Method and device for verifying the integrity of gas valve operators in a gas appliance

Abstract

A method and device for verifying the integrity of each operator of a gas valve including two operators disposed in succession on a passage path for the gas directed to a burner; the operator being subjected to command action by a corresponding actuator controlled by a command and control unit adapted to sense the presence of the flame in the burner, which is correlated with the gas flow rate reaching this burner. Each operator is made to close alternately, with corresponding cessation of gas feed to the burner and successive sensing of the extinguishing of the flame at the burner within a predefined time period, power to these operators being completely interrupted if it is sensed after said time period that the flame is extinguished.

Claims

1. A method for verifying the integrity of each operator of a gas valve of a gas appliance, the gas valve comprising two said operators disposed in succession along a gas passage path through the gas valve configured for supplying gas to a burner in the gas appliance, the method comprising: having each of said operators comprise: a body accommodating a portion of the gas passage path, a movable valving member disposed within the body to close or open the respective portion of the gas passage path, and an electrically powered valving member actuator for operating the movable valving member to regulate closing or opening the respective portion of the gas passage path according to burner extinguishing requests, subjecting each of the valving member actuators to command action by a corresponding operator actuator, controlling each of the operator actuators in its turn by a command and control unit which supervises the gas appliance operation, wherein each operator actuator is electrically controlled, and controlling the electrical feed current to the operator actuator causes a minimum closure action of the respective gas passage path, the minimum closure action being defined by an electrical feed current different from zero but sufficient to cause closure of the respective gas passage path by the intervention of the respective operator, determining the electrical feed current sufficient to close the respective valve passage path portion by reducing the electrical feed current, starting from the electrical feed current which is able to maintain the operator in a position in which the operator does not choke the gas passage path, wherein the determination is performed at predetermined time intervals to evaluate if there has been decay in the electrical feed current sufficient to close the respective valve passage path portion, the command and control unit sensing a flame signal corresponding to the presence of the flame in the burner of the gas appliance proportional to the gas flow rate reaching the burner, each operator being made to close alternately, with corresponding cessation of gas feed to the burner and successive sensing of the extinguishing of the flame at the burner, detecting incorrect functionality of at least one of the operators whenever it is sensed that the flame is extinguished only at a time after a predefined limit has been exceeded, this indicating the incorrect functionality of the operator subjected to closure; and upon detecting the incorrect functionality of at least one of the operators, performing the additional step of permitting each of the operators to simultaneously close the gas passage to bring the gas passage into a safety position.

2. The method as claimed in claim 1, wherein the predefined limit is a time period between 0 and 30 seconds, wherein each operator actuator is a stepping motor or solenoid motor.

3. The method as claimed in claim 1, wherein electrical feed current sufficient to close the respective valve passage path portion is achieved by gradually reducing the electrical feed current, starting from the electrical feed current which is able to maintain the operator in a position in which the operator does not choke the gas passage path.

4. The method as claimed in claim 1, wherein each valving member actuator is an electric motor, a minimum closure action of the respective gas passage path portion being defined by a movement of the motor which enables the closure of the respective gas passage path of the gas valve to close within a predetermined time interval.

5. The method as claimed in claim 1, implemented at each burner extinguishing request.

6. The method as claimed in claim 1, implemented at predefined time intervals.

7. The method as claimed in claim 1, implemented after a predefined number of ignitions.

8. The method as claimed in claim 1, implemented by forcing the extinguishing of the burner if the burner is continuously in operation.

9. The method as claimed in claim 2, wherein the predefined time period is between 0 and 10 seconds.

10. The method as claimed in claim 9, wherein the predefined time period is between 0 and 3 seconds.

11. The method as claimed in claim 1, wherein the additional step comprises the step of performing a safety closure of each operator by permitting the corresponding operator actuator for each operator to completely close the respective gas passage path portion, wherein a safety closure of the gas passage path occurs.

12. The method of claim 1, wherein the gas appliance is a boiler.

13. The method of claim 1, wherein the gas appliance is a water heater.

14. The method as claimed in claim 1, wherein each valving member actuator is an electric solenoid, a minimum closure action of the respective gas passage path portion being defined by an electric current value to the solenoid which enables the closure of the respective gas passage path portion of the gas valve within a predetermined time interval.

15. The method as claimed in claim 1, wherein each valving member actuator is an electric motor, a minimum closure action of the respective gas passage path portion being defined by an electric current value to the electric motor which enables the closure of the respective gas passage path portion of the gas valve within a predetermined time interval.

16. The method according to claim 1, wherein each valving member actuator is a solenoid.

17. The method according to claim 16, wherein each operator actuator is a stepping motor or solenoid motor.

18. A method for verifying the integrity of each operator of a gas valve of a gas appliance, the gas valve comprising two said operators disposed in succession along a gas passage path through the gas valve configured for supplying gas to a burner in the gas appliance, the method comprising: having each operator comprise: a body accommodating a portion of the gas passage path, a movable valving member disposed within the body, and an electrically powered valving member actuator operating the movable valving member to regulate closing or opening the respective portion of the gas passage path according to burner extinguishing requests, subjecting each of the valving member actuators to command action by a corresponding operator actuator, adapting each of the operators to regulate closing or opening of the gas passage path according to burner extinguishing requests; controlling electrical feed current from each of the operator actuators to each of the valving member actuators causing a minimum closure action of the gas passage path, the minimum closure action being defined by an electrical feed current different from zero but sufficient to cause closure of the gas passage by the intervention of the operator; determining the electrical feed current sufficient to close the respective valve passage path portion by reducing the electrical feed current, starting from the electrical feed current which is able to maintain the operator in a position in which the operator does not choke the gas passage path, wherein the determination is performed at predetermined time intervals to evaluate if there has been decay in the electrical feed current sufficient to close the respective valve passage path portion, controlling each of the operator actuators in its turn by a command and control unit which supervises the gas appliance operation; sensing a flame signal corresponding to the presence of the flame in a burner of the gas appliance proportional to the gas flow rate reaching the burner by the command and control unit; alternating closing each operator with corresponding cessation of gas feed to the burner and successive sensing of the extinguishing of the flame at the burner; interrupting the gas feed being detected due to incorrect functionality of at least one of the operators whenever it is sensed that the flame is extinguished only at a time after a predefined limit has been exceeded, this indicating the functionality of the operator subjected to closure is not completely correct; and performing the additional step of permitting each of the operators to simultaneously close the gas passage to bring the gas passage into a safety position upon detecting incorrect functionality of at least one of the operators.

19. The method according to claim 18, wherein each valving member actuator is a solenoid.

20. The method according to claim 19, wherein each operator actuator is a stepping motor or solenoid motor.

Description

(1) The present invention will be better understood from the following drawings, which are provided by way of non-limiting example and in which:

(2) FIG. 1 shows a detail of a gas valve controlled by the method of the present invention;

(3) FIG. 2 is a graphic representation of the various stages of the method of the invention; and

(4) FIG. 3 shows a scheme of a device according to the invention.

(5) With reference to said figures, a gas valve 1 is shown partially in FIG. 1 and comprises a body 2 in which a gas passage 3 is provided. This valve is positioned in a gas conduit 4 (see FIG. 3) and is arranged to enable or interrupt (or choke) the gas flow to a burner of a domestic and/or industrial appliance for heating water and for the production of domestic hot water. FIG. 3 shows a flame 5 which is generated at said burner (not shown).

(6) Known operators 6 and 7 are provided along the conduit 4 to regulate or partially or completely interrupt gas flow through the passage 3 and hence through the conduit 4. These operators comprise, for example, a valving element 10 movable on an aperture 12 between two successive chambers 13 and 14 of said passage 3 and an actuator 15 for moving the valving element 10. This actuator can comprise a solenoid 16 acting on a mobile implement 17 carrying the valving element 10 at one end; when the solenoid is powered, this implement 17 can be moved along its longitudinal axis W against a spring 18 which tends to maintain the valving element closed on the aperture 12. When the solenoid is not powered, the valving element closes onto the aperture 12, forced by the spring.

(7) Each operator 6 and 7 is commanded and controlled in its operation by a corresponding actuator 20, 21 connected to a command and control unit 24 for commanding and controlling the correct operation of the appliance or boiler. This is also achieved via a flame signal sensing device 25, of known type, positioned in proximity to the flame 5.

(8) With the unit 24 a security switching member 27 (powered by mains 28) is associated, presenting a known switching element 30 (for example a relay or other member such as to apply to the operators the electricity quantity for actuation) controlled and commanded by the unit 24. The actuators 20 and 21 and hence the operators 6 and 7 (for example the solenoids 16 of this latter) are powered via the member 27. A diagnostic module 33 (for example controlled by a microcontroller or part thereof if an integral part of the unit 24) controls the correct operation of the operators 6 and 7 and is connected to the member 27, to the operators 6 and 7 of the valve 1 and to the actuators 20 and 21 connected to these latter. However, current regulations maintain that a third safety control element for the two gas operators is not necessary, therefore for example the safety member 27 could be omitted or not be present.

(9) In particular, the actuator 20 is arranged to command an operator 6 preferably of ON-OFF type, whereas the actuator 21 is arranged to command an operator 7 preferably of modulating ON-OFF type. The operators can hence be mutually different: for example one operator could be commanded by a stepping motor or another operator could replace or be added to the solenoid-type operators 6 and 7. In that case the actuator 21, or an additional actuator, could consist of a known member for controlling the motor command waveform (frequency, steps and current).

(10) Hence in the case of the illustrated valve 1 (but non-binding, given by way of example only): the operators 6 and 7 are commanded at low voltage, the command of the two series operators is separate, and two current regulators are present (associated with the actuators 20 and 21) to fulfil the command sequence.

(11) Without detracting from the possibility of applying a variable (current or voltage) command to the operators, in known manner, it is evidently possible to also construct the valve 1 for, and to apply the control method of the invention to, operators functioning at different voltages (for example electric mains) and/or alternating voltages.

(12) The method for controlling the functionality of the operators 6 and 7 consists of defining for each operator a closure sequence which manages to identify a drift, i.e. a fall, in the closure force (i.e. the capacity to completely intercept the aperture 12 on which the valve 10 operates) by utilizing: the operator command current as an indirect “measurement” of the closure force; and the flame as an indication of the gas flow rate to the burner.

(13) This closure sequence takes place at a command current with an established value different from zero.

(14) When the command current has been reduced to this value (by the action of the unit 24 alternately on each actuator 20 and 21), if the operator 6 or 7 is integral and free of faults which could prevent correct functionality, the gas passage 3 is closed completely, resulting in cessation of the flame signal sensed by the sensor 25. The control unit 24 senses the extinguishing of the burner within a predetermined time period (for example between 0 and 30 seconds, advantageously between 0 and 10 seconds, and typically less than 1 second), consequently considering the system to be integral and enabling its subsequent regular operation.

(15) In the case of an operator 6 or 7 which is non-integral or is faulty (generically a “reduced closure force” on the valving element 10), a reduction of the command current to the established value does not result in closure or results only in partial closure of the gas passage 3 within the predetermined time. The control unit 24 detects the non-extinguishing of the burner flame (or alternatively only a partial decay) and goes into a safety condition (block stoppage), completely shutting off the command current to the actuators 20 and 21 to ensure closure of the operator 6 or 7.

(16) The current value is defined by considering the limiting closure value, on reaching which the gas operator 6 or 7 is still able to fulfil its safety function with sufficient margin.

(17) Simplifying, if the operator 6 or 7, when subjected to closure with this value, remains open, this is detected and the operator is set to safety; the residual closure force is in any event such as to ensure, once the command is removed (by removing electric power to the actuators 20 and 21), and with a margin, the complete tight closure of the closure member or valving element 10 (by virtue of the spring 18).

(18) Consequently, by controlling the flame, the unit 24 determines whether by the closure generated by the appropriate intervention on the corresponding actuator 20, 21 the operator 6, 7 has been brought into the position for closing the relative aperture 12. If this has occurred and has occurred within the predetermined limiting time, the unit 24 determines whether the operator works effectively. Otherwise it commands immediate safety closure (and preferably generating a warning signal for the user).

(19) The unit 24 is therefore able to determine what minimum action each actuator 20 and 21 has to carry out on the corresponding operator 6 and 7 to achieve closure of its relative aperture 12. This action can be expressed as a current value if the operator is a solenoid, or a particular action of an electric motor if the operator is driven by this latter (for example a predefined number of steps, or different current to the windings, for operating a stepping motor).

(20) FIG. 2 shows the closure sequence of the two operators 6 and 7 of the valve 1. As can be seen from the sequence shown in FIG. 2, on closure, while one operator (for example that operator 6 indicated in FIG. 2 as EV2) is maintained open in the final working state, the command current is reduced to drift test current on the other operator 7, indicated as EV1 (subject of the “closure force test”). If the burner is extinguished within a predefined time (the flame 5 disappears as sensed by the sensor 25), the operator is integral; in the opposite case there has been a drift in the closure force and consequently a block stoppage is carried out, hence putting the system to safety.

(21) This operation is alternatively carried out at each burner extinguishing request by the unit 24 in accordance with a predefined working programme (for example by means of an environmental thermostat) and/or at predefined time intervals (for example every predefined number of ignitions or a certain number of hours of operation) on both the operators 6 and 7, hence ensuring permanent monitoring of operator integrity, or by forcing periodic extinguishing in the case of systems permanently in operation.

(22) The described method can be alternatively carried out not by instantly reducing the feed current (generated by the actuators 20 and 21) of the operators 6 and 7 to a predefined value but by reducing it gradually such as to measure the extinguishing current and evaluating its possible decay with time, to then carry out the aforedescribed necessary safety actions.

(23) A particular embodiment of the invention has been described. Others are possible depending on the type of operators 6 and 7, for example by acting by means of a stepping motor or solenoid motor. In the case of a motor, for example, the value at which the functionality of the operator is investigated is a predefined number of rotation steps of the motor, or a certain value of the current to the windings at which the valving element is able to close the passage 3. These solutions are also to be considered as falling within the scope of the following claims.