TECHNICAL FIELD

The invention relates to a controller card used in burning devices operated with liqu id/gas fuel such as furnaces, central heating boilers, boilers, and burner.

The invention relates particularly to the following elements of the controller card used in burning devices operated with liquid/gas fuel such as furnaces, central heating boilers, boilers, and burner, wherein it is developed to allow the controller card to be operated with 6, 12, 18 volts by using the current obtained any of the energy sources including battery, cell battery, solar panel, and adapter instead of 220 or 380 or 24 volt energy, thereby eliminating the failure of the control card in case of high current variations or power cuts;

- 6 volt power inputs having an energy input, adapter input, and battery input connected to the controller card controlled by the power control card, allowing the controller card to be operated with the 6 volt current value, which allows the unit that provides ignition in the burning device, to be controlled;

12 volt power inputs having an energy input, adapter input, and battery input connected to the controller card controlled by the power control card, allowing the controller card to be operated with the 12 volt current value, which allows the unit that provides ignition in the burning device, to be controlled;

18 volt power inputs having an energy input, adapter input, and battery input connected to the controller card controlled by the power control card, allowing the controller card to be operated with the 18 volt current value, which allows the unit that provides ignition in the burning device, to be controlled;

PRIOR ART Today, burning devices operated with liquid/gas fuel such as ovens, central heating boilers, boilers and burners are used in food cooking facilities or for heating purposes.

The fuel reaching into the combustion section/chamber from the fuel line must be fired in order to operate the burning devices of the specified type of furnace, central heating boiler, boiler, and burner. The mentioned ignition is carried out by means of the electronic ignition systems that cannot be intervened externally.

The electronic ignition system of the burning devices has a controller card, a liquid/gas meter, an installation pressure presostat, a valve, a temperature indicator, a presostat, a lighter igniter, a fire detector, a fan motor, a gas alarm sensor and a fire alarm sensor.

In the operation of the burning device, the gas from the liquid/gas fuel line reaches the combustion section/chamber after the security check via the valve and pressure presostat and the fuel is ignited via the ignition system. After the resulting flame, combustion occurs. After the environment reached to the required temperature, the ignition system automatically cuts off the fuel flow and if the temperature drops, the fuel is combusted again in the combustion section/chamber via the ignition system. This process continues continuously and the operation of the burning device is allowed.

In the state of the art, the ignition systems used in burning devices receive energy directly from the network as 220 or 380 volt. Because the ignition system operates with 220 - 380 volt current obtained from the network line as defined, it does not work in possible power cuts and damages the controller card and the elements used in the ignition system.

In the state of the art, a controller card is developed in order to eliminate the above- mentioned problems and patent application has been made with the invention no. TR 2020 00604, titled as DOGALGAZ, CNG, LPG TIIRIINDEN GAZ YAKITLA QALI§AN GAZ YAKICI CiHAZLARDA KULLANILAN 24 VOLT ENERJiYLE QALI§AN ELEKTRONiK KUMANDA KARTI.

In the summary of the above-mentioned patent application number TR 2020 00604, the statements “An electronic circuit element which is used in the gas burning devices such as stone furnaces with a mobile/stable structure operated with natural gas, eng and Ipg fuel, consists of gas line 2, main valve 3, gas filter 4, burner collector 5, burner valve 6, resilient connection element 7, atmospheric burner 8, flame sensor, pressure presostat, heat probe and auto igniter lighter 1.12, and automatically ignites the oven A; wherein the electronic circuit element is developed to ensure the continuity of the system by working with 24 volt energy, thereby eliminating the effect of the power cuts on the network energy line with 220 volt current, as well as minimizing the possible accident risks by giving a warning about the gas leakage; wherein the invention relates to an electronic controller card 1 which allows any kind of natural gas, eng, Ipg type fuel coming from the gas line 2 and reaching the atmospheric burner 8 to be automatically combusted, therefore provides the operational continuity of the stone furnace, operates with 24 volt current, forms the security check unit via a fire alarm sensor 1 .2 and gas alarm sensor 1.3 and thus eliminates the possible accident risks.” are included. When the summary and content of the above-mentioned patent application number TR 2020 00604 are analyzed, the continuity of the burning device usage is limited to 24 volt in cases of problems arising from the network line, in which the controller card developed for gas burning devices and operated with 24 volt current is within the scope of protection. Limiting the current value to 24 volt, it is seen that all alternative electrical energy sources cannot be used in order to ensure the operational continuity of the burning devices.

As a result due to the problems faced in the state of art and mentioned above, there is a need to make improvements in the related technical field.

OBJECT OF THE INVENTION

Due to the existing problems in the prior art, it is intended to resolve all the problems described.

The object of the invention is to provide a controller card used in burning devices operated with liquid/gas fuel such as furnaces, central heating boilers, boilers, and burner.

Another object of the invention is to provide the following elements of the controller card used in burning devices operated with liquid/gas fuel such as furnaces, central heating boilers, boilers, and burner, wherein it is developed to allow the controller card to be operated with 6, 12, 18 volts by using the current obtained any of the energy sources including battery, cell battery, solar panel, and adapter instead of 220 or 380 or 24 volt energy, thereby eliminating the failure of the control card in case of high current variations or power cuts;

- 6 volt power inputs having an energy input, adapter input, and battery input connected to the controller card controlled by the power control card, allowing the controller card to be operated with the 6 volt current value, which allows the unit that provides ignition in the burning device, to be controlled;

12 volt power inputs having an energy input, adapter input, and battery input connected to the controller card controlled by the power control card, allowing the controller card to be operated with the 12 volt current value, which allows the unit that provides ignition in the burning device, to be controlled;

18 volt power inputs having an energy input, adapter input, and battery input connected to the controller card controlled by the power control card, allowing the controller card to be operated with the 18 volt current value, which allows the unit that provides ignition in the burning device, to be controlled;

By means of the ignition system having a control card with 6, 12, 18 volt power inputs of the invention, it has been ensured that;

- the problems encountered in current variations or current/energy cuts occurred in the network line are eliminated,

- the control card and therefore the ignition system can operate uninterruptedly with alternative energy, the control card and therefore the ignition system can be fed with current obtained from any of the energy sources such as battery, battery, solar panel, adapter, so that the burning device can work uninterruptedly, the ignition system can be easily assembled by forming the controller card in a small size, - the security elements consisting of the fire alarm and gas leakage alarm used in the ignition system can also use low-current energy, and

- the control card and therefore the ignition system can be remotely controlled by remote control and applications.

DESCRIPTION OF DRAWINGS

Figure-1 ; There is a representative schematic view of the controller card of the invention, used in the ignition system operated with 6, 12, and 18 volts.

REFERENCE NUMERALS

As. Ignition system

A. Controller card

1. 24 volt power inputs

1.1. Energy input

1.2. Adaptor input

1.3. Battery input

2. 6 volt power inputs

3. 12 volt power inputs

4. 18 volt power inputs

5. Power control card

6. Liquid/gas meter connection

7. Installation pressure presostat connection

8. Valve connection

9. Temperature indicator connection

10. Presostat connection

11. Lighter igniter connection

12. Flame detector connection

13. Fan motor connection

14. Gas alarm sensor connection

15. Fire alarm sensor connection 17. Activated signal lamp

18. Failure signal lamp

19. Rest button

20. Digital indicator panel

DETAILED DESCRIPTION OF THE INVENTION

The ignition system As used in the burning devices operated with the liquid/gas fuel including furnace, central heating boiler, boiler, and burner consists of a controller card A, a liquid/gas meter, an installation pressure presostat, a valve, a temperature indicator, a presostat, a lighter igniter, a fire detector, a fan motor, a gas alarm sensor and a fire alarm sensor.

In the Figure 1 , there is a representative schematic view of the controller card A used in the ignition system As of the burning devices operated with the liquid/gas fuel including furnace, central heating boiler, boiler, and burner.

The controller card 1 used in the burning devices operated with liquid/gas fuel is developed to allow the controller card to be operated with 6, 12, 18 volts by using the current obtained any of the energy sources including battery, cell battery, solar panel, and adapter instead of 220 or 380 or 24 volt energy, thereby eliminating the failure of the control card in case of high current variations or power cuts. In this process, the following elements is connected thereto in the production stage of the controller card A;

- 6 volt power inputs 2 having an energy input 1.1 , adapter input 1 .2, and battery input 1 .3 controlled by the power control card 5, allowing the controller card A to be operated with the 6 volt current value, which allows the unit As that provides ignition in the burning device, to be controlled;

12 volt power inputs 3 having an energy input 1.1 , adapter input 1 .2, and battery input 1 .3 controlled by the power control card 5, allowing the controller card A to be operated with the 12 volt current value, which allows the unit As that provides ignition in the burning device, to be controlled; 18 volt power inputs 4 having an energy input 1.1 , adapter input 1 .2, and battery input 1 .3 controlled by the power control card 5, allowing the controller card A to be operated with the 18 volt current value, which allows the unit As that provides ignition in the burning device, to be controlled;

Except for the power inputs 1 , 2, 3, 4 in the production stage of the controller card A; the power control card 5, which controls the power inputs 1 ,2, 3, 4 with the specified different currents, is connected.

In the assembly process of the ignition system As, the energy connection to any of the power inputs 1 , 2, 3, 4 on the controller card A, which allows the system As to operate, is made. Afterwards;

- the liquid/gas meter is mounted on the liqu id/gas meter connection 6,

- the installation pressure on the installation pressure connection 7, the valve on the valve connection 8,

- the temperature indicator on the temperature indicator connection 9,

- the presostat on the presostat connection 10, the lighter igniter on the lighter igniter connection 1 1 ,

- the flame detector on the flame detector connection 12, the fan motor on the fan motor connection 13,

- the gas alarm sensor on the gas alarm sensor connection 14, the fire alarm sensor on the fire alarm sensor connection 15.

In the operation of the ignition system As operated with any of the different currents including 6, 12, 18 of the invention, the user presses against the on/off button 16 when the energy is input to any of the power inputs 1 , 2, 3, 4. In this stage, the controller card A performs security checks, including the fire alarm, the gas alarm, the pressure presostat, the level flow presostat, and the air pressure presostat. In case of inconsistency in the limit levels in the software in any of them, the failure signal lamp 18 lights up on the screen. Afterward, the controller card A stops the operation of the system As. By pressing against the reset button 19, when the limits are checked and reached their values, the control card A provides a spark output by outputting the ignition transformer by following the software after the security checks. In this process, the energy output to the ignition electrodes of the lighter igniter (11 ) continues for a minimum of 7 seconds. In 2 seconds, gas or liquid fuel ensures that by sending energy to the valve, the fuel reaches the combustion section/chamber and the combustion takes place. The control and continuity of the flame is ensured in the combustion process with the flame monitoring window or ionization rod. In case of problematic or problematical burning, the valve is de-energized and the ignition system As is brought into an alarm state. In this stage, the alarm code is observed on the digital indicator panel 20 and the controller card A is reset after the necessary intervention is made. If the burning process is in a healthy way, the burning process continues up to the desired level in temperature control by providing continuity and the signal lamp 17 lights up in the circuit. In the security stages and alarm situations, there is a failure code on the screen. In cases such as fire and gas leakage, the burning process is terminated by the signal of the alarm devices in the environment.

The alternative energy sources including battery, cell battery, and solar panel enable the controller card A of the ignition system As to work safely in different current values due to the power inputs 2, 3, 4 of the invention.