DE2306544A1 - SHUT-OFF CONTROL FOR GAS HEATING POINTS - Google Patents

Description

Ga / egg.

DIBHL, 85 Nuremberg, Stephanstrasse 49

Shutdown control for gas heating stations

The invention relates to a shutdown control for gas heating stations connected to an alternating current network Cooking appliance with a switch for an electrical device, the gas heating points each by means of a Thermocouple are secured, which is connected to the AC mains connected winding of a gas valve holding open electromagnet is energized.

It is known in such shutdown controls to open the gas valve of the gas heating point in that the winding of the magnet is energized against the current direction of the thermocouple via the transformer. To keep this connection to the transformer as short as possible, it 1st known to provide to program switching mechanisms of cooking appliances additional contacts that are turned on in the primary or the secondary of the transformer and the close only briefly. The disadvantage of this known cut-off control is that special program control units must be provided for gas cut-off and that the known program control units provided for electrical appliances cannot therefore also be used for gas-fed cooking appliances. Another

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ORIGINAL UiS

laugh of the known circuits is that itself in the case of an additionally provided contact that closes only briefly - the winding of the magnet the current flows through it longer than is actually necessary to switch off the magnet or the gas valve is" " " " .

The object of the invention is to develop an additional circuit which, on the one hand, derives the pulse required for gas shutdown from the switching function customary in AC switches, namely "permanent opening" and, on the other hand, uses this pulse to switch the devices known for gas shutdown without the need for an electric heater provided program switching mechanism must have additional contacts, the separate operation of electric and gas heating points in a combined cooking device should not be hindered.

According to the invention, this object is achieved in that a -diirch \ controlled a rectifying semiconductor circuit Charging circuit is provided with a capacitor and that when the switch is opened, the capacitor via the Semiconductor circuit charges and by means of this charge the winding of the electromagnet briefly against the Current direction of the thermocouple is energized. This circuit enables the gas heating points to be switched off accomplish by means of program switchgear used for electric heaters. On the one hand, this circuit can be Use in cooking appliances that have both gas and Electric heating points are provided. On the other hand, the circuit also enables the use of for Electric cooking appliances provided program switchgear for gas cooking appliances.

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In an advantageous embodiment of the invention, there are additional switches for separate commissioning of the Gas heating points and any electrical heating points that may be provided.

In an advantageous embodiment of the invention, the semiconductor circuit is a rectifier, in particular a bridge rectifier, formed, at the output of which the charging circuit is connected, whereby through the charging current of the capacitor via a relay winding a relay contact is briefly closed. It is advantageously the rectifier via a switch, which is in particular from a contact of a program switching mechanism is formed, can be short-circuited.

Another advantageous embodiment that works without the relay described in the above embodiment is characterized in that the semiconductor circuit consists of a controllable semiconductor element and a diode is formed and that the capacitor between the control input of the controllable semiconductor element and the diode lies. The controllable semiconductor element is preferably a thyristor. Such a circuit is preferred in the Secondary circuit of the transformer switched on, since cheap semiconductor components can be used here. In this case, the semiconductor circuit can preferably be switched off in that the diode and the controllable semiconductor element lie on one pole of the alternating voltage and the capacitor and the diode via a switch to the other pole of the alternating voltage can be connected.

One advantage of this circuit is that the winding of the magnet is only influenced by the pulses pursued the necessary polarity. This ensures that the winding does not exceed the permissible level addition is heated.

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In a preferred embodiment of the last described Embodiment, the capacitor is dimensioned so that it is at the half-wave of the alternating voltage, which lets the diode through, charges in a staircase. This makes it possible on the one hand to use a capacitor with a small To use capacitance value, and on the other hand is achieved by the fact that on the winding of the holding magnet several Switch-off pulses are emitted. This ensures that the switch-off takes place at least with a later pulse, if for some reason it was not done on the first impulse.

Further advantageous features of the invention emerge from the following description of the drawings and the subclaims. Show it:

Fig. 1 shows an embodiment of the invention,
FIG. 2 shows a further exemplary embodiment of the invention and FIG. 3 shows the voltage profile on the thyristor and on the capacitor according to FIG. 2.

A thermocouple 1 of a gas heating point of a cooking appliance lies parallel to a winding 2 of an electromagnet to which a gas valve 3 of the gas heating point is assigned.
A secondary winding 4 of a transformer 5, the primary winding of which is denoted by 6, is connected in parallel with winding 2. The primary winding 6 is over one or
several switches at poles 7 and 8 of an alternating current network.

In FIG. 1, in a parallel branch to the primary winding 6, there is a bridge rectifier 9 connected to the direct current output
this rectifier 9, a capacitor 10 is connected. With this is the field winding 11 of a relay

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in series. A relay contact 12 of this relay is in series with the primary winding 6. A discharge resistor 13 is connected in parallel with the capacitor 10. The resistance of this resistor 13 is 10-10 ⁵ greater than that of the excitation winding 11. A switch 14, with which the rectifier 9 can be bridged, is located parallel to the alternating current inputs of the rectifier 9. A resistor 15 is connected upstream of the switch 14 and the rectifier to limit the current.

The cooking appliance has electrical devices that are not shown in detail. It can be electric heating Act. These electrical devices are connected to pole 16.

A switch 17 is connected upstream of the pole 16. Preferred water serve as switch 14 and switch 17 contacts of a known program switching mechanism. Parallel to switch 17 is another switch 18, with which the connected to the pole 16 electrical device independent of the Switching position of the switch 17 can be put into operation. Between the pole 7 and the rectifier 9 lies a switch 19 »which is closed when the gas heating stations are in operation is.

The mode of operation of the described arrangement according to FIG. 1 is as follows:

When operating the electric and gas heating stations at the same time Switches 14 and 17 are closed via the program switching mechanism, switch 19 is also closed, Switch 18 is open. The thermocouple 1 is warm, so that the coil 2 of the electromagnet opens the gas valve 3 keeps open. The rectifier 9 is short-circuited, the relay contact 12 is open.

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If the switches 14 and 17 are now opened, for example if these contacts of a program switchgear and the program has ended, then switch itself, the electric heating points and the gas heating points off at the same time »A gas heating point is switched off as follows:

When the switch 14 is opened, an alternating voltage is applied to the rectifier, which is processed by the rectifier and charges the capacitor 10. During the charging process, current flows through the excitation winding 11 of the relay, whereby the relay contact 12 is briefly closed. As a result, there is an oil mains voltage on the primary winding 6 of the transformer 5, which induces a voltage in the secondary winding 4. One of the half-waves of the induced alternating voltage cancels the voltage of the thermocouple, so that the winding 2 of the electromagnet is momentarily de-energized. As a result, the gas valve 3 opens and the gas supply to the gas heating point is interrupted.

In FIG. 2 and FIG. 1, the components provided with the same reference symbols correspond. In Figure 2, the inventive shutdown control is in the secondary circuit of the transformer 5. Between the secondary winding 4 and winding 2 of the holding magnet for the gas valve 3, a thyristor 20 is connected. A diode 25 is connected to the input 21 of the thyristor via a resistor 24. The capacitor 10 is located between the control input 23 of the thyristor 20 and the diode 25. The switch 14 is located between the connection point of the diode and capacitor and the pole of the secondary coil 4 facing away from the thyristor The control input 23 and the output 22 of the thyristor 20 are worn, and the discharge resistor 13 is bridged. The positive half-wave occurs at the output 22 in the switched state. The output 22 of the thyristor is at the negative pole of the SaermioeXeiients.

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The circuit described works when you look at your at Figure 1 starts out as follows: the switches 17 and 14 open, l'idt the positive Half-wave of the alternating voltage of the secondary winding the capacitor 10 via the diode 25 and the resistor 13a. (Until the switch 14 was opened, the positive half-wave was derived via this switch). Through the The charging current flowing through the capacitor 10 briefly conducts the thyristor until it passes through the negative Half-wave is blocked again. During the conduction of the thyristor 20 is on the pole of the winding 2 of the magnet, which is connected to the negative pole of the thermocouple, a positive voltage, so that the magnet is de-energized and the gas valve 3 closes. As a result, the gas supply is to the gas heating point assigned to this thermocouple interrupted.

A significant advantage of the arrangement of the shutdown control according to the invention in the secondary circuit of the transformer results from the fact that the voltage in the secondary circuit is significantly lower than in the primary circuit. For example, it is 220 volts in the primary circuit and 6 volts in the secondary circuit. This makes it possible to use semiconductor components that do not have to be designed for high voltages.

It is particularly advantageous to dimension the capacitor in such a way that on the side of the capacitor 10 facing the control input 23 there is a step-shaped voltage curve which is opposite to the opening voltage of the thyristor. This voltage curve is shown in FIG. 3 in the illustration above.

This makes it possible to use a capacitor, whose capacitance value is lower by about 2 powers of ten than that of the capacitor, the one due to the for

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the thyristor required control current of about 20-25 mA and a switching duration > 20 msec would have to use.

The step-shaped charging proceeds as follows: At the beginning of the positive half-cycle, the diode 25 becomes conductive, and the control input becomes due to the charging current of the capacitor 10 of the thyristor positive. From a certain value the thyristor switches through, so that at its output the rest of the positive half-wave lies (see FIG. 3 »lower Representation) Due to the reaction of the output 22 on the control input 23, the latter is also positive, see above that the capacitor can no longer charge. The thyristor and block on the following negative half-cycle the charge on the capacitor is essentially retained. With the next positive half-wave the diode will be again conductive and the capacitor continues to charge. This increases the voltage opposite to the opening voltage of the thyristor Charge the capacitor, so that the thyristor only later becomes the positive Half-wave is conductive. The process already described then starts again. Is after several half waves the capacitor is charged to such an extent that further charging can no longer take place, then the thyristor can Don't become more managerial.

The blocking of the thyristor, which occurs at the end of the charging process, has the overall consequence that the gas heating point is closed can operate even when the switch 14 is open. This is necessary, for example, when the switch 14 is a contact of a program switching mechanism and if the gas heating stations are independent via the switch 19 are to be put into operation by the program control unit.

The exemplary embodiments described here can be modified in various ways. For example, can

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the rectifier circuit of Figure 1 can be provided in the secondary circuit of the transformer 5, or the Relay contact 12 can be placed in the secondary circuit. In the embodiment of Figure 2, the thyristor 20 can through another controllable semiconductor component, for example a transistor, can be replaced. It can be in the If necessary, also switch on the circuit described in FIG. 2 in the primary circuit of the transformer.

In a further refinement of the exemplary embodiment according to FIG. 2, the secondary winding 4 can have additional turns 4 ¹ . The resistor 24 is then on the additional turns 4 ¹ . This increases the voltage across resistor 24. It is therefore possible to use a capacitor 10 with a smaller capacitance value.

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Claims (22)

Patent claims: / iy Shutdown control for gas heating points of a cooking appliance connected to an alternating current network with a switch for an electrical device, the gas heating points each being secured by means of a thermocouple which, when the respective gas heating point is in operation, energizes a winding of a holding magnet that holds a gas valve open, which is connected to the alternating current network via a transformer , characterized in that a charging circuit with a capacitor (10) controlled by a rectifying semiconductor circuit (9; 20, 25) is provided and that when the switch (17, 14) is opened, the capacitor (10) via the semiconductor circuit (; 20 , 25) and by means of this charge the winding (2) of the holding magnet is briefly energized against the current direction of the thermocouple (1). 2. Shutdown control according to claim 1, characterized in that the semiconductor circuit (9, 20, 25) in the The primary circuit of the transformer (6) is switched on. 3. Shutdown control according to claim 1, characterized in that that the semiconductor circuit (9, 20, 25) is switched on in the secondary circuit of the transformer (5). 4. Shutdown control according to one or more of the preceding Claims, characterized in that the semiconductor circuit is formed by a rectifier (9) is, at the output of which the charging circuit (10, 13) is connected, and by the charging current of the capacitor (10) a relay contact (12) is briefly closed via a relay winding (11). . - 11 - 409833/0565 - 5. Shutdown control according to claim 4, characterized in that that the relay contact (12) is in the primary circuit of the transformer (5). 6. Shutdown control according to claim 5, characterized in that the relay winding (11) in series with the capacitor (10) and the relay contact (12) in series with the primary winding (6) of the transformer (5). 7. Shutdown control according to one or more of the preceding claims 4-6, characterized in that the rectifier is a bridge rectifier (9). 8. Shutdown control according to claim 2 and one or more of the preceding claims 4-7, characterized in that that the rectifier circuit (9) is parallel to the primary winding (6) of the transformer (5). 9. Shutdown control according to one or more of the preceding claims, characterized in that the Semiconductor circuit can be short-circuited by a further switch (14). 10. Shutdown control according to claim 9 and one or more of the preceding claims 4-8, characterized in that the AC connections of the rectifier (9) can be short-circuited by the further switch (14). 11. Shutdown control according to one or more of claims 1 - 3 »characterized in that the semiconductor circuit is formed by a controllable semiconductor element (20) and a diode (25) and that the capacitor (10) lies between the control input (23) of the controllable semiconductor element (20) and the diode (25). - 12 - 409833/0 565 12. Shutdown control according to claim 11, characterized in that the diode (25) and the controllable Semiconductor element (20) are connected to one pole of the alternating voltage and the capacitor (10) and the diode (25) can be connected to the other pole of the alternating voltage via a further switch (14). 13. Shutdown control according to claim 12, characterized in that the capacitor (10) is dimensioned so that it is charged in a step-like manner in the case of one half-waves of the alternating voltage and at the control input (23) the potential opposite to the opening voltage is generated. 14. Shutdown control according to claim 3 and one or more of the preceding claims 11-13, characterized in that that the output of the controllable semiconductor element (20) to the winding (2) of the holding magnet is turned on. 15. Shutdown control according to one or more of the preceding claims 11-14, characterized in that the controllable semiconductor element is a thyristor (20). 16. Shutdown control according to one or more of the preceding claims, characterized in that a Discharge resistor (13) provided for the capacitor (10) is. 17. Shutdown control according to claim 16 and one or more of the preceding claims 11-15, characterized in that that a resistor (13a) parallel to the control input (23) and to the output (22) of the controllable Semiconductor element (20) lies. - 13 409833/0565 18. Shutdown control according to one or more of the preceding Claims, characterized in that the switch (17) and the further switch (14) simultaneously be operated. 19. Shutdown control according to claim 18, characterized in that that the switches (14, 17) are contacts of a program switching mechanism. 20. Shutdown control according to one or more of the preceding claims, characterized in that the electrical device has one or more electrical heating points of the cooking appliance. 21. Shutdown control according to one or more of the preceding Claims, characterized in that switches (18, 19) for separate start-up of the gas heating points and the electrical device are provided. 22. Shutdown control according to one or more of the preceding claims 11-21, characterized in that that the diode (25) is at a higher potential than the input (21) of the controllable semiconductor component (20). 409833/0565