US20020001163A1

US20020001163A1 - Electric gas-lighter

Info

Publication number: US20020001163A1
Application number: US09/307,747
Authority: US
Inventors: Massimo Aleardi
Original assignee: Miller Europe SpA
Current assignee: ITW Industrial Components SRL
Priority date: 1998-05-12
Filing date: 1999-05-10
Publication date: 2002-01-03
Anticipated expiration: 2019-05-10
Also published as: EP0957315A3; EP0957315A2; CA2271500A1; US6449138B2; ITTO980398A1; BR9901462A

Abstract

An electric gas-lighter wherein a discharge generating circuit has input terminals connectable to a supply source, and at least one output terminal for generating sparks. The gas-lighter has a filter for eliminating electromagnetic noise and in turn having a single capacitor having a first terminal communicating with a reference potential, and a second terminal communicating with one of the input terminals via a resistor.

Description

The present invention relates to an electric gaslighter which may be applied, for example, to the cooking range of a gas cooker.

BACKGROUND OF THE INVENTION

Cooking ranges are known which are fitted with built-in electric gas-lighters operated manually to produce sparks and light gas flames on the range.

One type of cooking range with an electric gas-lighter (FIG. 1) comprises

metal gas burners

2, each provided with a respective electrode 3 located to the side of the burner 2 and insulated electrically with respect to the grounded metal surface 4 supporting the burners.

When operated, the electric gas-lighter produces a spark between each

electrode

3 and the respective burner 2 to light the flame of the burner supplied with gas.

FIG. 1 shows a complete circuit diagram of one known type of gas-lighter.

In addition to

electrodes

3, the gas-lighter comprises a first and a second input terminal 7, 8 connectable to a supply line, e.g. an alternating mains line (not shown), by closing a switch (not shown); and an electric-discharge generating circuit 5 interposed between input terminals 7, 8 and electrodes 3, and for producing the sparks on electrodes 3.

Circuit 5 comprises a resistor 9 having a first terminal connected to input terminal 7, and a second terminal connected to the anode of a rectifying diode 10, the cathode of which is connected to a first node 11.

Circuit 5 also comprises a capacitor 12 having a first terminal connected to node 11, and a second terminal connected to a node 13 in turn connected to second input terminal 8.

Circuit 5 also comprises a voltage discharge device 15 having a first terminal connected to node 11, and a second terminal connected to a first terminal 16 a of a primary winding 16 of a transformer 17. The primary winding of transformer 17 has a second input terminal 16 b connected to node 13, and transformer 17 also comprises two identical secondary windings 18, each having far more turns than primary winding 16.

The terminals of each secondary winding 18 are connected to respective electrodes 3.

The gas-lighter operates as follows.

When the switch (not shown) is closed to connect the gas-lighter circuit to the alternating supply line, the alternating mains voltage is rectified by

diode

10 and a rectified voltage is applied to charge capacitor 12. When the voltage at the capacitor terminals reaches a threshold value V_THequal to the ignition threshold value of discharger 15, transformer 17 and capacitor 12 are connected, and capacitor 12 discharges via primary winding 16. A discharge current I_SCof extremely high intensity (e.g. a 150-280 A peak) is thus generated and flows through primary winding 16, at the terminals of which a discharge voltage V1 (e.g. of 400 V) is generated during the discharge transient (lasting a few microseconds). Discharge voltage V1 induces, at the terminals of secondary windings 18, a voltage V2 much higher than V1 (e.g. 28 kV) and which is applied to electrodes 3. For each secondary winding 18, voltage V2 is sufficient to produce sparks between each electrode 3 and metal burner 2, which is grounded.

Gas-lighters of the above type have the drawback of generating, at the output (i.e. towards the supply mains) and during the discharge transient, severe electromagnetic noise above the limits laid down by European standards (EN55014 and following).

One proposed solution to the problem is to fit the gas-lighter with an electronic filter to reduce the electromagnetic noise at the output and so obtain a low-noise gas-lighter as shown in FIG. 2. In addition to the components described above (indicated using the same reference numbers), a low-noise gas-lighter comprises an

electronic filter

20 interposed between terminals 7, 8 and a circuit 5 a equivalent to circuit 5 but having no resistor 9.

Filter

20 comprises a first decoupling resistor 25 a having a first terminal connected to terminal 7 and a second terminal connected to a node 22 communicating with the anode of diode 10 and with a first terminal of a capacitor 21 a having a second terminal connected to a reference potential (ground). Filter 20 also comprises a second decoupling resistor 25 b having a first terminal connected to terminal 8 and a second terminal connected to a node 23 communicating with node 13 and with a first terminal of a capacitor 21 b having a second terminal connected to the reference potential (ground).

Capacitors

21 a and 21 b are thus located between

respective nodes

22 and 23 and a common node 24 which is the ground.

Filter

20 defines a preferential path by which to discharge the electromagnetic energy produced during the discharge transient of capacitor 12. More specifically, said energy is conveyed by

capacitors

21 a and 21 b directly towards ground 24 to reduce the electromagnetic emissions emitted by the circuit towards the supply mains.

Though

filter

20 indeed provides for reducing the noise level generated during operation to well below the prescribed limit, gas-lighters fitted with filters 20 are not without further drawbacks.

Though minimum per gas-lighter, the expense of providing the filter with two capacitors is far from negligible on a mass-production scale, as in the household appliance industry.

SUMMARY OF THE INVENTION

It is an object of the present invention to provide an electric gas-lighter which is highly straightforward, and which at the same time provides for eliminating the drawbacks associated with gas-lighters of the type described above.

According to the present invention, there is provided an electric gas-lighter as claimed in claim 1.

BRIEF DESCRIPTION OF THE DRAWINGS

A non-limiting embodiment of the present invention will be described by way of an example with reference to the accompanying drawings, in which: [0022]
FIG. 1 shows a schematic electric diagram of a known filterless electric gas-lighter; [0023]
FIG. 2 shows a schematic electric diagram of a known electric gas-lighter fitted with a filter; [0024]
FIG. 3 shows a schematic electric diagram of an electric gas-lighter featuring a filter in accordance with the teachings of the present invention.[0025]

DETAILED DESCRIPTION OF THE INVENTION

FIG. 3 shows a gas-[0026] lighter 40 comprising a first and a second input terminal 41, 42 connectable to an alternating supply line 43 by closing a switch 44; and an electric-discharge generating circuit 45 interposed between input terminals 41, 42 and electrodes 3, and for producing sparks on electrodes 3.
[0027] Circuit 45 comprises a resistor 47 having a first terminal connected to terminal 41, and a second terminal connected to the anode of a rectifying diode 48, the cathode of which is connected to a first node 50.
[0028] Circuit 45 also comprises a capacitor 52 having a first terminal connected to node 50, and a second terminal connected to a node 53.
[0029] Circuit 45 also comprises a resistor 55 parallel to capacitor 52; and a known discharger 57 (e.g. a Sidac high-energy, solid-state gas tube) having a first terminal connected to node 50, and a second terminal connected to a first terminal 60 a of a primary winding 60 of a transformer 61. Primary winding 60 of transformer 61 has a second input terminal 60 b connected to node 53, and transformer 61 also comprises two identical secondary windings 62, each having far more turns than primary winding 60.
The terminals of each [0030] secondary winding 62 are connected to respective electrodes 3, each facing and a short distance from a metal portion of a respective burner 2.
A [0031] filter 70 comprises a single capacitor 71 of capacitance C, which has a first terminal connected to a reference potential (ground) 73, and a second terminal communicating with node 53 via an electric line 54, which also communicates directly with terminal 60 b of primary winding 60. The second terminal of capacitor 71 also communicates with input terminal 42 via a resistor 65 of resistance R.
Preferably but not exclusively, capacitance C of [0032] capacitor 71 is in nanofarads (e.g. ranges between 1 and 4.7 nanofarads); resistance R is in tens of kilohms (e.g. is about 15 kilohms); and filter 70 operates in the 150 kHz to 300 MHz frequency range and has a mean attenuation of about 20 dB.
In actual use, when [0033] switch 44 is closed, mains voltage is applied to terminals 41 and 42 so that a rectified voltage is applied to charge capacitor 52. When the voltage at the terminals of capacitor 52 reaches a threshold value equal to the ignition threshold value of discharger 57, transformer 60 and capacitor 52 are connected, and capacitor 52 discharges via primary winding 60. A discharge current of extremely high intensity is thus generated and flows through primary winding 60, at the terminals of which a discharge voltage (e.g. of 400 V) is generated during the discharge transient (lasting a few microseconds). The discharge voltage induces, at the terminals of secondary windings 62, a voltage much higher than the discharge voltage and which is applied to electrodes 3.
A [0034] spark 80 is thus generated between each electrode 3 and the outer body of the respective burner 2, and is accompanied by instantaneous current flow between the two burners 2 of each pair of electrodes 3, and through the metal surface supporting and grounding the burners.
The advantages of [0035] filter 70 are as follows.
Using a single capacitor as opposed to two not only simplifies the gas-lighter but also provides for reducing production time and cost, which, in mass production terms, affords considerable saving even eliminating only one component. [0036]
The two-capacitor filter of the electric gas-lighter described with reference to FIG. 2 was based on the preconceived idea that a two-capacitor filter was the only possible way of effectively reducing electromagnetic noise, which was believed to be impossible using a single-capacitor filter. In actual fact, tests of the gas-lighter according to the invention have shown the effectiveness of [0037] filter 70 to be equal to, if not greater than, that of the two-capacitor filter in FIG. 2, and that most of the electromagnetic noise flows along line 54 fitted with filter 70. As such, being fitted along line 54 extending directly between terminal 60 b of primary winding 60 and input terminal 42, filter 70 provides for blocking most of the electromagnetic noise.
Clearly, changes may be made to the electric gas lighter described and illustrated herein without, however, departing from the scope of the present invention. [0038]

Claims

1. An electric gas-lighter wherein a discharge generating circuit (45) comprises input terminals (41, 42) connectable to a supply source (43); and at least one output terminal (3) for generating sparks; said gas-lighter also comprising a filter (70) for filtering electromagnetic noise;

characterized in that said filter (70) comprises a single capacitor (71) having a first terminal communicating with a reference potential (73), and a second terminal communicating with one (42) of said input terminals (41, 42) via first resisting means (65).

2. A gas-lighter as claimed in claim 1, wherein said discharge generating circuit (45) comprises:

capacitor means (52) connected to said input terminals (41, 42) via rectifying means (48);

discharging means (57) connected to said capacitor means (52) to discharge the current accumulated in said capacitor means (52) into the primary winding (60) of a transformer (61) having at least one secondary winding (62) communicating with said output terminal (3).

3. A gas-lighter as claimed in claim 2, characterized in that said filter (70) is located along a line extending directly between a terminal (60 b) of said primary winding (60) and one (42) of said input terminals (41, 42).

4. A gas-lighter as claimed in claim 2, characterized by comprising second resisting means (47) interposed between one (41) of said input terminals (41, 42) and said rectifying means (48).

5. A gas-lighter as claimed in claim 2, characterized by comprising third resisting means (55) parallel to said capacitor means (52).

6. A gas-lighter as claimed in claim 1, characterized in that said capacitor (71) has a capacitance (C) in nanofarads, and said resisting means have a resistance (R) in tens of kilohms.

7. A gas-lighter as claimed in claim 1, characterized in that said filter (70) operates in the 150 kHz to 300 MHz frequency range.

8. A gas-lighter as claimed in claim 1, characterized in that said filter (70) has a mean attenuation of about 20 dB.