The embodiments of the present invention relate to gas lighter, particularly a disposable gas lighter or gas reservoir for any type of lighter.
More precisely, the embodiments of the present invention relates to a device and a method for facilitating the operations of filling and sealing of the lighter. More particularly the present invention relates to a disposable lighter or a gas reservoir for all types of lighter of the type which comprises a reservoir made of plastic material, especially amorphous plastic, adapted to be filled with a liquid hydrocarbon, especially butane or mixtures of butane and other hydrocarbons.
Synthetic amorphous materials, like polymers such as ABS (Acrylonitrile Butadiene Styrene) or polycarbonate, often used for disposable gas lighters, are advantageous since they allow users to see the level of remaining fuel within the reservoir. However, such amorphous materials may be brittle as a result of their non-crystalline structure.
It is known in the art to arrange a well in the bottom of the reservoir and to insert a ball into the well. However, the force-fit introduction of the ball within the well can cause cracks in the well of the reservoir and thus create a leakage.
Other methods rely on the use of an 0-ring seal; however the cost effectiveness of such solutions is poor with regard to a definitive sealing feature.
U.S. Pat. No. 4,486,171 describes a method using a plug member molded integrally with the lighter body. This plug allows the filling of the body but the final closing and sealing of the reservoir is provided by the dispensing valve. Since such valve is force-fitted into the well, the risk of causing cracks remains.
There is therefore a need to improve known solutions relating to the operations of filling and sealing a transparent disposable gas lighter.
To this end, it is provided a sealing assembly, enabling to fill and seal a reservoir of a disposable gas lighter, comprising
wherein the plug is adapted to be moved from a first axial position in which a passage is provided between an inner portion of the reservoir and outside, to a second axial position (P2) providing a temporary seal position in which a gastight contact is provided between the circular bulge portion of the plug and the inner wall of the well, and further from the second position to a third axial position (P3) providing a definitive seal position, wherein the weld portion of the plug is welded to the reservoir in a gastight manner.
Thanks to these dispositions, it is possible to obtain an inexpensive and reliable solution to seal the reservoir of a disposable gas lighter or a gas reservoir for any type of lighter.
Further, the operations of filling and sealing can be combined to provide an optimized industrial process.
In various embodiments of the present invention, one may possibly have recourse in addition to one and/or other of the following arrangements:
The embodiments of the present invention also relates to a method to fill and seal a reservoir of a disposable gas lighter, wherein the reservoir has a substantially cylindrical well having an axis X and an inner wall, the method that includes:
/A/—providing a plug in the well, arranged in a first axial position, the plug having a front section and a rear section, the front section comprising at least one recess to provide a fluid passage, the rear section having at least a circular bulge portion and a weld portion adapted to be melted by welding,
/B/—filling the reservoir with a supply of fuel, the fuel flowing into the reservoir through the fluid passage,
/C/—pushing the plug into a second axial position wherein the circular bulge portion bears against the inner wall of the well thereby providing a provisional gastight contact,
/D/—welding the plug into the well to result in a third axial position to form a definitive gastight seal.
In various embodiments of the method, one may possibly have recourse in addition to one and/or other of the following arrangements:
Other features and advantages of the invention appear from the following detailed description of one of its embodiments, given by way of non-limiting example, and with reference to the accompanying drawings, in which:
In the figures, the same references denote identical or similar elements.
In the bottom portion 12, there is provided a well 3. This well 3 extends along a longitudinal axis X, and exhibits a substantially cylindrical shape with an inner wall 30 and en edge portion 31; the latter being disposed in a recess 11 larger than the cylindrical well 3. The recess 11 may have various shapes, partly beveled or straight; in the illustrated example the recess comprises a beveled mouth 14 having a frusto-conical shape. Since the well is disposed within this recess 11, the well area stands back from the bottom surface of the bottom portion 12, which provides a natural mechanical protection.
The well area is molded integrally with the lighter body 1. The lighter body and therefore the well portion could be made of a non-crystalline resin, for example styrene acrylonitrile, ABS, or polycarbonate; this kind of material has the advantage of being transparent, so that it is possible to see the remaining level of liquid within the reservoir; further this kind of material is also inexpensive. The invention is not limited to transparent material, it can also be used with opaque non-crystalline materials or crystalline materials.
The well 3 provides a fluid communication between the interior space 13 of the reservoir and the exterior. After the fitment of at least the dispensing valve on the top of the lighter body, the well 3 is used to fill the reservoir with a liquid fuel comprising hydrocarbons, especially butane or mixtures of butane and other hydrocarbons. The diameter of the well can be small, for example comprised between 1 mm and 3 mm.
The fill operation is performed with the help of an injection nozzle 7 connected to a fuel external supply (not shown). The injection nozzle 7 has a beveled edge 74 complementary with the beveled mouth 14 in the bottom of the reservoir. In order to perform the fill operation, the injection nozzle 7 is brought to bear on the above mentioned beveled mouth 14 (as illustrated in
Further, there is provided a plug 2 intended to be received in the well and intended to close the well 3 after the fill operation. More precisely, as shown on
The material of the plug can be identical to the material of the reservoir; however it can also be a different type of resin or plastic material, not necessarily transparent, provided that the temperature melting point is not very different from the temperature melting point of the reservoir material, to favour a good welding capability as explained later.
One advantage to select an opaque material is to allow an optical automated check of the presence of the plug during the automated assembly process.
The plug material is not completely rigid, it exhibits a certain compressibility to allow deformation.
The front section 21 comprises radial projections 41 and at least one recess 4 to provide a fluid passage F between radial projections 41. The radial projections 41 are circumscribed in a circle having a diameter D1 slightly larger than the internal diameter D of the well. In the depicted example, there are provided three radial projections 41 delimited by three recesses 4.
The rear section 22 has a circular bulge portion 5 providing a circular bearing having a diameter D2 slightly larger than the internal diameter D of the well, and a weld portion 6 adapted to be melted by welding as it will be explained in details below. Further, it is provided an end portion 28 disposed transversely at the back of the rear portion 22.
Before the insertion into the well, the plug 2 may be positioned in an axial preliminary position indicated by PO (dashed line in
In this first position P1, the well is not closed, indeed the recesses 4 arranged between radial projections 41 provide a fluid passage denoted F to allow the subsequent filling operation.
Thereafter, the above described injection nozzle 7 is applied to the beveled mouth 14, and liquid fuel is injected into the reservoir. When the prescribed quantity has been introduced in the reservoir, which can be determined by various means, a pushing rod 8 provided in the center of the injection nozzle 7 is moved upwards to move the plug 2 from the first position P1 to a second axial position denoted P2 (
It is to be noted that the movement of the front end 82 of the pushing rod 8 can be controlled by the force exerted or by displacement range. Thus, only the bulge portion is inserted in the well and not the weld portion 6 which abuts on the edge portion 31 of the well.
While the second position P2 provides a temporary seal position, there can be performed functional testing of the lighter if required, and/or the lighter can be moved to another assembly station.
More precisely, the diameter D2 of bulge portion 5 at rest can be chosen between 101% and 105% of the inner diameter D of the well. The radial compression stress of the bulge portion 5, added to the radial compression stress of the radial projections 41, provide a sufficient retention force against the action of the internal pressure prevailing in the reservoir after filling.
When the condition to definitively seal the reservoir is obtained, a definitive seal operation is undertaken. To this end, in the illustrated example, an ultrasonic sonotrode 9 with a front end 92 is applied to the back portion 28 of the plug 2. The ultrasonic sonotrode 9 simultaneously applies axial and transverse vibrations while pushing the plug 2 toward a third axial position P3 shown in
It is to be noted that other welding solutions are not excluded within the scope of the invention.
Although the plug 2 is supplied as a separate part in the illustrated preferred embodiment, it is also possible to have the plug integrally molded with the reservoir, the two parts possibly linked together by a breakable link.
Advantageously, the front portion 21, the bulge portion 5 and the weld portion 6 are arranged axially next to one another, to result in an axial overall dimension of the plug smaller than 10 mm, preferably smaller than 5 mm. This forms a compact solution which does not trespass much on the volume of the reservoir.
Advantageously, the seal assembly described above is deprived of any intermediate part between the plug and the well, and deprived of any elastic member or biasing member.
In other words, the method to use the seal assembly described above comprises at least:
/A/—providing the plug 2 in the well, arranged in a first axial position (P1, filling position),
/B/—filling the reservoir with fuel flowing into the reservoir through the fluid passage 4,
/C/—pushing the plug into a second axial position (P2 temporary seal position) wherein the circular bulge portion 5 bears against the inner wall of the well thereby providing a provisional gastight contact,
/D/—welding the plug into the well 3 to result in a third axial position (P3, definitive seal position) to form a definitive gastight seal, preferably using an ultrasonic welding technique.
It should be noted that the bulge portion 5 can be dissymmetric and exhibit a shoulder shape. Further, the weld portion can be arranged in geometric continuity of the bulge portion. Moreover, the weld portion 6 can exhibit various forms not necessarily axisymmetric before welding.
It should be noted that the sealing assembly and methods described above can be used not only or a disposable gas lighter, but also for a reservoir of any kind of utility gas lighter.
This application is a national stage application of International Application No. PCT/IB2013/000534, filed on Mar. 5, 2013, the entire contents of which are incorporated herein by reference.
Filing Document | Filing Date | Country | Kind |
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PCT/IB2013/000534 | 3/5/2013 | WO | 00 |