HU212142B - Burning safer with thermocouple - Google Patents

Abstract

FIELD OF THE INVENTION The present invention relates to a non-delayed thermoelement burner for hydrocarbon burners having a solenoid valve closure / i connected to a thermocouple / i. auxiliary power supply, a timer circuit connected to it, switching / non-actuator buttons / rotary knobs. It is characteristic that the starter input (52) of the timer circuit (5) is connected to a push-button (54) and / or a push-button (14) of the locking device (1), while the output (53) of the timing circuit (5) is a switching element (6). ) to the actuator input (61), the output of the switching element (6) (64) preferably via a symmetrical backpressure / cause (R) to the outlet / outlet (21) of the thermocouple (2), and the output (s) (21) to the closure device (s). (1) is connected to the input / output (121) of the solenoid coil (s). EN 212 142 B Description scope: 8 pages (including 3 sheets)

Description

The present invention relates to a non-delayed thermocouple burner for hydrocarbon burners.

Due to the stricter safety regulations, only gas-fired appliances equipped with a flame retardant have recently been placed on the market.

A detailed description of the known solutions can be found in Dr. Meszléry Celesztin's "Gas Technology Exemplar" (Technical Publisher, Budapest, 1978). 107-109 of his work. pages.

One very scary solution is the thermoelectric combustion fuse.

According to the cited literature, term In a thermoelectric ignition fuse, the generated thermoelectric voltage opens an electromagnetic valve.

Pressing the button causes gas to flow into the ignition line and ignite the ignition flame.

The ignition flame heats the thermocouple system, which causes current to develop and the electromagnet pulls the magnet plate attached to the valve, opening the gas flow path. ... If the thermocouple is installed correctly, modern structures have an opening time of 3-6 seconds and a closing time of 35-50 seconds ... ".

The reference cited refers to "ignition fuse and" gas "mode, but of course the solution is suitable for systems without a flame, e.g. including domestic gas stoves and other hydrocarbon burning appliances.

In conventional systems, due to the low power gained by the thermocouple, the solenoid valve is opened, retracted, pressed by a rotary knob or by a single push button, the thermocouple only provides "hold".

In practice, the lifetime of a thermocouple, depending on its quality, current state and position of adjustment, is generally more than 20 seconds in the literature.

During this time, the magnet must be held in the "retracted" position by pressing the pushbutton or the rotary knob.

A solution for higher value equipment is described, inter alia, in Patent Application HU 181 266, entitled "Adjustable Selective Vapor Detector Operating Equipment for Ignition and Flaming of Gas and Oil Combustion Devices".

However, this solution is simple for simple equipment, e.g. household gas cookers for several reasons, eg. because of cost level, not applicable.

Our goal is to provide a thermocouple burner fuse that is immediately or with a minimum delay of 0.5 to 1 second after starting the burner. "Holds the solenoid's opening solenoid, but if the thermocouple does not take over the solenoid within the safely allowed time, the magnet will drop and the solenoid will close.

The present invention is based on the discovery that by using an auxiliary power source and some electronic elements, the voltage and current provided by the appropriate switching arrangement thereof can hold the magnet until the thermocouple revives, but only for a period not exceeding the safety time. open.

In the solution we propose, during the thermocouple recovery period, the solenoid valve is open during auxiliary power supply, which supplies power to the solenoid valve after pressing the rotary knob, but the safety time allowed is 20-25 seconds. at the end of the day it will disconnect the power supply.

For safety reasons, the auxiliary power source supplies only the amount of voltage or current required to hold the manually closed - "retracted" magnet.

The auxiliary power source is connected to the solenoid actuator input parallel to the thermocouple.

Accordingly, the present invention provides a non-delayed thermocouple burner for hydrocarbon burners having a solenoid valve closure (s), a thermocouple (s) attached thereto, an auxiliary power source, a timing circuit, a switching element (s) and actuator buttons.

It is characterized in that the starter input of the timing circuit is connected to a pushbutton and / or a pushbutton of the locking mechanism, while the output of the timing circuit is connected to the actuator input of the switching element is connected to the inlet (s) of the solenoid (s) of the locking device (s).

A preferred embodiment is:

- timing circuit integrated timing circuit used as a monostable multivibrator,

- timer circuit with inverter and transistor timer.

BRIEF DESCRIPTION OF THE DRAWINGS In the following, the invention will be described in more detail with reference to an exemplary embodiment.

Figure 1 is a block diagram of a conceptual design of a non-delayed thermocouple burner according to the invention,

Fig. 2 is an example of a non-delayed thermocouple burner according to the invention. a schematic diagram of an embodiment,

Fig. 3 is a schematic circuit diagram of another timing circuit of a non-delayed thermocouple burner according to the present invention.

Figure 1 is a block diagram of a conceptual design of a non-delayed thermocouple burner according to the invention.

The non-delayed thermocouple burner according to the invention has an auxiliary power source 4, a timing circuit 5, a switching element 6, a push button 14 and / or a push button 54 and preferably has a symmetrical resistor R.

Further elements of the figure are: the locking device 1, the thermocouple 2, the burner 3 and the ignition circuit 7.

The locking device 1 is formed of a pin 11, a solenoid valve 12 and a rotary knob 13).

Actuator output 41 of auxiliary power source 4 to input 51 of timer circuit 5, power output 42 of terminal 4

EN 212 142 Β is connected to the 62 inputs of the battery. The auxiliary power source 4 may have its own built-in power source, e.g. battery, or it can be network-powered. In this case, the connection is provided by the inputs 43 and 43 '.

The trigger input 52 of the timing circuit 5 is connected to a separate push button 54 and / or to a push button 14 actuated by the rotary button 13, and its output 53 is connected to the actuator input 61 of the switching element 6.

The outputs of the switching element 6, which may be electromechanical relay or electronic without mechanical structure, are connected to the input of the solenoid coil M of the solenoid valve 12, if the structure also includes an ignition circuit 7, to that input.

In the embodiment shown, the output 63 of the switching element 6 is connected to the inlet 122 of the solenoid winding M of the solenoid 12, the output 64 of which is connected to the input 121 of the solenoid circuit R and the output 65 is connected to the input 71 of the ignition circuit.

The output 72 of the ignition circuit 7 is connected to a properly formed burner assembly 3 not shown in the drawings.

The output 21 of the thermocouple 2 is connected to the inlet 121 of the solenoid coil M of the solenoid 12, and the output 22 is connected to the inlet 122.

In practice, the thermocouple 2 generally has only one power outlet and the other pole is connected to the body.

In this case, the output 22, the output 63 and the input 122 are connected via a ground, so that the switching element 6 has only two switched outputs.

In the case where the device does not have an electronic ignition unit, the switching element 6 has only one output.

An important element of the preferred non-delayed thermocouple burner according to the invention is the symmetrical resistor R.

When operating a device with multiple burners with a single burner fuse, the use of a symmetrical resistor is not only expedient but necessary.

In these cases, e.g. for gas stoves, the most common area of use, multiple burners and correspondingly more thermocouples are connected to a single circuit. The thermocouples are connected in parallel to the respective output of the coupling.

In this case, the solenoid coils of the solenoid valves are also connected in parallel.

The resistance of the thermocouples and the solenoid coils of the solenoid valves are usually a few hundred ohms. Differences in resistance due to manufacturing variation due to parallel connection would significantly affect the uniform current distribution, which would cause malfunctions.

Another problem is that due to the parallel connection, one thermocouple would have an undesirable effect on several - each - solenoids.

The use of a sufficiently high symmetrical resistor is not necessary but is advantageous.

An inlet V and an outlet V 'are connected to the closure 1.

The output line V 'is connected to the burner 3.

The non-delayed thermocouple burner of the present invention operates as follows.

When describing the operation, it is assumed that the auxiliary power source 4 is operational and the hydrocarbon at a suitable pressure is present in the V line. By pressing the rotary knob 13 and the push button 54, the timing circuit 5 receives a start signal and provides a voltage voltage at the outputs of the switching element for a predetermined period of time.

In the absence of a separate push button 54, the timing circuit 5 receives a trigger pulse from the push button 14 actuated by a mechanical connection to the rotary knob 13.

By pressing the rotary knob 13, the solenoid valve 12 opens as described above and remains open due to the voltage at its input 121.

By turning the rotary knob 13, the tap 11 opens, the hydrocarbon enters the V 'line and the burner 3.

If the device has 7 ignition circuits, the ignition starts automatically, if not, manual ignition is required.

After the time allowed by the timing circuit 5, the outputs of the switching element 6 are de-energized.

If the recovery time of the thermocouple 2 is less than the time allowed by the timing circuit 5, then the current required to keep the solenoid valve 12 open is provided by the output 21 of the thermocouple 2.

Figure 2 is a schematic diagram of an exemplary embodiment of a non-delayed thermocouple burner according to the invention.

The exemplary embodiment is designed to provide four burners.

Only circuits of the invention are shown in the figure.

The dashed circuit elements illustrate an exemplary embodiment of an inventive circuit.

In the exemplary embodiment, the non-delayed thermocouple auxiliary power source 4 is formed by a transformer Tr, a rectifier diode D1, D2 and a capacitor C.

The inputs 43 and 43 'are connected to mains voltage via fuses B1, B2.

The actuator output 41 of the auxiliary power source 4 is connected to the input 51 of the timing circuit 5, a power input.

The output 53 of the timing circuit 5 is connected to the actuator input 61 of the switching element 6.

In the exemplary embodiment of the timing circuit 5, a timer with a 5 'integrated circuit used as a monostable multivibrator, a timer for adjusting the required duration, the delay time, is given by the formula T = R 1 x C, where R 1 | is the timing resistor, C is the timing capacitor.

HU 212 142 B

With the setting resistor R _2, the amplitude of the start signal can be determined, while the chiller capacitor is CH.

The reset (reset) of the timing circuit 5 can be accomplished via the inlet 4 'and the reset via the inlet 2'. The output of the timing circuit 5 is the output 3 ', which displays the two logic state signal levels.

A logical level for a time corresponding to the set time T activates the switching element 6 via its actuator input 61.

The switching element 6 is a two-contact relay.

The input 66 of the switching element 6 is connected to the output 44 'of the auxiliary power source 4.

The output 64 of the switching element 6 is connected to the common 12Γ node of the parallel-connected symmetrical resistors R.

The other end of the symmetrical resistor R is connected to the 121 inputs of the associated solenoid M.

Four symmetrical resistors R are fitted according to the four burners.

The exemplary embodiment also includes 7 ignition circuits.

The output 65 of the switching element 6 is connected to the input 71 of the ignition circuit 7.

The input 73 of the ignition circuit 7 is connected to the output 44 of the auxiliary power source 4 and the outputs 72 of which are connected to the respective points of the ignition devices.

Another embodiment of the timing circuit 5 is a timer implemented with the inverters and transistors of FIG.

In this case, the timing is given by the formula T = C ₂ x R ₃ . where C2 is the timing capacitor and R _{3 is} the timing resistor.

The I, inverter and I ₂ inverter circuits are preferably constructed from Schmitt trigger input inverters of an integrated circuit.

The transistor Tr, with a base divider resistor Rbl, Rb2 connected to it, performs current amplification tasks.

By default, the timer C ₂ capacitor is uncharged, the transistor Tr is closed.

54, the trigger button 52 turned earth input ( "0" level) starts, via the diode D at the output of the A] inverter being loaded "H" level of the timing capacitor _C2.

The "H" level causes the transistor Tr to open through the I ₂ inverter and supplies the "H" level to the 53 outputs.

Through adjustment of the timer resistor _R4 after the push button 54 is released, the input of inverter Ij is "H" level, the output of the "0" level.

Diode D in the closing direction does not allow this level to be applied to the timer capacitor C ₂ . The discharge of the capacitor C _{2 at} the resistor R ₃ begins.

This voltage at the input of the inverter I ₂ reaches the tilt limit, inverting the inverter I ₂ , closing the transistor Tr, resulting in a level "0" at the output 53.

The circuit arrangement shown in the figure is very simple, so that the preceding figures 2 and 3 can be interpreted without further explanation on the basis of a more detailed explanation, its operation does not require special explanation.

It is also possible to have an embodiment where the system start button (s) are connected in front of the auxiliary power source input. In this case, the system is disconnected from power when not in use.

Claims (3)

PATENT CLAIMS 1. Non-delayed thermocouple combustion protector for hydrocarbon burners having a solenoid valve shutter (s), a thermocouple (s) attached thereto, an auxiliary power source (4), a connected timing circuit (5), a switching element (e) (6) and actuating buttons characterized in that the trigger input (52) of the timing circuit (5) is connected to a push button (54) and / or a push button (14) of the locking device (1), while the output (53) of the timing circuit (5) at the inlet (61), the outlet (64) of the switching element (6) is preferably via the balancing back pressure (s) to the outlet (21) of the thermocouple (s) (2) and said outlet (s) (21) ) is connected to the input (s) (121) of its magnetic coil (s). (Priority: December 15, 1993) The burner safety device according to claim 1, characterized in that the timing circuit (5) is a time switch used as a monostable multivibrator implemented by an integrated circuit (5 '). (Priority: December 15, 1993) Burner fuse according to claim 1, characterized in that the timing circuit (5) is a time switch implemented by inverters (I, I ₂ ) and a transistor.