KR100613219B1 - Gas lighter - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a gas lighter, wherein the gas is discharged through a tank enclosed by a cap so as to have an internal space filled with gas, and a nozzle mounted on a nozzle bottom passing through the cap, or the gas is discharged through the nozzle. In the gas lighter comprising a gas ejection adjustment mechanism provided in the cap and a spark ignition mechanism for generating a spark to ignite the gas ejected from the nozzle, the nozzle bottom has an outer diameter compared to other parts on the outer surface It has a small O-ring mounting groove continuously formed to have the same outer diameter from a predetermined position to one end, and the O-ring is mounted on the O-ring mounting groove in the through groove formed through the cap so as to connect the inside and the outside of the tank. It is characterized in that the installed nozzle bottom is installed in an airtight manner, and according to the simple structure, a certain amount of gas has a constant flow rate. This has the effect of being ejected to the outside.

Gas lighters, filters, auxiliary tanks, nozzles, adjustment

Description

Gas lighter

1 is a half sectional perspective view showing a gas lighter according to the prior art;

2 is an exploded perspective view showing a gas lighter according to the prior art;

3 is a detailed view showing the main portion of a gas lighter according to the prior art;

4 is a half sectional view showing a gas lighter according to an embodiment of the present invention;

Fig. 5 is a detailed view of the main part of Fig. 4;

Figure 6 (a) and (b) is a detailed view of the auxiliary tank of the gas lighter according to an embodiment of the present invention;

Figure 7 (a) and (b) is a detailed view of the auxiliary tank connector of the gas lighter according to an embodiment of the present invention;

8 is a detailed view showing main parts of a gas lighter according to another embodiment of the present invention;

FIG. 9 is a detailed view illustrating main parts of the modification of FIG. 8; FIG.

※ Explanation of symbols about main part of drawing ※

10: cap 20: nozzle bottom

22a: gas passage 30: nozzle tower

40, 41, 42, 43: filter 50, 51, 52: filter support

51a, 52a: gas passage 60: auxiliary tank connector

61: main body 61a: gas passage

62: extension portion 70: auxiliary tank

71: body portion 72: fitting portion

73: gas supply groove 81, 82: gas groove

100: tank 320A, 320B: nozzle bottom

321: O-ring 322A, 322B: O-ring mounting groove

330 nozzle 340 T-packing

420: Flint 440: Wheel

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a gas lighter, and more particularly, to a gas lighter which allows a certain amount of gas to be blown out at a constant flow rate by a simple structure.

In general, the gas lighter ejects the gas stored in the tank to the outside as needed and forms a flame using the ejected gas.

Figure 1 is a half sectional perspective view showing a conventional gas lighter, Figure 2 is an exploded perspective view, the upper opening of the tank 100 is sealed by the cap 200, and the gas to the cap 200 to eject or A gas ejection adjustment mechanism for blocking the ejection, and a ignition mechanism for providing a spark to the gas ejected from the tank 100 to form a flame.

The gas ejection adjustment mechanism includes a hollow cylindrical nozzle top 310 and a nozzle bottom 320, the upper end of the nozzle bottom 320 is fixed to the lower end of the nozzle top 310, such a nozzle top ( 310 and the nozzle bottom 320 are hermetically mounted to the through groove 210 formed to penetrate up and down on one side of the cap 200 via the O-ring 321.

In addition, a gas ejection nozzle 330 having a gas passage penetrating in the longitudinal direction is accommodated in the nozzle top 310 and the nozzle bottom 320 with an O-ring 332, and the nozzle 330 is The upper end is installed to penetrate the upper end of the nozzle tower 310 to be exposed to the upper side. In addition, the nozzle 330 is elastically supported downward by the nozzle spring 331, the T-packing 340 is installed at the lower end of the nozzle 330 serves to open and close the lower portion of the nozzle bottom 320. Perform.

In addition, the gas ejection adjustment mechanism is a filter 350 formed of a sponge material which is located under the nozzle bottom 320 and passes gas and has excellent resilience and restoring force, and is located below the filter 350 and has an upper end. A hose holder 370 having a T-disc 360 having protrusions formed at a center, a lower center, or a top and a lower center thereof, a gas passage disposed below the T-disc 360 and vertically penetrated therethrough; The hose 380 is hermetically coupled to the upper end of the hose holder 370. At this time, a protrusion is formed at the bottom of the through groove 210 of the cap 200 to protrude inwards, and the hose holder 370 is prevented from falling off by the protrusion.

The ignition mechanism is a flint case 410 is inserted into the cap 200 and fixed, a flint 420 mounted on the flint case 410 to be elastically supported upward by the spring 430 and to be movable up and down, The wheel 440 in close contact with the top of the flint 420 and rotatably mounted to the flint case 410, and one side thereof is coupled to the top of the nozzle 330, and a central portion thereof is connected to the flint case 410. And a lever 450 rotatably mounted.

In addition, the gas lighter includes a protective cap 500 for protecting the flame formed on the top of the nozzle 330, a male screw is formed on the outer surface of the nozzle tower 310 and penetrates the cap 200. A female thread is formed in the groove 210 to rotate the nozzle top 310 to move upward and downward relative to the cap 200. The nozzle top 310 has an upper end of the nozzle top 310. The flame adjuster 390 is rotated for mounting.

When the user presses the lever 450 downward while rotating the wheel 440 in the gas lighter having the above-described configuration, the spark ignition spark is generated from the flint 420 and the gas is ejected from the nozzle 330. The flame is generated at the top of the (330).

However, in the conventional gas lighter, the user directly adjusts the amount of gas ejected through the nozzle by rotating the nozzle tower 310 using the adjuster 390, which is inconvenient according to a user's operation for adjusting the amount of gas. And, when an excessive amount of gas is ejected according to the user's operation failure, not only the gas consumption is increased, but also the size of the flame is rapidly increased to have a problem for the safety of the user.

In addition, there is a problem in that the manufacturing process is complicated because a complicated structure for adjusting the size of the flame and the gas blowing is required, and accordingly, the manufacturing cost is increased.

In addition, the nozzle bottom 320 is manufactured by a die-casting casting method having a high precision, and as shown in detail in FIG. 3, the O-ring mounting groove 322 along the circumferential direction on the bottom outer surface of the nozzle bottom 320. Is mounted, and the O-ring 321 is fitted into the O-ring mounting groove 322. However, when the O-ring mounting groove 322 of the nozzle bottom 320 is manufactured by die casting by a casting mold paired with a semi-circular hole, the O- ring mounting groove 322 at the position corresponding to the boundary of the casting mold is formed. The surface of the ring mounting groove 322 has a portion that protrudes slightly to the outside, this protrusion portion prevents the O-ring 321 from being in close contact with the O-ring mounting groove 322 (the O-ring ( A small gap is formed between the 321 and the O-ring mounting groove 322, which causes a problem of gas leakage. In addition, in the post-processing process of precisely trimming the O-ring mounting groove 322, a fine metal material generated during processing remains on the surface of the O-ring mounting groove 322, so that the O-ring 321 is O- In addition to still being in close contact with the ring mounting groove 322, there was also a problem of cost increase and productivity decrease due to post-processing.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described problems, and an object of the present invention is to provide a gas lighter in which a certain amount of gas is blown out at a constant flow rate by a simple structure so that flame control by a user is unnecessary.

In addition, the present invention by changing the O-ring mounting structure of the nozzle bottom to make the O-ring mounting portion with a high-precision die casting casting method that does not require additional processing, gas leakage is prevented, cost reduction and productivity can be improved Another object is to provide a gas lighter that is intended to be.

As a technical configuration for achieving the above object, the present invention, the tank is sealed by a cap to have an internal space filled with gas, and the gas is ejected through a nozzle mounted to the nozzle bottom through the cap or A gas lighter comprising a gas ejection adjusting mechanism provided in the cap to block gas ejection through a nozzle, and a ignition mechanism generating spark to ignite the gas ejected from the nozzle, wherein the nozzle bottom is disposed on an outer surface. O-ring mounting groove formed continuously to have the same outer diameter from a predetermined position to one end while having a smaller outer diameter than other parts, and an O-ring in a through groove formed through the cap to connect the inside and the outside of the tank. It is to provide a gas lighter, characterized in that the nozzle bottom is installed in the mounting groove is air-tightly fitted O-ring.

The O-ring mounting groove may be continuously formed from the upper end of the nozzle bottom to a predetermined distance or continuously formed from the lower end of the nozzle bottom to a predetermined distance.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 4 is a half sectional view showing a gas lighter according to an embodiment of the present invention, Figure 5 is a detailed view showing the main portion of Figure 4, the same as the reference numerals of Figures 1 to 3 for the same components as the prior art It is to be noted that detailed description of these components is omitted.

The gas lighter of the present embodiment may be configured to eject the gas through or to block the gas ejection through the nozzle through a tank sealed by a cap to have an inner space filled with gas, and a nozzle mounted on the nozzle bottom passing through the cap. And a ignition mechanism for generating a spark to ignite the gas ejected from the nozzle, and the schematic configuration is similar to the conventional gas lighter shown in Figs. .

The cap 10 has a through groove 12 penetrating up and down to connect the inside and the outside of the tank 100, the through groove 12 has a nozzle bottom (20) having a substantially hollow cylindrical shape. This is airtightly fitted and fixed.

Then, the lower end of the nozzle top 30 is fixed to the upper end of the nozzle bottom 20, the nozzle 330 is a spring (in the inner space formed by the combination of the nozzle bottom 20 and the nozzle top 30) 331, the O-ring 332 and the T-packing 340 is mounted, and the approximate configuration in which the gas is ejected by the vertical movement of the nozzle 330 is similar to the conventional one.

An inner central portion of the nozzle bottom 20 is blocked by the partition wall 22, and a gas passage 22a that is opened and closed by the T-packing 340 penetrates up and down at the central portion of the partition wall 22. .

In addition, the nozzle bottom 20 is mounted so that the filter 40 formed with pores of fine size through which gas passes is located under the partition wall 22, and the tank 100 at the lower end of the nozzle bottom 20. The auxiliary tank 70 is provided to store the predetermined amount of gas supplied to the inside of the filter 40 and to provide the gas to the nozzle 330 through the filter 40.

More specifically, the nozzle bottom 20 is provided with a filter mounting groove 24 having a circular cross section in which the filter 40 is mounted therein while forming a hollow cylinder shape starting from the partition wall 22 to the bottom thereof. The auxiliary tank 70 is mounted at the lower end of the nozzle bottom 20 via the auxiliary tank connector 60.

The auxiliary tank connector 60 is formed to have an approximate disc shape and is securely fitted to the lower inner side of the filter mounting groove 24 so that the gas tank 61a penetrates up and down in the center. , A hollow cylindrical shape surrounding the gas passage (61a) is formed integrally at the lower end of the main body (61) and made of an extension portion (62) extending a predetermined length downward, wherein the auxiliary tank (70) is A solid cylindrical fitting portion 72 extending upwardly to be fitted into the extension portion 62, and a hollow cylindrical shape having a lower end covering the outside of the extension portion 62 and sealed at the lower portion thereof. And a main body portion 71 integrally formed with 72.

In this case, an extension part may be formed between the outer diameter part of the extension part 62 of the auxiliary tank connector 60 and the inner diameter part of the body part 71 of the auxiliary tank 70 to accommodate a proper amount of gas. The outer diameter of 62 and the inner diameter of the main body portion 71 are set. In addition, the upper end of the main body portion 71 extends to contact the lower end of the nozzle bottom 20 and the gas of the tank 100 is supplied to the inside of the main body portion 71 at the upper end of the main body portion 71. Several gas supply grooves 73 that are passages are formed. In addition, the gas received between the outer diameter portion of the extension portion 62 of the auxiliary tank connector 60 through the gas supply groove 73 and the inner diameter portion of the body portion 71 of the auxiliary tank 70 is a main body. An inner diameter portion of the extension 62 of the auxiliary tank connector 60 and the fitting portion 72 of the auxiliary tank 70 so that the filter 40 may be supplied to the filter 40 through the gas passage 61a of the 61. First and second gas grooves serving as gas passages between the outer diameter portions of the auxiliary tank connector 60 and the lower end of the extension portion 62 of the auxiliary tank 70 and the inner upper end of the main body portion 71 of the auxiliary tank 70. (81) (82) is formed, in the present embodiment, the first gas groove 81 is formed continuously in the longitudinal direction on the outer surface of the fitting portion 72 in a plurality of places along the circumferential direction and the second gas The groove 82 is formed radially at the lower end of the extension portion 62 and disposed in various places to correspond to the first gas groove 81 along the circumferential direction. However, the first gas to form a groove 81 on the inner surface of the extension portion 62 and may even form a second gas groove 82 to the inner upper end of the main section (71).

The filter 40 is between the auxiliary tank 70 and the nozzle 330, more specifically, between the upper end of the main body 61 of the auxiliary tank connector 60 and the lower end of the partition wall 22 of the nozzle bottom 20. It may be composed of a plurality of filters (41, 42, 43) stacked on.

In addition, it is preferable that the filter 40 is supported by the filter support 50. The filter support 50 has a predetermined thickness and a gas passage through which the gas passes through the gas is passed through the center. It has a shape. Of course, such a filter support 50 is composed of a plurality of filter supports (51, 52) that are fitted between each of the plurality of filters (41) (42) (43) formed of a plurality, these filter support ( In each of the 51 and 52, gas passages 51a and 52a penetrate up and down in the center.

In the present embodiment having the above-described configuration, when the gas lighter is not used, that is, when no external force is applied to the lever 450, the nozzle 330 remains lowered by the spring 331, and the nozzle ( The T-packing 340 provided at the bottom of the 330 closes the gas passage 22a formed in the partition wall 22 of the nozzle bottom 20, thereby preventing the gas ejection through the nozzle 330.

And, the auxiliary tank 70 is filled with the appropriate amount of gas bar, when the user is forced to shake the gas lighter or the gas lighter located in the user's pocket, the gas filled in the tank 100 gas supply groove Through the 73 is filled in the space inside the main body portion 71 of the auxiliary tank 70 and the extension 62 of the auxiliary tank connector 60.

In order to use the gas lighter, the lever 450 is pushed downward, and the wheel 440 is rotated at the same time, the nozzle 330 rises and the gas is ejected and the ejected gas is formed on the spark formed from the flint 420. Is ignited by

In this case, when the nozzle 330 is raised, the gas filled in the auxiliary tank 70 passes through the nozzle 330 through the gas passage 61a, the filter 40 and the filter support 50 of the auxiliary tank connector 60. ), The amount of gas supplied to the nozzle 330 is limited by the amount of gas filled in the auxiliary tank 70 so that a certain amount of gas is ejected through the nozzle 330 during one gas lighter operation.

This solves the problem that an inconsistent amount of gas is ejected through the nozzle during a single operation of the gas lighter as in the related art, and sometimes an excessive amount of gas is ejected through the nozzle, resulting in excessive gas consumption.

In addition, the gas flow rate per unit time ejected through the nozzle 330 is determined by the pore size of the filter 40. If the pore size of the filter 40 is appropriately set, the nozzle irrespective of the change in the outside air temperature, etc. The gas flow rate per unit time ejected through 330 is always constant, whereby the flame size of the nozzle is always constant, which solves the conventional problem that the safety of the user is impaired by an excessively large size flame.

Therefore, since the size of the flame is appropriately adjusted by the filter and the amount of gas ejected through the nozzle by the auxiliary tank is controlled by the present embodiment, the user needs to directly adjust the size of the flame according to the change of the outside temperature as in the prior art. There is no.

In particular, the present embodiment has a simple structure in which the nozzle bottom 20 is fixedly installed on the cap 200, and the nozzle top 310 is rotatably mounted to the cap 200, and the nozzle top 310 may be installed. Compared with the conventional gas lighter having a complicated structure in which the adjuster 380 is mounted to the nozzle top 310 for rotation, the manufacturing process is simpler and the manufacturing cost is reduced.

FIG. 8 is a detailed view of a main part of a gas lighter according to another embodiment of the present invention. The same components as in the prior art are denoted by the same reference numerals as in FIGS. 1 to 3, and detailed descriptions of these components are omitted. do.

The present embodiment relates to a mounting structure of the nozzle bottom 320A installed in the cap 200, the nozzle bottom 320A is a nozzle top in the through groove 210 formed to penetrate up and down on one side of the cap 200. Fitted with 310.

At this time, the outer surface of the nozzle bottom 320A is provided with an O-ring 321 having a continuous shape along the circumferential direction, the O-ring 321 is the outer surface of the nozzle bottom 320A and the through groove ( It serves to block the leakage of gas through the inner surface of the 210.

More specifically, an outer surface of the nozzle bottom 320A is formed with an O-ring mounting groove 322A having a smaller outer diameter than other portions from a lower portion to a predetermined distance from an upper portion thereof, and the O-ring mounting groove ( The O-ring 321 is fitted into the 322A from the bottom to the top.

The nozzle bottom 320A is manufactured by a die casting casting method, and the material is preferably zinc (Zn) metal which is widely used in the die casting casting method due to its low unit cost, low melting point, and high precision of dimensions.

The O-ring mounting groove 322A having the above-described shape has the same outer diameter size from the lower predetermined position to the lower end, and the O-ring mounting groove 322A has a circular hole (not shown) of a casting mold (not shown). It can be formed as shown in the figure) and has a very precise round shape as compared with the case produced by the die casting casting method by a casting mold paired with a semi-circular hole as in the prior art. Therefore, the post-process of precisely processing the O-ring mounting groove 322A formed in the nozzle bottom 320A of this embodiment is unnecessary.

Fig. 9 is a detailed view of the main portion showing the modification of Fig. 8, and according to this modification, an outer surface of the nozzle bottom 320B is mounted with an O-ring formed with a smaller outer diameter than other portions from a top to a predetermined distance from a lower portion thereof. A groove 322B is formed, and the O-ring 321 is fitted into the O-ring mounting groove 322B from the top to the bottom.

Of course, the nozzle bottom 320B is also manufactured by a die casting casting method, and as shown in FIG. 8, the O-ring mounting groove 322B may be formed by a circular hole of a casting mold, thus having a very precise round shape. Has Therefore, the post-process of precisely processing the O-ring mounting groove 322B formed in the nozzle bottom 320B of this embodiment is unnecessary.

As described above, since the O-ring mounting grooves 322A and 322B formed in the nozzle bottoms 320A and 320B have a very precise round shape in the die casting casting method, the through groove 210 and the nozzle bottom of the cap 200 are formed. The gap between the 320A and 320B is completely blocked by the O-ring 321, so that the gas leakage prevention effect is excellent.

In addition, since the processing accuracy of the O-ring mounting grooves 322A and 322B is excellent, there is no need for post-processing, which solves the problems of the prior art, in which the cost is increased and productivity is reduced by post-processing.

As described above, according to the gas lighter according to the present invention, the amount of gas consumed in one operation of the gas lighter is always constant by the amount of gas stored in the auxiliary tank, thereby having an excellent effect of preventing excessive gas consumption.

In addition, the gas flow rate per unit time ejected through the nozzle is always constant due to the pore size of the filter, which has an excellent effect of solving the conventional problem that the safety of the user is impaired by an excessively large size flame.

In addition, since the size of the flame and the gas blowing are controlled by the filter and the auxiliary tank, the user does not need to adjust the size of the flame and the amount of gas blowing separately, so the operation of the gas lighter is simple, and the size of the flame and the gas blowing can be adjusted. The complicated structure is unnecessary, so the manufacturing process is simple and the manufacturing cost is reduced.

In addition, an O-ring mounting groove having a small outer diameter and a very precise round shape is formed in comparison with other portions from the outer surface of the nozzle bottom to a predetermined distance from the top to the bottom or from the bottom to the predetermined distance. -O-rings are installed in the ring mounting groove to prevent gas leakage very effectively.

In addition, since the processing degree of the O-ring mounting groove is excellent, there is no need for post-processing, which has an excellent effect of solving the problems of the prior art, in which cost increases and productivity is reduced by post-processing.

Claims (3)

The gas is provided in the cap to eject the gas through the nozzle and the nozzle attached to the nozzle bottom penetrating the cap or to block the gas ejection through the nozzle to have an internal space filled with gas In the gas lighter comprising an adjusting mechanism and a ignition mechanism for generating a spark to ignite the gas ejected from the nozzle, The nozzle bottom has an O-ring mounting groove continuously formed to have the same outer diameter from a predetermined position to one end while having a smaller outer diameter than the other portion on the outer surface, and penetrates the cap to connect the inside and the outside of the tank. The gas lighter, characterized in that the nozzle bottom is installed in the air-tightness O-ring mounting groove in the O-ring mounting groove. The gas lighter of claim 1, wherein the O-ring mounting groove is continuously formed from an upper end of the nozzle bottom to a predetermined distance. The gas lighter of claim 1, wherein the O-ring mounting groove is formed continuously from a lower end of the nozzle bottom to a predetermined distance.

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