WO2010026058A1 - Gas valve - Google Patents

Abstract

The object of the invention is a gas valve (10, 110) for a gas-operated cooking appliance, comprising a valve body (12, 112) with a plug receptacle opening. A plug (24, 124) is disposed rotatably in the plug receptacle opening and comprises an outer surface (80) that is designed at least partially from an elastic rubber material. According to the invention, the elastic rubber material is made up of a self-lubricating silicone. The plug (24, 124) can be made entirely of the elastic rubber material, at least in a partial area of the outer surface (80) up to an inner surface facing a hollow inner space (26).

Description

 gas valve

The invention relates to a gas valve for a gas-powered cooking appliance.

Such cooking appliances can be designed, for example, as gas stoves, gas hobs or as gas ovens. The heat source used in these cooking appliances is a gas flame burning at a gas burner. The fuel used is a suitable fuel gas, such as natural gas, city gas or LPG (propane and / or butane gas). The performance of the gas burner is controlled by an operator of the cooking appliance by means of the gas valve. For this purpose, the gas valve has a variable opening cross-section, which is adjustable by the operator by actuating the gas valve.

According to a conventional design, the gas valve is designed as a plug valve. Such a plug valve has a metallic valve body into which a plug receiving opening is incorporated. The chick receiving opening is usually designed as a conical or cylindrical bore. A correspondingly shaped plug is inserted into the plug receiving opening and is rotatable relative to the valve body. In the chick, at least one gas passage opening is incorporated, which connects a hollow interior of the plug with an outer surface of the plug. The valve body has a corresponding outlet channel, which leads from an inner circumferential surface of the plug receiving opening to a gas outlet, to which a gas line leading to the burner is connected. Depending on the rotational position of the plug, the gas passage opening and the outlet channel overlap completely, partially or not at all. The opening cross section of the gas valve results from the degree of overlap of the gas passage opening and the outlet channel. By turning the plug in the chick receiving opening, the opening cross section of the gas valve and thus the power of the gas burner is infinitely adjustable.

In order to avoid a wear caused by friction and to limit the torque required to rotate the plug, it is known that the chick in the

To lubricate the chick receiving opening. The valve body and the plug are usually made of metal, such as aluminum or brass. When Lubricant is usually used in grease. A disadvantage of this arrangement is that the grease partially settles in the gas passage opening and in the outlet channel, thereby closing a part of the opening cross-section. This leads for example to a hysteresis effect when opening and closing the gas valve and also prevents a reproducibility of a specific burner output by turning the plug into a specific angular position.

According to another known in the art, the valve body is made entirely of metal, while the chick has a metallic core and the surface of the plug is coated with plastic, for example with synthetic resin. To reduce friction, particles of graphite are incorporated in the plastic. Such a gas valve is described for example in the document GB 755 536. It is known from GB 2 079 407 A to carry out the surface of the plug of a PTFE valve. However, such valves have disadvantages in terms of ease of manufacture and lifetime.

The present invention is therefore an object of the invention to provide an easy to produce gas valve with a long service life, which is precisely adjustable with the gas supplied to the gas burner amount.

This object is achieved by the characterizing features of the independent claims 1, 2 or 3.

According to the invention, the rubber-elastic material is formed by a self-lubricating silicone. A self-lubricating silicone is a silicone-based plastic. That to reduce the friction between chicks and

Chick receiving opening provided lubricant is contained in the silicone and does not have to be applied from the outside. The lubricant is already introduced into the silicone during the polymerization of the silicone. When using self-lubricating silicone can be completely dispensed with additional, externally applied lubricant.

Another aspect of the invention is that an oil is provided as a lubricant. The oil used as a lubricant is in contrast to fat at Ambient temperature liquid. The oil accumulates in contrast to fat not in the gas passage opening or in the outlet channel. A narrowing of the flow cross section through the oil is thus excluded. The lubricant oil can be applied during the assembly of the plug in the chick receiving opening. It is also possible to relubricate the chick already mounted in the chick receiving opening, for example in the course of maintenance work. When using self-lubricating silicone, the oil may be included as a lubricant in the silicone.

According to a further aspect of the invention, the chick is at least in a partial area from the outer surface to a hollow interior facing inner surface made entirely of the rubber-elastic material. The rubber-elastic material is designed here as a solid material. At least in a portion of the rubber-elastic material forms the chick per se, and not only its surface. The gas passage opening is preferably located in this portion and is completely formed in the rubber-elastic material. Thus, the gas passage opening can already be made during the primary molding of the rubber-elastic material. A mechanical post-processing of the rubber-elastic material is not required. For the preparation of the gas passage opening and no mechanical fine machining of a metallic part of the plug is required.

With particular advantage, a silicone is provided as rubber-elastic material. Silicone as a material is characterized by a high abrasion resistance and a good aging resistance. The shape of the chick can be made so precisely with the prototyping of the silicone, that the chick closes the chick seat tightly, so that leakage of gas into the environment is reliably prevented.

When using self-lubricating silicone, an oil provided for lubricating the plug with respect to the valve body is completely contained in the self-lubricating silicone. In this case, no additional oil for lubricating the plug from the outside must be introduced into the gas valve.

The plug has at least one gas passage opening which connects the outer surface of the plug with a hollow interior of the plug, and the outer surface is at least in the region of the gas passage opening of the rubber-elastic material educated. The gas flows with the gas valve open from the interior of the plug via the gas passage opening in the plug to an outlet channel in the valve housing. When the gas valve is closed, the plug is in a position in which the gas passage opening is closed by the valve housing. At least in the region of the plug in which the gas passage opening is located, the rubber-elastic material forms the outer surface of the plug.

Preferably, the plug has a plurality of gas passage openings which connect the outer surface of the plug with a hollow interior of the plug, and the outer surface is formed in the region of the gas passage openings of the rubber-elastic material. The plurality of gas passage openings allow a stepwise adjustment of the opening cross section of the gas valve. Each of the plurality of gas passage openings has a relatively small cross section, which is smaller than the cross section of the gas passage opening of a chick with a single gas passage opening. Accumulation of grease in the small gas passages affects the operation of one gas valve with a multiple chick

Gas passage openings particularly strong. When using oil as a lubricant or when using a self-lubricating silicone, the lubricant does not affect the operation of the gas valve. A gas valve with a plurality of gas passage openings is described for example in the post-published patent application with the application file PCT / EP2008 / 058605.

According to another preferred embodiment, the plug has at least one gas passage opening, which connects the outer surface of the plug with a hollow interior of the plug and is connected in the region of the outer surface of the plug with a channel, which is designed as a recess of the outer surface of the plug. Such a gas valve is described in the post-published patent application claiming priority EP07360051.2. The channel begins at the gas passage opening and extends as a depression along the surface of the plug. The channel serves to increase the rotational angle range of the plug, in which a gas passage through the gas valve is made possible. The flow resistance for the gas can be finely adjusted. An accumulation of grease in the channel particularly affects the operation of such a gas valve. When using oil as a lubricant or when using a self-lubricating silicone, the lubricant does not affect the operation of the gas valve.

With particular advantage, the channel extends at least over a quarter of the circumference of the plug. The operator can thus continuously adjust the power of the gas burner over a rotation angle range of more than 90 degrees.

According to a possible embodiment, the chick in the region of the at least one gas passage opening on a metallic core, on which the outer surface of rubber-elastic material is applied. The metallic core forms the bearing component of the plug and serves for torque transmission. The rubber-elastic material is applied to the core and may have a thickness of between a few tenths of a millimeter to a few millimeters.

The chick may in this case have a metallic axis, which forms a common component with the metallic core. The axle protrudes from the chick receiving opening. The axle may be directly or indirectly connected to a knob with which an operator turns the chick. The axis can be made in one piece or in several parts. In the case of a multi-part design, the parts of the axle may be movable in the axial direction relative to each other.

If the chick has a completely made of rubber-elastic material area is located in this area no metallic core. The chick has here a metallic axis, which adjoins in the axial direction of the completely made of rubber-elastic material area. The completely made of rubber-elastic material area and the metallic axis are rotatably connected.

The chick may have a conical shape or a cylindrical shape.

Further advantages and details of the invention will be explained in more detail with reference to the embodiment shown in the schematic figures. It shows

Figure 1 shows a first embodiment of a gas valve according to the invention FIG. 2 shows a plug of the gas valve according to FIG. 1

Figure 3 shows a second embodiment of a gas valve according to the invention Figure 4 is a gas valve with a chick with metallic core and a

Outer surface of rubber-elastic material

Figure 5 shows a chick, which is made entirely of rubber-elastic material in a large area.

FIG. 1 shows a gas valve 10 in a side view. The gas valve 10 is provided for providing a gas flow for a gas burner of a gas hob or a gas oven. The gas valve 10 has a valve body 12, which is cuboid in the present embodiment and in which

Outlet channels 14 are arranged for the passage of gas. Formed on the valve body 12 are an inlet opening 16 for the flow of gas into the gas valve 10 and a gas outlet 18 for the outflow of gas to the gas burner. On an upper, in an application an operator facing side 20 of the valve body 12, a guide member 22 is arranged, which receives an adjustment (not shown) for manually adjusting a gas flow. The gas valve 10 further has a cone-shaped chick 24 in the present example. The chick 24 is rotatably supported relative to the valve body 12 in a chick receiving opening. It is also sleeve-shaped and has a hollow interior 26. Gas can flow from the inlet opening 16 via the hollow interior and via the outlet channels 14 to the gas outlet 18. For this purpose, the chick 24 is provided with one or more gas passage openings (see FIG. 2 or 3), which permit a stepless or stepwise adjustment of the gas flow rate by means of a rotary movement of the chick 24.

FIG. 2 shows the chick 24 in a perspective view. The various gas passage openings 50, 52, 54 of the plug 24 connect the hollow interior 26 of the plug 24 with an outer surface of the plug. When the plug 24 is inserted into the plug receiving opening of the valve body 12, the gas passage openings 52 correspond to the outlet channels 14, given the corresponding position of the plug 24. FIG. 3 shows a second embodiment of the gas valve 110, which essentially has a valve body 112 and a plug 124. In the valve body 1 12 a chick receiving opening 102 is formed, which has the smoothest possible inner wall. Through the valve body 112, an outlet channel 114 leads from the chick receiving opening 102 to a gas outlet, not shown, in order to be able to conduct gas thereon.

Further, there is a channel 106 formed in the outer surface of the plug 124. The channel 106 thereby leads only a limited depth into the wall material of the plug 124 and does not extend to the hollow interior 126. At one end of the channel 106 is connected to a gas passage opening 105 so that gas from the gas passage opening 105 into the channel 106 can flow.

The chick 124 is rotatable about a rotation axis z as a rotation axis of the chick receiving opening 2 in a predetermined rotation angle range about the rotation axis z. In the axial direction of the axis of rotation z, the channel 106 is in a height range of the outer surface of the plug 124, which is covered in dependence on the angular position of the plug 124 of the outlet channel 1 14 in the valve body 101. As a result, a gas flow between the gas passage opening 105 and the outlet channel 1 14 already arise when only the channel 106, but not already the gas passage opening 105 is disposed opposite the outlet channel 114.

The greater the distance of the outlet channel 1 14 from the gas passage opening 105, the lower is the gas flow rate due to the throttling effect of the channel 106.

In both above-described embodiments according to Figures 1 and 2 and according to Figure 3 is provided as a lubricant between the chicks 24, 124 and the valve body 12, 112 according to the invention an oil. When using oil as a lubricant, a narrowing of the gas passage openings 52 or the channel 106 is avoided by the lubricant. In question is the use of mineral, synthetic and / or vegetable oils as a lubricant. FIG. 4 shows a further aspect of the invention, which can likewise be used for both embodiments according to FIGS. 1 and 2 as well as according to FIG. According to the invention, an outer surface 80 of the plug 24, 124 is formed by a self-lubricating silicone. The silicone contains oil as a lubricant. It is already introduced into the silicone during the polymerization and is stored in the silicone. On the surface, the oil exits in a small amount from the silicone and forms a lubricating film 81. The outer surface 80 of self-lubricating silicone is applied in the example of FIG. 4 on a metallic core 82 and fixedly connected thereto. The core 82 merges into a metallic axis 83, at which the chick 24, 124 can be rotated.

Another aspect of the invention is illustrated graphically in FIG. This design can also be used for both embodiments according to FIGS. 1 and 2 as well as according to FIG. The chick 24, 124 is executed here in a large portion of completely rubber-elastic material. The rubber-elastic material extends from the hollow interior 26 to the outer surface 80. A metallic axis 83 is fixedly connected to the rubber-elastic material at the upper end in the drawing. As a rubber-elastic material is for example silicone into consideration, preferably also in an embodiment as a self-lubricating silicone.

Claims

1. Gas valve (10, 1 10) for a gas-operated cooking appliance, with a valve body (12,

112) having a chick receiving opening and a chick (24, 124) rotatably disposed in the chick receiving opening and having an outer surface (80) at least partially made of a rubber elastic material, characterized in that the rubber elastic material of a self-lubricating silicone is formed.

2. Gas valve (10, 1 10) for a gas-operated cooking appliance, with a valve body (12,

112) having a chick receiving opening and a chick (24, 124) rotatably disposed in the chick receiving opening and having an outer surface (80) at least partially made of a rubber elastic material and facing the chick receiving opening of the valve body (12, 12; 112) is lubricated by means of a lubricant, characterized in that as

Lubricant an oil is provided.

A gas valve (10, 110) for a gas powered cooking appliance, comprising a valve body (12, 112) having a plug receiving opening, and a plug (24, 124) rotatably disposed in the plug receiving opening and having an outer surface (80). comprises, which is at least partially made of a rubber-elastic material, characterized in that the chicks (24, 124) at least in a portion of the outer surface (80) to a hollow interior (26) facing inner surface made entirely of the rubber-elastic material is.

4. Gas valve (10, 1 10), characterized by a combination of claims 1 and 2 or by a combination of claims 1 and 3 or by a combination of claims 2 and 3 or by a combination of claims 1, 2 and 3.

5. Gas valve (10, 1 10) according to claim 2, 3 or 4, characterized in that a silicone is provided as the rubber-elastic material.

6. Gas valve (10, 1 10) according to claim 1 or 4, characterized in that for lubrication of the plug (24, 124) relative to the valve body (12, 112) provided oil is completely contained in the self-lubricating silicone.

7. Gas valve (10, 1 10) according to one of claims 1 to 6, characterized in that the chick (24, 124) at least one gas passage opening (52, 105), which the outer surface (80) of the plug (24, 124 ) with a hollow interior of the plug (24, 124) connects, and the outer surface (80) is formed at least in the region of the gas passage opening (52, 105) of the rubber-elastic material.

8. Gas valve (10) according to any one of claims 1 to 6, characterized in that the plug (24) has a plurality of gas passage openings (52) which surrounds the outer surface (80) of the plug (24) with a hollow interior of the plug (24). connect, and the outer surface (80) in the region of the gas passage openings (52) is formed of the rubber-elastic material.

9. Gas valve (110) according to one of claims 1 to 8, characterized in that the plug (124) has at least one gas passage opening (105) which surrounds the outer surface (80) of the plug (124) with a hollow interior of the plug (124 ) and in the region of the outer surface (80) of the plug (124) with a channel

(106), which is designed as a depression of the outer surface (80) of the plug (124).

10. Gas valve (110) according to claim 9, characterized in that the channel (106) extends at least over a quarter of the circumference of the plug (124).

11. Gas valve (10, 1 10) according to one of claims 7 to 10, characterized in that the plug (24, 124) in the region of the at least one gas passage opening (52, 105) has a metallic core (82), to which the Outside surface (80) made of rubber-elastic material is applied.

12. Gas valve (10, 1 10) according to claim 1 1, characterized in that the plug (24, 124) has a metallic axis (83) which forms a common component with the metallic core (82).

13. Gas valve (10, 1 10) according to any one of claims 3 to 10, characterized in that the chick (24, 124) has a metallic axis (83) extending in the axial

Direction connected to the completely made of rubber-elastic material area.

14. Gas valve (10, 1 10) according to one of claims 1 to 13, characterized in that the plug (24, 124) has a conical shape.

15. Gas valve (10, 1 10) according to one of claims 1 to 13, characterized in that the plug (24, 124) has a cylindrical shape.