THERMOELECTRIC SAFETY ASSEMBLY

Abstract

A thermoelectric safety assembly that includes a thermocouple configured to detect a flame in a burner and, in response to detecting the flame, generating an electrical voltage. The assembly includes an electromagnetic valve electrically connected to the thermocouple, and a transistor electrically connected between the thermocouple and the electromagnetic valve. The electromagnetic valve is arranged electrically connected with a field-effect transistor. The assembly also includes a voltage booster configured to power the transistor, the transistor being connected in parallel with the voltage booster. An output terminal of the voltage booster is arranged connected with a gate terminal of the transistor, the voltage booster being configured to boost the electrical voltage generated in the thermocouple, an electrical voltage being obtained that is capable of keeping the transistor closed such that the electromagnetic valve is energized.

Claims

1. A thermoelectric safety assembly comprising: a thermocouple configured to detect a flame generated by a burner and to produce an electrical voltage in response to detecting the flame; an electromagnetic valve electrically coupled to the thermocouple and configured to allow a passage of gas towards the burner when the electromagnetic valve is energized by the thermocouple; a field-effect transistor electrically connected between the thermocouple and the electromagnetic valve and transitional between an open state and a closed state, in the open state a current generated by the thermocouple is not allowed to pass through the field-effect transistor, in the closed state the current generated by the thermocouple is allowed to pass through the field-effect transistor, the electromagnetic valve being electrically coupled to the field-effect transistor; and a voltage booster configured to power the field-effect transistor and being connected in parallel with the field-effect transistor, an output terminal of the voltage booster being arranged connected with a gate terminal of the field-effect transistor, the voltage booster being configured to boost the electrical voltage generated in the thermocouple so that the electrical voltage is sufficient to cause the field-effect transistor to assume the closed state to allow a current to flow from the thermocouple through the field-effect transistor to energize the electromagnetic valve.

2. The thermoelectric safety assembly according to claim 1, wherein upon the flame not being detected by the thermocouple, a de-energizing of the electromagnetic valve occurs by the field-effect transistor assuming the open state to prevent current to flow from the thermocouple to the electromagnetic valve.

3. The thermoelectric safety device according to claim 1, wherein the field-effect transistor is a metal-oxide-semiconductor field-effect transistors.

4. The thermoelectric safety device according to claim 2, wherein the field-effect transistor is a metal-oxide-semiconductor field-effect transistors.

5. A gas combustion system comprising: a gas burner; a thermocouple configured to detect a flame generated by the burner and to produce an electrical voltage in response to detecting the flame; an electromagnetic valve electrically coupled to the thermocouple and configured to allow a passage of gas towards the burner when the electromagnetic valve is energized by the thermocouple; a field-effect transistor electrically connected between the thermocouple and the electromagnetic valve and transitional between an open state and a closed state, in the open state a current generated by the thermocouple is not allowed to pass through the field-effect transistor, in the closed state the current generated by the thermocouple is allowed to pass through the field-effect transistor, the electromagnetic valve being electrically coupled to the field-effect transistor; and a voltage booster configured to power the field-effect transistor and being connected in parallel with the field-effect transistor, an output terminal of the voltage booster being arranged connected with a gate terminal of the field-effect transistor, the voltage booster being configured to boost the electrical voltage generated in the thermocouple so that the electrical voltage is sufficient to cause the field-effect transistor to assume the closed state to allow a current to flow from the thermocouple through the field-effect transistor to energize the electromagnetic valve.

6. The thermoelectric safety assembly according to claim 5, wherein upon the flame not being detected by the thermocouple, a de-energizing of the electromagnetic valve occurs by the field-effect transistor assuming the open state to prevent current to flow from the thermocouple to the electromagnetic valve.

7. The thermoelectric safety device according to claim 5, wherein the field-effect transistor is a metal-oxide-semiconductor field-effect transistors.

8. The thermoelectric safety device according to claim 6, wherein the field-effect transistor is a metal-oxide-semiconductor field-effect transistors.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0015] FIG. 1 shows an electrical diagram of a thermoelectric safety assembly having a thermocouple powered by a flame of a burner.

DETAILED DESCRIPTION

[0016] FIG. 1 shows an electrical diagram of a thermoelectric safety device 1 in the absence of flame for gas combustion systems according to the invention. The thermoelectric safety device 1 comprises a thermocouple 2 configured to detect a flame 8 in the combustion system, in particular in a burner 10 of the combustion system, and an electromagnetic valve 7 electrically connected to the thermocouple 2 and configured to allow or prevent the passage of gas towards the burner. In the presence of flame the thermocouple 2 heats up, an electrical voltage capable of keeping the electromagnetic valve 7 energized being generated allowing the passage of gas towards the corresponding burner 10. In the absence of flame the thermocouple 2 cools down to the point at which an electrical voltage capable of keeping the electromagnetic valve 7 energized cannot be generated, the electromagnetic valve 7 preventing the passage of gas towards the burner 10.

[0017] The gas combustion system is preferably a gas appliance incorporating the thermoelectric safety device 1. In particular, the gas apparatus may be a gas cooking top, although the thermoelectric safety device 1 could be incorporated to any other type of gas appliance known in the state of the art, a gas oven for example. Furthermore, the gas appliance can comprise a burner or a plurality of burners, each burner comprising the respective thermoelectric safety device 1. Gas electromagnetic valves are known in the state of the art so their description in this application is not considered necessary.

[0018] The thermoelectric safety device 1 further comprises a transistor 6 electrically connected between the thermocouple 2 and the electromagnetic valve 7. The transistor 6 acts as a switch, allowing acting upon the electromagnetic valve 7 regardless of whether the thermocouple 2 detects flame. In other words, by means of a non-depicted control, the electromagnetic valve 7 can be acted upon de-energizing it although the thermocouple 2 detects a flame in the burner.

[0019] The thermoelectric safety device 1 comprises a voltage booster 5 powering the transistor 6, the voltage booster 5 being configured to boost the electrical voltage generated in the thermocouple 2, there being obtained at the output of the voltage booster 5 an electrical voltage capable of keeping the transistor 6 closed such that the electromagnetic valve 7 is energized. The voltage booster 5 is configured to boost a no-load voltage of the thermocouple 2 of millivolts up to a nominal voltage of the transistor 6, said nominal voltage being greater than approximately 1.5V. The nominal voltage of the transistor 6 is preferably approximately 3V.

[0020] The transistor 6 is a field-effect transistor, preferably a MOSFET type transistor. The transistor 6 comprises a gate terminal 6a, a drain terminal 6b and a source terminal 6c, an output terminal 5a of the voltage booster 5 being arranged connected to the gate terminal 6a of the transistor 6.

[0021] The transistor 6 acts as a switch. In particular, when it operates in the cutoff region there is no conduction between the source terminal 6c and the drain terminal 6b, so it operates as an open switch regardless of whether or not the thermocouple 2 detects the presence of flame. In the described embodiment, the transistor 6 allows the passage of current when it is powered with a voltage from 1.5 V, operating as a closed switch when it reaches the nominal voltage.

[0022] When the thermocouple 2 detects the presence of flame it generates a voltage, referred to as no-load voltage, which is amplified through the voltage booster 5. When the nominal voltage of the transistor 6 is reached, the transistor 6 operates as a closed switch, allowing the energization of the electromagnetic valve 7. The thermocouple 2 passes from working with no-load to working with a load from that time. From that time, virtually all the thermoelectric current generated in the thermocouple 2 passes directly through the transistor 6, the voltage booster 5 consuming very little current.

[0023] When the flame turns off, the thermocouple 2 starts to cool down and less thermoelectric current is generated. There comes a time in which the transistor 6 opens and the electromagnetic valve 7 is disengaged, closing the passage of gas towards the burner 10. The disengagement of the electromagnetic valve 7 is controlled by the transistor 6, i.e., before the electromagnetic valve 7 is disengaged because the sufficient current does not reach it when the thermocouple 2 cools down upon the flame of the corresponding burner being turned off, the transistor 6 opens, whereby current automatically does not reach the electromagnetic valve 7 and the electromagnetic valve 7 is disengaged.

[0024] In addition, the excess voltage which is generated in the voltage booster 5 once the transistor 6 has been powered so that it operates as a closed switch, i.e., when it is powered with the nominal voltage, can be used for other functions such as powering luminous indicators of the blinking led type, RFID or battery charging systems used in gas cooking appliances.