the height of the lever 32 or 33, i.e. the height of the eddy current coupling 25, and thus the immersion of the bell 29, can be read off this display button for the eddy currents in the air gap. Since the motor 26 runs at constant speed, the mechanical torque on the bell 29 has a value which is correlated with the depth of immersion in the air gap and in a clear relationship with the position given to the cam disk 17 under the action of the return spring 31 the position of the fuel needle J5 for the low inflow is initially fixed when the tappet of the valve rod is behind a starting area 15a of the cam and suddenly opens the passage to the pilot flame through the position before this starting area, and vice versa.

You can see that it is always the one of the two Lever 32 or 33 carries the eddy current coupling 25, which under the influence of the measured by the ball 40 lowest temperature, which is the only control temperature.

Of course, the organ forming the eddy current coupling can also have the shape of a disk, which is arranged at a variable distance from a magnet 27, the mobility not from the movement of the eddy current coupling 25 in the bell, but from the controlled sliding movement can result on its axis 29a.

With measures of this kind, the following with reference to FIGS. 6 achieve results to be explained. 6 shows a diagram which shows the time T as abscissa values and the temperature r- of the service water as positive ordinate values, for example, and the eddy current coupling could also have other actuation arrangements for a bell as described above, and in particular those for changing the air gap through the mobility of the field closure member, wherein the bell and the magnet are axially fixed and this field closure member 28 is movable, either in the axial or in the radial direction, it is then divided into several segments and the mobility of this field closure member 28 then

ίο is given by an amplifier device, which has several levers according to the principle described above.

The eddy current coupling could just as well have the shape of a disk 29 instead of a bell 24, which is inserted between a magnet 27 and a field closure member 28, the controller by changing the air gap either as a result of an axial movement of the magnet 27 or of the field closure member 28 with respect to the disc 29 or both parts can take place at the same time.

The F i g. 7 to 9 show design modifications, the same reference numerals as in FIGS. 1 to 6 being used for the same parts. The formation of the integrated circuit shown in FIG. 7 corresponds to the front area or at the entrance of the FIG. 1. One difference is behind the Gaszuflußregler 7, takes place from which the gas outlet through an opening 2d \ which without passing through the base plate 1 a results in a direct connection to the space in which the control valve 14, 15 and the corresponding return springs are arranged.

The gas flows from the side of the base plate 1 on which this control valve 14, 15 is located, through the from Valve seat 2e surrounded breakthrough to the other side in a space 50 in which the actuating rod 16a is located. The latter is tightly connected to a flexible membrane 52 through this membrane through which closes the space 50 and isolates it from a space Si in the lower cover 3, which encloses the mechanism of the servomotor. The downward protruding from the membrane 52 end of the Operating rod 16a is supported on the end of a correspondingly designed operating lever 53, which forms the output organ of the actuating or regulating device.

An opening 54 in the base plate 1 connects the space 50 with the upper cover part 3f, which covers the seat of a diaphragm valve and a connection

λ W ppp "3tiyp Or ^ in ^ enw ^ fte dl * ³ A u ^ troTim ^ n ^ ** c! * ³ ^ 55 ^; · π dl ** manifold ^ to the burner.

taken water d shows as a result of the movements of the valve body 14, which are caused by the cam disk 17 and thus by the changed immersion depth of the bell 29 in its air gap, the motor 26 rotating constantly. The short temperature fluctuations O \ and Oi of the curve te correspond to the course of the curve S representing the water withdrawal. This water temperature is during the fluctuations in the outflow quantity in the water withdrawal curve S, as the curve t _c shows, on one except for the short fluctuations O \ and Ch necessarily kept constant value.

These arrangements can be used just as well for simple heating systems as for heating systems in mixed operation, in which, for example, the heating of domestic hot water has priority over space heating Has. and they can also be used in heating systems with line control that has not yet switched on the heating when hot water is requested.

The membrane 52 does not interfere with the actuation of the control valve 14.15 and isolates the space of the device the actual integrated circuit from the outside air. As the F i g. 8 and 9 show the stator of the motor is seated 26 slidable on rod guides, which have a base flange 56 with a support plate 23 of the reduction gear associate. The lower flange 57 of the stator rests on flanges 58 outside this guide two tubes 59 closed on the other side, in which the springs 206 and 216 are arranged, which are supported with their upper end on the bottom of the tubes and with their other end on tips 60 of flange 56.

If necessary, an intermediate centering capsule can be provided. That way results

ds an absolutely reliable elastic return force for the motor-magnet group 26, 27 with great accuracy and high sensitivity.
As in particular F i g. 8 shows the flange 57

connected to the legs of a fork rocker 62 by two tension rods 61. This fork swing arm is by means of an axis 63 on a shoulder of the flange 23 forming the support plate of the reduction gear 24 hinged. >

Near the point of application of a pull rod on the leg of the fork rocker 62 is the nose of one Control lever 32a or 33a, which is on a fixed cutting edge 34a and a movable control cutting edge 36a is held, the latter by a measuring probe io 38a of the same training as described above is operated. The arrangement of the levers 32a and 33a next to one another prevents them from being constrained too much and plenty of space for the Tragelementc and the corresponding actuating elements remains, while 15 at the same time too great a height is avoided.

For this purpose 4 sheets of drawings

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Claims (10)

Patent claims: 1. Device for controlling the regulating valve for the gas flow for firing a heating boiler or a hot water device with a thermostatic element providing a temperature error signal for actuating the valve, characterized in that it has an eddy current coupling (25), the receiving element (27) is constantly driven by a motor (26) and its output element (29) with the control valve (14, 15) braked by a return spring (31) a cam (17) is connected, the output torque of the eddy current coupling (25) controlled by the error signal generated by the thermostatic element. 2. Device according to claim!, Characterized in that the thermostatic element controls the output torque of the eddy current coupling (25) by changing the air gap thereof. 3. Device according to claim 2, characterized in that the receiving element is an axially fixed Magnet (27) and the output element is an electrically conductive disc (29), which in one limited by the magnet (27) and a field closure plate (28) arranged parallel to the output organ Air gap lies, the air gap from the thermostatic element by common axial displacement the disc (29) and the field closure plate (28) can be changed. 4. Device according to claim 2, characterized in that the output element has a one the The receiving element forming, axially fixed magnet (27) surrounding the bell (29) and this is surrounded coaxially by a field closure member (28) which consists of an at least two-part ring, the two parts of which are movable towards or away from one another, the air gap between these two ring parts from the thermostatic element by moving these two Parts is changeable. 5. Device according to claim 1, characterized in that that the eddy current coupling (25) has an unchangeable air gap and its output moment can thereby be controlled by the thermostatic element. that this thermostatic element is connected to the motor (26) driving the receiving element (27) in such a way that the motor speed is changeable by the thermostatic element. 6. Device according to claim 1, characterized in that the receiving element is an axially fixed Magnet (27) and the output element is a bell (29) enveloping this magnet, which under the action of the thermostatic element to a variable extent in the unchangeable Air gap of the eddy current coupling (25) can be immersed. 7. Device according to claim 1, characterized in that the eddy current coupling ring (25) is an axially fixed output element (29). a receiving element connected to the motor (26) in a rotationally fixed manner (27) and a field closing element (28) and that the motor with μ through the thermostatic element the receiving element as well as the connecting element with respect to the alisgang element overall axially is movable. 8. Device according to one of claims 1 to 7, characterized in that the thermostatic Element includes as many thermostatic actuation arrangements for the vortex tube coupling (25), how to control temperatures. 9. Device according to claim 4 for the mixed operation of a central heating and a hot water supply, characterized in that the eddy current coupling (25) solely by that of the lowest Temperature corresponding thermostatic element can be actuated, so that the hot water supply is preferred to operate. 10. Device according to one of claims 1 to 9, characterized in that the control valve (14,15) as a double valve! with a valve (14) for strong Flow and a valve (15) is designed for low flow and that the cam track the cam disc (17) has a starting area (15a,} with a variable pitch through which the Low flow valve (15) can be actuated suddenly.