NO133512B - - Google Patents

Description

The present invention relates to a nozzle device for a lighter with liquefied gas, which lighter uses a piezo-electric element, where the device has at least two air-communicating cylindrical bodies, where the respective bodies are separated from each other and extend in a largely parallel relationship to each other.

Different types of lighters with liquefied gas using a mechanical-electrical element have been proposed. Such a known lighter with liquefied gas is usually arranged so that the piezoelectricity generated by the reset of the plus and minus electrons in the crystal mass of the mechanical-electric element as a result of a percussion shock applied to this is caused to give a spark discharge between the point the electrode and the nozzle so that the fuel gas that is sprayed out from

the nozzle is ignited by this spark. However, the lifetime of this electrical spark thus generated as the piezoelectric element receives a shock is quite short in duration. Furthermore

the heat energy of this spark discharge is likewise small. For these reasons, the fuel gas that is sprayed out from the nozzle of conventional liquid gas lighters has often failed to ignite as desired and thus the ignition condition or the ignition speed of these known liquid gas lighters has been far from satisfactory.

This fault condition during ignition can be attributed to the fact that the fuel gas sprayed out from the nozzle is not sufficiently mixed with the surrounding air. To overcome this condition, various proposals have been made to improve the state of mixing of fuel gas with ambient air by modifying the design and configuration of the nozzle. Such previous proposals include a device where the nozzle is provided with a secondary gas spray opening in addition to the main nozzle opening, or a device in which an air-communicating cylindrical member is mounted on the edge of the nozzle, or a device that a damper device (damper device) is provided above the nozzle. However, such earlier devices were found to be still unsatisfactory with respect to ignition speed. Accordingly, recent proposals represent devices intended to extend the duration of the ignition discharge and thereby improve the ignition speed by introducing in series a resistance between the piezoelectric element and the discharge electrode.

Thus is the most widely used construction of lighters

with liquefied gas using a mechanical-electrical element that is commercially available now, of the device comprising, in combination, a known nozzle construction that can improve the mixing state of the fuel gas and the surrounding air, and a device that is intended to extend the duration of the discharge by means of the action of an inserted resistance.

However, such a lighter with liquid gas has the disadvantages that

it naturally leads to an increase in its production costs

• and at the same time to a complication of the nozzle construction as well as a significant difficulty in the production of a material for parts of small size such as the nozzle for the lighter.

It is therefore a primary object of the present invention

to eliminate the disadvantages of previous nozzles for liquid gas lighters.

Another object of the invention is to provide a new and simple device for the nozzle for lighters with liquid gas, which ensures an improved, light and satisfactory mixture of fuel gas with surrounding air.

A further object of the present invention is to provide an improved nozzle device of the type described which provides an improved satisfactory ignition speed without

to require the acquisition of some additional device, such as a resistor to extend the duration of the electrical discharge as was done in the prior art between the piezo-electric element and the discharge electrode arranged to face the nozzle.

Yet another object of the present invention is to provide an improved device of the type described above, which is simple in construction, easy to assemble and low in manufacturing cost.

The mentioned disadvantages are overcome and the mentioned purposes are fulfilled by

the initially stated device, which is characterized by the fact that one of said bodies is arranged in the bore in said nozzle and constitutes an extension part past the open end of said nozzle, and that the other of said bodies is mounted on the outer circumference of said nozzle and has an extension member extending past the open end of said nozzle.

The device according to the invention has at least two air-communicating organs which are able to provide a better mixture of gas and air than is possible with only one organ.

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By arranging several organs according to the invention, the volume of gas emitted from the openings in the organs becomes proportional to that emitted from a main nozzle and furthermore the volume of gas emitted from a nozzle device is greatly influenced by the variation in ambient temperature, whereby the volume changes greatly degree. In the case of a device with only one organ, it is impossible to regulate the volume, while with two or more organs it is possible to regulate the volume and thereby a volume of undergas for use in underignition can always be kept largely even so that constant stable ignition is ensured, without some influence of temperature, by a low-energy spark from piezo-electric elements.

According to a preferred embodiment of the invention, the aforementioned members are made of spiral springs.

Further features of the invention will be apparent from the following patent claims as well as from the following description with reference to the drawings. Fig. 1 is a longitudinal sectional view of an embodiment of the present invention. Fig. 2 is a corresponding drawing representing another modified embodiment. Fig. 3 is a corresponding drawing representing yet another modified embodiment. Fig. 4 is a corresponding view of yet another modified embodiment.

It will be understood that these drawings are given by way of examples only and that they must not be considered to limit the invention thereto.

As a result of extensive experiments, the inventor has arrived

that the most economical and easy way to accomplish the purposes of the present invention is to use at least two cylindrical pieces of spiral springs made of stainless steel, one of which is smaller both in diameter and pitch of the spiral turns and is shaped so as to be narrowly arranged in the bore of the cylindrical nozzle part, while it extends a few millimeters beyond the edge of the nozzle and the other is larger both in diameter and in the pitch of the screw-wound turns and is thus shaped so as to narrowly surround the outer circumference of the nozzle while extending a few millimeters beyond the edge of the nozzle. These two bodies are placed on the nozzle in a separate parallel relationship with respect to each other via the wall of the nozzle.

The reason for the use of these spiral pieces is, for one thing

that they are readily available on the market and are cheap, and that they are easily mounted on the cylindrical nozzle. The size of these spring members can vary according to what is necessary to adapt the size of the nozzle used. The nozzle part is manufactured to provide shoulders or step portions on the inner as well as on the outer sides of the nozzle on which the lower ends of the spiral members are to be supported. For lighters of ordinary size with liquefied gas which have a nozzle with a thickness of 0.4 mm for the nozzle wall, for example, the inner spiral member has a diameter of approximately 1.2 mm with clearances of plus 0 mm and minus 0.05 mm in case the spiral member is made with a thread of 0.18 - 0.25 mm, preferably 0.2 mm, in diameter, and a pitch of the spiral turns of such a spiral piece is about 0.06 - 0.02 mm, preferably 0.05 - 0.03 mm and the length of the part of this spiral means which extends past the upper uncovered edge of the nozzle is 1^5 - 3.0 mm, preferably 2.0 mm. On the other hand, the outer spiral member preferably has an outer

diameter of 2.0 mm, with an opening of 0.08 - 0.12 mm, preferably 0.1 mm between the respective turns and extending a distance of 1.5 - 3.0 mm beyond the upper uncovered edge of the die. There may be a difference between the outstanding lengths of these inner and outer members 4 and 5 within the range of Ot-1.0 mm. An excessively large difference in the lengths of projection will cause the spiral pieces to be placed in such a place where they are exposed to the highest temperature region of the burner flame, and the spiral pieces could burn up. Likewise, the distances between the inner and outer members 4 and 5 are equal to 0.15 - 0.25 mm, preferably 0.2 mm.

In conventional liquefied gas lighters using a piezoelectric element and having no nozzle device as in the present invention, the most effective distance between the end of the discharge electrode and the nozzle serving as the cathode to ensure good ignition condition is usually 3, 0 mm.

This positional relationship between the two requires precise technical skill to ensure their precise placement. According to the present invention, however, the assembled coil spring pieces greatly alleviate this manufacturing difficulty as the mixed streams of fuel gas and air flow outward and upward from the many openings formed between the turns to easily catch the spark.

As will be understood by those skilled in the art, these spiral members may be replaced by perforated cylindrical members, wherein the inner member has several perforations smaller in size than those of the outer member. However, the use of perforated cylindrical members will require an additional step when punching out a plate material and consequently this will increase the manufacturing cost. In contrast to this, the spiral members used in the present invention are already available on the market and naturally the production costs can be reduced as a result of this by using such spiral threads. Alternatively, the spiral members may be replaced by pieces of wire mesh, the inner member having meshes smaller than those of the outer member or members.

With reference to fig. 1 shows the first embodiment

of the nozzle device according to the present invention. A familiar one

nozzle member 1 is mounted to the upper end part of a fuel container which is not shown and its bore is in connection with the space in the container. This nozzle member 1 is equipped with a bore 2 which is formed centrally longitudinally in it to allow the fuel gas* to pass through it. This bore 2 opens at its upper end to provide an opening for the gas to spray into the air. The upper part 3 of this bore 2

is formed to have a diameter which is only slightly larger than that of the remaining part.- A first air-communicating cylindrical member 4 which will be described in detail later, is received in said part 3 of the bore 2 and which has a larger diameter of a in such a way that this air-communicating cylindrical member 4 is supported at its base on a shoulder 6 and extends longitudinally in relation to the nozzle member 1 i. a set length - 0.2 mm in this example - past the open tip la of the nozzle member 1 i parallel to the longitudinal

end wall of this part of the bore 2. A second air-communicating cylindrical member 5 is mounted on the second circumference of the nozzle member 1. The bottom of this second air-communicating cylindrical member 5 is supported on a shoulder 7 of an outer enlarged part 1b of this nozzle member 1. This second air-communicating cylindrical member 5 also extends the same distance past the open tip la of the nozzle member 1 as the first similar member 4 with this part of the nozzle member 1 and in parallel with the first member 4 with a small space from this inner member 4, where said space corresponds essentially to the width of the wall at the upper end of the nozzle member 1.

The first and second air-communicating cylindrical bodies 4 6g 5

are formed with two pieces of cylindrical coil springs differing from each other in diameter and size, considering their easy availability in the market. The first member 4 has air-communicating openings which are smaller than those of the second member 5. In this first example, the first or inner air-communicating cylindrical member 4 is equipped with a piece of coil spring made of a stainless steel wire which has a diameter of 0.2 mm, with air-communicating openings consisting between the respective spiral turns which are 0.05 mm and pitch which is 0.25 mm.

On the other hand, the second or outer air-communicating cylindrical member 5 is equipped with a piece of spiral spring made of the same stainless steel wire having a diameter of 0.2 mm, where air-communicating openings of 0.1 mm exist between the respective spiral turns for the spiral, and a pitch of 0.3 mm.

Let us now assume that the liquefied gas lighter having a nozzle device as described above is operated in a known manner to ignite the fuel gas which is sprayed in through the bore 2 in the nozzle member 1. The fuel gas stream emerging under pressure from the bore 2 is first partially branched to pass through the openings existing between the respective helical turns of the first air-communicating cylindrical member 4 to flow in the space between the first member 4 and the second air-communicating cylindrical member 5. The gas streams thus flowing through this spaces are further divided as they pass through the corresponding openings in the second member 5 to flow to the outside thereof. Thus, the pressure of the gas streams that this gas had when it was initially sprayed out of the opening of the nozzle 1 is reduced as it is first divided into a number of streams when it passes through a plurality of openings of the first member 4 and again after as they already divided gas streams are further divided when they pass through the large number of openings in the second member 5. During the previously mentioned step-wise movements of the fuel gas, the amount of the gas streams sprayed through the openings of the second member 5 is reduced to a significant extent by these two air-communicating cylindrical members 4 and 5 being split. As a result of this, the fuel gas flowing on the outside of the second member 5 in a majority of flows is mixed with the surrounding air in a very desirable ratio for combustion and thus an ideal state of gaseous form in mixture suitable for to be ignited by a faint spark. Therefore, such a mixture of the fuel gas and the air is unfailingly ignited by a discharge spark which takes place between the discharge ■ electrode A electrically connected to the piezoelectric element not shown and placed to face the nozzle member 1 and the other or the outer air-communicating cylindrical member 5. thus the nozzle arrangement according to the present invention completely eliminates the need to extend the duration of the discharge spark which is effected by the provision of a resistor as has been done in the prior art.

The nozzle device according to the present invention is simple in construction, i.e. at least two air-communicating cylindrical members 4 and 5 are only mounted on both sides of the wall for the nozzle without the need for a resistor, so that this nozzle device can be produced in a fairly simple manner and at a low price. Even when the space between the two bodies 4 and 5 is blocked by dust for one reason or another during use, such dust will be completely burned away and no blocking of this space will occur.

Another example of the nozzle device according to the present invention is shown in fig. 2. The only difference between the first example as shown in fig. 1 can be found in that the outer member 5 extends to such an extent that its free upper end is located at a certain distance, i.e. up to 1.0 mm past the free upper end of the first or inner member 4. In such part of the outer member 5, the part of the fuel gas which is ejected from the upper end of the inner member 4 enters the openings of the second member 5 which is placed in said part where the spiral turns thereof have an inner diameter which is larger than the outer diameter of the inner member 4, and opposes the secondary streams of fuel gas which go up 1 the space between the two members 4 and 5. In this way, absolutely all the streams of fuel gas are caused to make a quite uniform upward current as a whole so that the unwanted pulsating flame and the blowing out of the flame due to the pressure of the jet stream but of the fuel gas, which often occurred with lighters with liquid gas in the prior art, both are perfectly eliminated, and thus a desirable normal flame can be obtained.

Yet another example of the nozzle device according to the present invention is shown in fig. 3. In this example, the first or inner spiral piece 4 extends further than the second or outer spiral piece 5. The gas that is sprayed out from the opening of the bore 2 is divided into three streams, i.e. the first stream rises through the loop in the first ogran 4, the second stream rises through the space between the first and second spiral pieces 4 and 5, and the third stream flows to the outside of the second spiral piece 5. This third stream is sufficiently reduced in terms of its flow rate and pressure as it passes through the space between the first and second spiral pieces 4 and 5, so that on the outside of the second spiral piece 5, the gas volume mixes well with air to provide a condition that is quite easily ignited by the weak spark as in the previous examples.

Moreover, the aforementioned first gas stream is positively directed upwards

by means of the extension 4a of the first spiral piece 4, and the flame from the nozzle opening is extended and of a reduced diameter. Thus it is, even in the case where the distance between the upper

the end of the nozzle and the upper end of the first spiral piece 4 is substantially large, certainly to achieve an effective flame length that extends past the upper end of this first spiral piece 4. Furthermore, the first gas stream flows on the outside of the part of the extension 4a through the openings present therein to form around this extension 4a a thick fuel gas region.

However, such a thick fuel gas region will make it difficult for the discharge spark to pass through said region.

Therefore, according to the present invention, the electric spark is passed through another region where the third gas drum is present, and the mixture of gas and air is ignited in this last-mentioned region. Thus, a non-failing ignition can be expected. The description has been directed towards examples where the nozzle device comprises two inner and. external air-communicating cylindrical bodies,. The present invention is not limited to the use of such double air-communicating cylindrical bodies, but can also apply

the majority of such bodies.

As shown in fig. 4, three air-communicating cylindrical members, 4, 5 and 10 are supported on respective shoulders 6, 7 and 8, respectively, so as to extend upwards in separate parallel relationships, where one of these, namely the inner member 4, is inserted in the enlarged part of the bore 2. The free ends of the parts of the extension of these three bodies 4, 5 and 10 can be aligned or they can be parallel-displaced in position relative to each other as shown e.g. in fig. 4. In each of these cases, the user of the lighter can achieve the same desired ignition of the fuel gas.

Claims (8)

11 Nozzle device for a lighter with liquefied gas, which lighter uses a piezo-electric element, where the device has at least two air-communicating cylindrical members, where the respective tive bodies are separated from each other and run in a largely parallel relationship to each other, characterized in that one of said bodies is arranged in the bore in said nozzle and constitutes an extension part past the open end of said nozzle, and that the other of said bodies is mounted on the outer circumference of said nozzle and having an extension portion extending past the open end of said nozzle. 2. Nozzle device as specified in claim 1, characterized in that said extension part of the body which is located in the bore of the nozzle is greater in length than the part or parts of the extension of the body or bodies which are mounted on the outer circumference of the nozzle. 3. Nozzle device as stated in claim 1, characterized in that said extension part of the body which is located in the bore of the nozzle is smaller than the part or parts of the extension of the body or bodies which are mounted on the outer circumference of the nozzle. 4. Nozzle device as specified in claim 1, characterized in that the free ends of the extension parts of the respective organs are arranged in the same height position. 5. Nozzle device as stated in claim 1, characterized in that the free ends of the extension parts of the respective organs are parallel shifted in position in relation to each other. 6. Nozzle device as set forth in one of claims 1-5, characterized in that the respective air-communicating cylindrical bodies are made of spiral springs that are not flammable, of which springs the innermost has openings between their respective spiral turns that are smaller than those of the other organs. 7. Nozzle device as stated in one of claims 1-5, characterized in that the respective air-communicating cylindrical bodies are made of pieces of wire mesh that are not flammable, of which the innermost mesh has a mesh opening that is smaller than those of the other bodies. 8. Nozzle device as set forth in one of claims 1-5, characterized in that the respective air-communicating cylindrical bodies are made from pieces of a perforated plate material that is not flammable, of which material the innermost part has perforations that are smaller in size than those for the other organs.