JPS62190323A - Automatic gas lighting controlling device of battery type - Google Patents

Abstract

PURPOSE:To obtain an economical automatic gas lighting controlling device, by depressing a gas valve by actuating a DC solenoid at the same time when an all-day timer is turned ON, and by holding the valve in the open state by supplying electric current of a capacitor of large capacity to a gas valve holding solenoid installed in a temperature sensor circuit. CONSTITUTION:An LC display, clock module (1.5V drive) of battery type, of less power consumption is used as an all-day timer 12. A capacitor and keep relays are used in a multipoint circuit 13, which functions as a circuit to control power consumption less. About 20sec is thought to be a proper time for the period of opening of a gas valve 5 at the time of lighting, so that a DC solenoid 24 holds the valve 5 for 1sec, and another contact point 19 is added to the all-day timer 12 in order to hold the valve 5 in the open state for the remaining 19sec. The gas valve 5 is held in the open state by a gas valve holding solenoid 6, by supplying current to the solenoid 6 from a capacitor 21 till the thermoelectromotive force rises in a thermocouple 4. With such an arrangement, automatic lighting controlling wiring for each electric appliance and central automatic lighting controlling board can be eliminated.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to an automatic gas lamp lighting control device that automatically turns on and off a gas lamp without installing a commercial power line.

(Prior Art) A conventional device will be explained with reference to FIG. Two contacts 2a at the lighting time of the all-day timer 1.

2b is turned on, one contact 2a connects the temperature sensor (thermocouple) 4 and the valve open holding solenoid 6 built into the gas valve 5, and the other contact 2b connects the two 2
A timer of about 0 seconds (3a.

3b), one contact 3a of the timer drives the AC solenoid 7 to open the gas valve 5, and the other contact 3b of the timer drives the ignition device 8.

If the gas lamp does not light up, no thermoelectromotive force is generated by the temperature sensor 4, and after the 20 second timer contact 3a is turned off, no thermoelectromotive force is supplied to the solenoid 6 that keeps the gas valve 5 open. , the gas valve 5 closes naturally to stop the gas supply. Also, if the gas lamp lights up within 20 seconds,
A thermoelectromotive force is generated by the temperature sensor 4, and the thermoelectromotive force is supplied to the solenoid 6 that maintains the gas valve 5 in an open state.
The gas lamp continues to light. Also, when the light is turned off, for example when the time to turn off the light of the all-timer 1 has come, by opening the contact 2a of the temperature sensor circuit, the gas valve 5 can stop supplying the thermoelectromotive force of the thermocouple to the valve-open holding solenoid 6. Therefore, the gas valve 5 is forcibly closed and the gas lamp is turned off.

(Problem to be solved by the invention) MJ using conventional equipment for gas lamps! In order to install a gas lamp, automatic lighting control wires and gas piping must be installed for each gas lamp, and an automatic lighting control panel must be installed in the center, which is an economically expensive device. There was a drawback that it became

(Means for Solving the Problems) Therefore, the present invention uses a battery as the power source, and has an all-day timer and a branch circuit that branches the output of the timer to four contacts, and two of the contacts are about 4 each
It has a timer circuit that outputs seconds and approximately 20 seconds, and when the all-day timer is turned on, the 20-second timer drives the lighting circuit, and the 4-second timer drives the DC solenoid to press the gas valve and open the valve. At the same time as turning on the temperature sensor circuit, I switched the contacts of the pre-charged large capacity capacitor and supplied that power to the gas valve holding solenoid to keep the gas valve open for about 20 seconds. Since the automatic lighting control device can be installed with only a few installation works, it is possible to create an economical automatic gas lamp lighting control device.

(Embodiment) To explain the device of the present invention with reference to FIG. 2, the all-day timer 12 has a battery type low power consumption LCD display CL.
An OCK module (operating at 1.5V) is used, and a circuit using a capacitor and a keep relay is used in the branch circuit 13, resulting in a low power consumption control circuit. Also 20 seconds timer 2
The lighting device 8 that operates with the contact 25 of 3 also has 1.5v to 3v.
The spark generator uses a high-voltage transformer to reduce power consumption.

The conventional device requires a strong force from the AC solenoid 7 to keep the gas valve 5 open for 20 seconds, and also consumes a large amount of electric power.

Therefore, the AC solenoid 7 is replaced with a DC solenoid 24, the battery 15 is used as a DC 12V battery, the DC solenoid 24 is used as a DC 6V version, a 10Ω resistor 16 is connected, a 10000 μF capacitor 17 is connected after that, and a 4V battery is used as the battery 15. By connecting the contact point 18 of the second timer 22, the initial operation of the DC solenoid 24 is made strong, and a circuit is adopted that requires only half the rated power to maintain the DC solenoid. Also, in order to create a complete ignition circuit, it is considered appropriate for the gas valve 5 to be open for 20 seconds at the time of ignition, so the DC solenoid 24 is held for 4 seconds, leaving 16 seconds.
In order to maintain the open state for seconds, another contact 19 is added to the all-day timer 12 and a 1.5V battery 2 is connected in advance.
The large-capacity capacitor 21 charged by 0 supplies the power of the capacitor 21 to the gas valve holding solenoid 6 until the thermoelectromotive force of the thermocouple 4 rises, thereby maintaining the gas valve 5 in the open state. I did it like that.

(Effects) The present invention uses a battery as a power source, and has an all-day timer and a branch circuit that branches the output of the timer to four contacts, and two of the contacts have a power supply of about 4 seconds and about 20 seconds, respectively. It has a timer circuit that outputs seconds, and at the same time as the all-day timer is turned on, the lighting circuit is driven by a 20-second timer.
Drive the DC solenoid with a second timer to press the gas valve to open the valve, turn on the temperature sensor circuit, and at the same time switch the contacts of the pre-charged large capacity capacitor and transfer the power to the gas valve holding solenoid. Since the gas valve is maintained in the open state for about 20 seconds after supplying gas, it is an economical automatic gas lamp ignition system that does not require automatic lighting control wires for each gas lamp or a central automatic lighting control panel. I was able to do it.

[Brief explanation of drawings]

Figure 1 is an explanatory diagram of the electric circuit of a device that uses conventional commercial power.
FIG. 2 is an explanatory diagram of the electric circuit of the device of the present invention. 12...Battery type all day timer 13...Branch circuit 14...Temperature sensor circuit contact 15...12V battery 16...10Ω resistor 17...10000μ capacitor 18...4 second timer contact 19...Added contact 20...1.5V battery 21...10F capacitor 22...4 second timer 23...20 second timer 24...DC solenoid 25...20 second timer Contact procedure amendment (voluntarily submitted) January 11, 1985 Commissioner of the Japan Patent Office Kuro 1) Mr. Akio, Incident indication 1986 Patent application No. 31003, title of invention Amended battery type automatic gas lighting control device Relationship with the product case Patent applicant 〒252 Address 3470-1-2 Fukaya, Ayase City, Kanagawa Prefecture Date of amendment order Voluntary submission 10 Contents of amendment Ni-...2 (1) F! IH[11'4F'&53! I, m (71
1<mft6° '<,'' (2) Insert and correct the symbol [14j in FIG. 2. Description 1. Title of the invention: Battery-type automatic gas lighting control device 2. Claims: A device using a battery as a power source, an all-day timer,
It has a branch circuit that branches the output of the timer to four contacts, and two of the contacts have timer circuits that output approximately 1 second and approximately 20 seconds, respectively, and the 20 second timer is activated at the same time as the all-day timer is turned on. , drive the tachiiri crotch, drive the DC solenoid with the upper sand timer, press the gas valve to open the valve, turn on the temperature sensor circuit with Mataya's two batteries, and at the same time turn on the temperature sensor circuit, which is charged in advance. Switch the contacts of the large capacity capacitor and supply the power to the gas valve holding solenoid in the sensor circuit.
A complete gas set that keeps the gas valve open for about seconds. 3. Detailed Description of the Invention (Field of Industrial Application) The present invention relates to an automatic gas lighting control device that automatically turns on and off gas appliances without installing a commercial power line. (Prior Art) A conventional device will be explained with reference to FIG. Two contacts 2a at the lighting time of the all-day timer 1. 2b is ONL, one contact 2a connects the temperature sensor (thermocouple) 4 and the valve open holding solenoid 6 built in the gas valve 5, and the other contact 2b connects the two 2
A timer (3a, 3b) of about 0 seconds is started, one contact 3a of the timer drives the AC renoid 7 to open the gas valve 5, and the other timer contact 3b drives the ignition device 8. If the gas is not lit, no thermoelectromotive force is generated by the temperature sensor 4, and no thermoelectromotive force is supplied to the solenoid 6 that keeps the gas valve 5 open after the 20 second timer contact 3a is turned off. The gas valve 5 closes naturally to stop the gas supply. Moreover, if the gas is turned on within 20 seconds, a thermoelectromotive force is generated by the temperature sensor 4, which supplies the thermoelectromotive force to the solenoid 6 that holds the gas valve 5 in an open state, so that the gas continues to be lit. Also, when the light is turned off, for example when the time to turn off the light of the all-timer 1 has come, by opening the contact 2a of the temperature sensor circuit, the gas valve 5 can stop supplying the thermoelectromotive force of the thermocouple to the valve-open holding solenoid 6. Therefore, the gas valve 5 is forcibly closed and the gas is turned off. (Problem to be solved by the invention) M! In order to do this, automatic lighting control wires and gas piping must be installed for each gas appliance, and an automatic lighting control panel must be installed in the center, which is an economically expensive device. There was a drawback that it became (Means for Solving the Problems) Therefore, the present invention uses a battery as the power source, and has an all-day timer and a branch circuit that branches the output of the timer to four contacts, and two of the contacts are about 1 each
It has a timer circuit that outputs seconds and approximately 20 seconds, and when the all-day timer is turned on, the 20-second timer drives the ignition device, and the 1-second timer drives the DC solenoid to press the gas valve and open the valve. Then, at the same time, turn on the temperature sensor circuit with the other two contacts, switch the contacts of the pre-charged large capacity capacitor, supply that power to the gas valve holding solenoid of the temperature sensor circuit, and turn on the gas valve for about 20 seconds. Since it is maintained in the open state, gas appliances with an automatic lighting control device can be installed without the need for commercial power lines and with only gas installation work, making it possible to install an economical automatic gas lighting control device. done. (Embodiment) To explain the device of the present invention with reference to FIG. 2, the all-day timer 12 has a battery type low power consumption LCD display CL.
OCK module) Li (1.5V operation) is used, and a circuit using a capacitor and a keep relay is used in the branch circuit 13, resulting in a low power consumption control circuit. 20 again
The ignition device 8 operated by the contact 25 of the second timer 23 also has 1.
Low power consumption is achieved by using a spark generator that uses a high voltage transformer that operates at 5V to 3V. The conventional device requires a strong force from the AC solenoid 7 to keep the gas valve 5 open for 20 seconds, and a large amount of electric power is consumed to output that force. Therefore, the AC solenoid 7 is replaced with a DC solenoid 24, the battery 15 is used for DC 12V, the DC solenoid 24 is used for DCeV, a resistor 16 is connected, a capacitor 17 is connected after that, and a one-second timer 22 is used.
By connecting the contact 18 of the DC solenoid 24, the initial operation of the DC solenoid 24 is made strong, and a circuit that requires only half the rated power to maintain the DC solenoid 24 is adopted. In addition, in order to completely light the circuit, it is considered appropriate for the open time of the gas valve 5 to be about 20 seconds, so the DC solenoid 24 is held for 1 second, and the remaining 19 seconds remain open. Add another contact 19 to the all-day timer 12 and set 1 in advance.
．． The large-capacity capacitor 21 charged by the battery 20 of 5■ supplies power from the capacitor 21 to the gas valve holding solenoid 6 until the thermoelectromotive force of the thermocouple 4 rises, thereby opening the gas valve 5. I tried to maintain the condition. (Effects) The present invention uses a battery as a power source, and has an all-day timer and a branch circuit that branches the output of the timer to four contacts, and two of the contacts are connected to each other for about 1 second and about 200 seconds, respectively. It has a timer circuit that outputs seconds, and at the same time as the all-day timer is turned on, the ignition device is driven by a 20-second timer, and 1
Drive the DC solenoid with a second timer to press the gas valve to open it, and at the same time turn on the temperature sensor circuit with the other two contacts, switch the contacts of the pre-charged large capacity capacitor. This power is supplied to the gas valve holding solenoid in the temperature sensor circuit to keep the gas valve open for about 20 seconds, eliminating the need for automatic lighting control wires for each gas appliance and for a central automatic lighting control panel. We were able to create an economical gas automatic lighting control device. 4. Brief explanation of the drawings Figure 1 is an explanatory diagram of the electric circuit of a device that uses conventional commercial power.
FIG. 2 is an explanatory diagram of the electric circuit of the device of the present invention. 12... Battery type all-day timer 13... Branch circuit 14... Temperature sensor circuit contact 15... 12V battery 16... Resistor 17... Capacitor 18... 1 second timer contact 19. ...Added contacts 20...1.5v battery 21...IOF capacitor 22...1 second timer 23...20 second timer 24...6VDC solenoid 25...20 second timer contact

Claims (1)

[Claims] It uses a battery as a power source, and has an all-day timer.
It has a branch circuit that branches the output of the timer to four contacts, and two of the contacts have timer circuits that output approximately 4 seconds and approximately 20 seconds, respectively, and the 20 second timer is activated at the same time as the all-day timer is turned on. Drive the lighting circuit, drive the DC solenoid with a 4-second timer, press the gas valve to open it, turn on the temperature sensor circuit, and at the same time switch the contacts of the pre-charged large capacitor. A battery-powered gas lamp automatic lighting control device that supplies the electric power to a gas valve holding solenoid to maintain the gas valve in an open state for about 20 seconds.