This invention relates to a burner including an ignition device having improved wiring.
Burners used indoors and outdoors include those having a small gas cylinder containing liquefied gas such as butane, and a burner head wherein liquefied gas in the gas cylinder is vaporized and burned at the burner head. Some of these burners include means for generating electric discharge such as a piezoelectric element so that gas can be readily ignited at locations where fire sources are not readily available, such as at outdoor camping sites (see e.g. JP2000-104925A).
A piezoelectric element 7 is mounted to the housing 1. The piezoelectric element 7 is connected through an electric wire 8 to a core wire 10 located adjacent to burner ports 9 formed in the burner head 4. Electric discharge is generated by depressing a piezoelectric switch 11. The position of the core wire 10 is not particularly limited provided gas can be reliably ignited by the electric discharge between the core wire 10 and the burner head 4. But ordinarily, it is preferably provided adjacent to the center of the concentric circles along which the burner ports are arranged (and thus remote from the peripheral edge of the burner head 4). By providing the core wire 10 adjacent to the center of the concentric circles along which the burner ports are arranged, it is possible to minimize the distance between the core wire 10 and the burner port remotest from the core wire, so that all the burner ports 9 can be ignited quickly.
When the core wire 10 is provided adjacent to the center of the above concentric circles, as shown in
In this conventional arrangement, since the wire 8 is provided outside the intake pipe 3, the wire 8 may be caught by an external object and damaged during transportation. Also, flames of the burner head 4 may overheat and deteriorate the wire 8, thereby shortening its life. Thus, in order to prevent contact to the wire 8 and leakage of air-gas mixture, the wire 8 is provided with shield plate 26 (see
An object of the present invention is to prevent damage to and overheating of the electric wire for electric discharge/ignition, thereby increasing its life, without increase in cost.
In order to achieve this object, according to the present invention, the above-mentioned electric wire or the means for generating electric discharge are arranged to extend through the intake pipe. By arranging the electric wire or the electric discharge means to extend through the intake pipe, since the wire or the means is not exposed, it is never damaged by being caught by an external object during transportation. Also, because the air-gas mixture is flowing through the intake pipe, and the mixture is always kept at around the room temperature, the wire or the means is less likely to be overheated and deteriorate.
In a specific arrangement, the burner according to the present invention comprises a burner head having burner ports, an intake pipe through which a mixture of gas and air is configured to be supplied to the burner head so as to be released through the burner ports, and a core wire provided adjacent to the burner ports for generating electric discharge therefrom, thereby igniting the mixture, wherein the burner further comprises means for generating electric discharge from the core wire, and an electric wire extending through the intake pipe and connecting the core wire to the means, the burner head being formed with a through hole through which the core wire extends from inside to outside the burner head, and wherein an insulator is disposed between the core wire and the burner head to keep the core wire insulated from the burner head. The insulator may be a ceramic insulator. A ceramic insulator is inexpensive and has a relatively high heat resistance.
Since the electric wire extends through the intake pipe to the burner head, only one through hole is necessary to protrude the core wire from the burner head. Thus, compared to the conventional burner (see
The core and the electric wire may not necessarily be separate members. For example, the free end of the electric wire may be protruded from the ceramic insulator as the core wire.
In this arrangement, instead of connecting the core wire to the means for generating electric discharge by means of the wire, the means for generating electric discharge may be extended to the burner head so that one end of the means protrudes from the burner head, the core wire comprising the one end of the means.
With this arrangement, it is not necessary to connect the electric wire to the electric discharge generating means, so that the burner can be assembled more easily. Also, it is possible to reduce the number of parts used.
In this arrangement, the electric discharge generating means may be a piezoelectric element. Since a piezoelectric element can generate electric discharge without the need for an external power source such as a battery, the burner can be used e.g. outdoors where no external power sources are readily available.
According to this invention, since the electric wire that connects the core wire to the electric discharge generating means or the electric discharge generating means itself is arranged to extend through the intake pipe, the wire or the electric discharge generating means is never caught and damaged by an external object during transportation. Also, the wire or the electric discharge generating means is less likely to deteriorate due to overheating during use of the burner. This eliminates the necessity to provide the wire or the electric discharge generating means with e.g. a shield plate, which in turn makes it possible to reduce its manufacturing cost. Also, it is possible to prolong the life of the burner.
a) is a plan view of a burner head of the burner according to the present invention; and
a) is a plan view of a different burner head of the burner according to the present invention; and
The burner head 4 has a through hole 12 extending through the center of its top surface. A ceramic insulator 13 is fitted in the through hole 12, closing the through hole 12. A core wire 10 is embedded in the ceramic insulator 13 and has a first end protruding outwardly from the burner head 4 so that electric discharge occurs between the first end of the wire 10 and the top surface of the burner head 4. The core wire 10 has a second end protruding into the burner head 4 and connected to a piezoelectric element 7 provided in the housing 1 through an electric wire 8 extending through the intake pipe 3. By depressing a piezoelectric switch 11 of the piezoelectric element 7, electric discharge occurs from the first end of the core wire 10, which ignites and burns the gas supplied to the burner ports 9.
As shown in
The position of the wire 8 in the intake pipe 3 is not limited provided the wire 8 does not influence the mixing of gas and air, and is determined e.g. by experiments or fluid simulations.
As described above, since the electric wire 8 is not exposed to the outside of the intake pipe 3, the wire 8 is least likely to be caught and damaged by an external object. Since the temperature of the gas-air mixture is always kept at around the normal temperature, the wire 8 is less likely to deteriorate due to overheating during use of the burner. This eliminates the need to provide the electric wire 8 with a shield plate to protect the wire 8. This simplifies the manufacturing steps of the burner and reduces its manufacturing cost.
Instead of connecting the core wire 10 to the piezoelectric element 7 through the electric wire 8, as shown in
Instead of the burner head 4 shown in
The present invention is applicable to not only burners in a narrow sense but to burners in a broad sense including lanterns and heaters, because lanterns and heaters also have a burner head for burning an air-gas mixture.
Typical lanterns are shown in
In these lanterns too, as with the above-mentioned burner, the electric wire 8 or the terminal extends through the intake pipe, and the core wire 10 protrudes from the burner head 4. Electric discharge is generated from the core wire 10 to ignite the burner head 4, thereby emitting light from the mantle 14 (see
The above-mentioned heater includes a burner head for burning an air-gas mixture to produce radiant heat, and radiate the thus generated radiant heat in a predetermined direction by means of a reflecting plate. Since the basic elements of this heater, including the burner head, are identical to those of an ordinary burner, this invention is applicable to this heater too.
In the above embodiments, the piezoelectric element 7 is used to generate electric discharge. But means for generating electric discharge is not of importance in the present invention, and different means may be used to generate electric discharge, such as dry cells.
According to the present invention, the fire power of the burner is adjusted by pushing in the spindle 6, which is an element of a regulator, thereby adjusting the degree of opening of a valve body 19. Since the valve body 19 is biased in a straight line in the axial direction of the spindle 6, the fire power is accurately adjustable.
In particular, as shown in
Since the spherical member 24 has a diameter larger than the coil diameter of the adjusting spring 23, when the spherical member 24 is brought into contact with the end of the adjusting spring 23 from its axial direction, the spherical member 24 is kept in line contact with the end of the adjusting spring 23 along an annular line without being getting into the adjusting spring 23. Thus, even if the spindle 6 is slightly inclined relative to the axis of the housing when the spherical member 24 is pushed in by the spindle 6, they remain in line contact with each other along an annular line.
The spindle 6 has a conical tapered surface 6a on its inner side, and the spherical member 24 is guided in the axial direction of the spindle 6 while being stably received in the recess defined by the conical tapered surface 6a. This minimizes looseness between the spindle 6 and the spherical member 24, so that the spindle 6 and the spherical member 24 are stably kept in line contact with each other along an annular line. The tapered surface 6a is not limited to a conical surface but may be e.g. in the shape of a square pyramid, provided the spherical member 24 can be stably guided by such a tapered surface.
The regulator is not limited to the one shown in
Number | Date | Country | Kind |
---|---|---|---|
2008-076043 | Mar 2008 | JP | national |
2008-077801 | Mar 2008 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/JP2009/055407 | 3/19/2009 | WO | 00 | 9/16/2010 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2009/119432 | 10/1/2009 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
3330267 | Bauer | Jul 1967 | A |
20060040374 | Nishiyama et al. | Feb 2006 | A1 |
Number | Date | Country |
---|---|---|
1 323 639 | Jul 1973 | GB |
47-33873 | Oct 1972 | JP |
55-22885 | Jun 1980 | JP |
60-21864 | Feb 1985 | JP |
60021864 | Feb 1985 | JP |
2000-104925 | Apr 2000 | JP |
2000-193239 | Jul 2000 | JP |
2005-317514 | Nov 2005 | JP |
Entry |
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Notice of Reasons for Rejection issued Oct. 30, 2012 in JP 2008-076043 which is a foreign counterpart to the present application (and its partial English translation). |
International Search Report issued May 19, 2009 in International (PCT) Application No. PCT/JP2009/055407. |
Number | Date | Country | |
---|---|---|---|
20110027733 A1 | Feb 2011 | US |