KR101348744B1 - Nozzle for Container - Google Patents

Abstract

A nozzle coupled to a container, one side of which is coupled to the container and the other side of which has a first wedge coupling portion and a first connection nozzle having an inclined coupling surface, and one side of which has a second wedge coupling portion coupled to the first wedge coupling portion. And a second connection nozzle which is inclinedly coupled to the inclined coupling surface of the first connection nozzle and rotates along the inclined coupling surface.

Description

Nozzle for Container

The present invention relates to a nozzle, and more particularly, to a nozzle for a container to be used in combination with a container such as a silicone cartridge.

The nozzle is used in combination with a container such as a cartridge, a tube containing a filler, silicon, glue, and the like, and serves to guide the silicon in the container to a specific point.

The nozzle may be formed integrally with the vessel, but is usually provided in the form of engaging the vessel in use.

When injecting silicon or the like into a specific area using the nozzle, the nozzle may be made of a hard material, and thus, the operation may not be easy. For example, when the silicon is to be injected into a recessed or bent point, there is a case where the operation is impossible because the inside of the nozzle is not directly touched by a straight nozzle. Alternatively, for certain working environments it may be easier to use bent nozzles. In this case, it is convenient to bend the nozzle at a desired angle.

Figures 1a, 1b, 1b is a perspective view and a cross-sectional view showing the bending nozzle of US Patent 7,931,175.

As shown in Figs. 1A, 1B and 1C, the prior art bending nozzles are composed of two sub nozzles 11 and 13 having inclined engagement surfaces that are symmetrical, and the two sub nozzles 11 and 13 are relatively The nozzle is bent while rotating. The first sub-nozzle 11 and the second sub-nozzle 13 are coupled at 45 °, so when the second sub-nozzle 13 rotates with respect to the first sub-nozzle 11, the second sub-nozzle 13 May be unfolded in a straight line (180 °) form or bent in a right angle (90 °) form.

In addition, as shown in the cross-sectional view of FIG. 1C, the bending nozzle of the prior art has a protrusion P formed on the outer periphery of the end of the first sub-nozzle 11, and the inner surface of the end of the second sub-nozzle 13. The recessed part R is formed in. When the protrusions P and the depressions R are compressed using the compactor, the protrusions P are inserted into the depressions R, through which the first sub nozzle 11 and the second sub nozzle 13 are inserted. Combined with each other.

As described above, the bending nozzle of the prior art has a configuration in which the first sub nozzle 11 and the second sub nozzle 13 are joined by compression of the protrusion P and the depression R, and at the time of manufacture, It is difficult to combine in the manufacturing process, such as to use a separate, in particular, by using a separate compression machine to increase the manufacturing cost. In addition, the first sub-nozzle 11 and the second sub-nozzle 13 may be separated by lowering the protrusion P, and in this case, the first sub-nozzle 11 and the second sub-nozzle may be directly operated by the user in the field. It is virtually impossible to use a combination of (13).

In addition, although a large amount of existing nozzles in the form of a straight line exists on the market and is currently on sale, a conventional bending nozzle has a problem that such a conventional nozzle cannot be used. For example, a deep recessed or bent portion may need to be extended to use a bending nozzle, in which case it may be easier to use in combination with a conventional straight nozzle, which is not possible with conventional bending nozzles. Do.

The present invention is to solve the problems of the conventional bending nozzle,

First, it is easy to combine when manufacturing the bending nozzle to increase the production efficiency and productivity,

Second, even if the nozzle is separated at the time of use, can be combined again,

Third, the existing straight nozzle can be combined and used as needed, and also

Fourth, it is an object to make it easy to select the nozzle type according to the use environment.

The nozzle for a container of the present invention for achieving the above object comprises a first connection nozzle and a second connection nozzle which is inclinedly coupled to the first connection nozzle.

One side of the first connection nozzle is coupled to the container, and the other side has a first wedge coupling portion and has an inclined coupling surface.

The second connection nozzle has a second wedge coupling portion coupled to the first wedge coupling portion of the first connection nozzle on one side. The second connection nozzle may be inclinedly coupled to the inclined coupling surface of the first connection nozzle and may rotate along the inclined coupling surface. The inclination angle may be selected as needed. For example, when the inclination angle is 45 °, the bending angle of the first connection nozzle and the second connection nozzle may vary from a straight line 180 ° to a right angle 90 °.

The second connection nozzle is provided with a coupling portion that can be used by combining the existing nozzle. The coupling part may be provided in a thread form on the outer circumferential surface or the inner circumferential surface of the other side of the second connection nozzle.

The second connection nozzle may be integrally formed with nozzles of various shapes. For example, the second nozzle may include a central nozzle having a central portion inflated from both ends, and a tapered nozzle having a diameter decreasing toward the outlet. It can extend integrally with the other end of a connection nozzle. When using such a composite nozzle, the user can select a specific part according to the use environment and then cut the corresponding part.

The first wedge engaging portion of the first connecting nozzle and the second wedge engaging portion of the second connecting nozzle are inclined toward the container. Through this, the second wedge coupling portion is easily coupled to the first wedge coupling portion, and after engagement, the second wedge coupling portion is not easily released from the first wedge coupling portion.

The first wedge engaging portion of the first connecting nozzle and the second wedge engaging portion of the second connecting nozzle may have a shape in which the protrusion protrudes upward and is symmetrical to the left and right.

The first connection nozzle and the second connection nozzle symmetrically include a plurality of protrusions and depressions on the inclined coupling surface. The protrusions or depressions are preferably formed at equal intervals along the circumference. The protrusion and the depression are used to determine the amount of rotation while controlling the rotation of the first connection nozzle and the second connection nozzle. In addition, the protrusion may be made of an elastic material.

According to the container nozzle of the present invention, when the bending nozzle is manufactured, the bonding is easy and easy to manufacture, thus increasing the productivity. In addition, even when the nozzle is separated at the time of use, it can be easily combined again to be used.

In addition, existing nozzles widely used in the market can be easily combined with the container nozzle of the present invention can be used.

In addition, since the nozzles have various shapes, the user can select and use a specific type of nozzle according to the use environment.

Figures 1a, 1b, 1b is a perspective view and a cross-sectional view showing the bending nozzle of US Patent 7,931,175.
Figure 2a is a cross-sectional view of a tapered nozzle with an inclined wedge engagement in accordance with the present invention.
FIG. 2B is a cross-sectional view of a tapered nozzle having a non-inclined wedge engaging portion as a modification of FIG. 2A.
3A and 3B show nozzles with different structures of the second connection nozzles as modifications of FIGS. 2A and 2B.
4A and 4B illustrate connection nozzles for adjusting angles that can combine existing nozzles.
Figure 5 shows another embodiment of the connecting nozzle for angle adjustment according to the present invention.
6A and 6B show another embodiment of a nozzle having a wedge shaped engagement.

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

Figure 2a is a cross-sectional view of a tapered nozzle with an inclined wedge engagement in accordance with the present invention.

As shown in FIG. 2A, the nozzle of FIG. 2A includes a first connection nozzle 210 and a second connection nozzle 310.

One side of the first connection nozzle 210 is coupled to the outlet 410 of the container. In FIG. 2A, although the coupling between the first connection nozzle 210 and the container outlet 410 is illustrated as screw coupling S211 and S411, shooting coupling is also possible.

The other side of the first connection nozzle 210 is coupled to the second connection nozzle 310, and the other side of the first connection nozzle 210 is rotatably coupled to the second connection nozzle 310. In addition, the other coupling portion of the first connection nozzle 210 is provided with a plurality of wedge-shaped protrusions (W211). The wedge-shaped protrusion W211 of the first connection nozzle 210 is formed on the other inner peripheral surface of the first connection nozzle 210 to correspond to the wedge-shaped protrusion W311 formed on the second connection nozzle 310. Here, when the wedge-shaped protrusion W311 of the second connection nozzle 310 is formed on the inner circumferential surface, the wedge-shaped protrusion W211 of the first connection nozzle 210 is formed on the outer peripheral surface of the other side of the first connection nozzle 210. do.

One side of the second connection nozzle 310 is inclinedly coupled to the inclined coupling surface of the first connection nozzle (210). In addition, on one side of the second connection nozzle 310, a plurality of wedge-shaped protrusions W311 corresponding to the wedge-shaped protrusions W211 of the first connection nozzle 210 are formed on the outer circumferential surface of the second connection nozzle 310. It is. The engagement surface of the second connection nozzle 310 coupled with the first connection nozzle 210 also has an inclination angle corresponding to the inclined engagement surface of the first connection nozzle 210.

As shown in FIG. 2A, the wedge-shaped protrusions W211 and W311 of the first connection nozzle 210 and the second connection nozzle 310 are inclined toward the container outlet 410, and thus the second connection nozzle ( 310 may be easily coupled to the first connection nozzle 210, and after coupling, the second connection nozzle 310 may not be easily separated from the first connection nozzle 210.

Each of the first connection nozzles 210 and the second connection nozzles 310 are inclined with each other while the inclined coupling surfaces face each other, and as a result, the first connection nozzles 210 and the second connection nozzles 310 according to the relative rotation amount. The bending angle of is changed. For example, when the inclination angle is 45 °, the bending angle varies from the straight direction (180 °) to the right angle direction (90 °).

Semi-circular protrusions P211 for controlling the rotation and the amount of rotation between the first connection nozzle 210 and the second connection nozzle 310 on the inclined coupling surface of the first connection nozzle 210 and the second connection nozzle (310). ) And depression R311 are formed symmetrically. Protruding portion (211) is coupled in the form of being inserted into the depression (R311). The protruding portion P211 or the recessed portion R311 may form a circle and be formed at equal intervals. In addition, the protrusion P211 is preferably made of an elastic material. Furthermore, in order to seal the coupling surface of the first connection nozzle 210 and the second connection nozzle 310 more, the coupling surface of the first connection nozzle 210 and the second connection nozzle 310 may also be made of an elastic material. have.

The other side of the second connection nozzle 310 is integrally formed with a tapered nozzle 313 is reduced in diameter as it goes to the outlet.

FIG. 2B is a cross-sectional view of a tapered nozzle having a non-inclined wedge engaging portion as a modification of FIG. 2A.

As shown in FIG. 2B, in the nozzle of FIG. 2B, the wedge-shaped protrusions W211 ′ and W311 ′ of the first connecting nozzle 210 ′ and the second connecting nozzle 310 ′ protrude upward and are symmetrically symmetrically. It is formed and does not incline in either direction. The nozzles having the non-inclined wedge shaped protrusions W211 'and W311' of FIG. 2B are less likely to couple the second connection nozzle 310 'to the first connection nozzle 210' compared to the nozzle of FIG. 2A. It may be easy, and it may be easy to separate the second connection nozzle 310 'from the first connection nozzle 210' even after the coupling. However, even when the wedge-shaped protrusions W211 'and W311' are non-inclined, an object of the present invention may be easily achieved to easily couple the first connection nozzle 210 'and the second connection nozzle 310'. In addition, according to the material of the wedge-shaped protrusions (W211 ', W311'), the difficulty of coupling and separation can be adjusted, the nozzle having the non-sloped wedge-shaped protrusions (W211 ', W311') of Figure 2b Worth as.

3A and 3B show nozzles with different structures of the second connection nozzles as modifications of FIGS. 2A and 2B.

The nozzles of FIGS. 3A and 3B are modified in the shape of the second connection nozzles 320 and 320 'from the nozzles of FIGS. 2A and 2B. Two types of nozzles 321 and 323 are combined. That is, one side is connected to the first connection nozzles 210 and 210 ', and the diameter is increased toward the center of the expanded nozzle portion 321 and the form of the diameter is reduced again, extending from the extended nozzle portion 321 is formed to go to the outlet It consists of the tapered nozzle part 323 which diameter becomes small.

When using the nozzle, it is usually used to cut a part of the nozzle according to the use environment. When using the nozzles of FIGS. 3A and 3B, it is convenient to use the tapered nozzle and the expandable nozzle by cutting the appropriate part according to the use environment and the need. Do.

In FIGS. 3A and 3B, the second connection nozzles 320 and 320 'are extended in the order of the extended nozzle portion 321 and the tapered nozzle portion 323, but the taper-type nozzle portions 323 are changed as necessary. ) And the extended nozzle unit 321 may be extended.

Figure 4a shows a connecting nozzle for adjusting the angle that can combine the existing nozzle.

The connection nozzle for angle adjustment of FIG. 4A includes a first connection nozzle 210 and a second connection nozzle 330.

Since the first connection nozzle 210 has the same configuration as the first connection nozzle 210 shown in FIG. 2A, a description of the first connection nozzle 210 will be omitted and the second connection nozzle 330 will be omitted. Explain in detail. In addition, the description of the second connection nozzle 330 will be described in detail based on differences from the second connection nozzle 310 of FIG. 2A.

One side of the second connection nozzle 330 is coupled to the first connection nozzle 210.

The other side of the second connection nozzle 330 is formed with a nozzle coupling portion (S331) that the existing nozzle is coupled to the outer peripheral surface. Since the conventional nozzle is usually screwed to the container outlet 410, it is preferable to form a thread (S331) on the outer peripheral surface of the nozzle coupling portion of the second connection nozzle 330. Of course, if the coupling portion of the existing nozzle is formed of a wedge-shaped protrusion, the outer circumferential surface of the nozzle coupling portion of the second connection nozzle 330 may also be configured as a wedge-shaped protrusion.

The existing nozzle 340 connected to the second connection nozzle 330 may use a tapered nozzle 340 having a diameter decreasing while going to the outlet. Of course, although not shown in Figure 4a, the existing nozzle is connected to the nozzle of the composite structure, that is, one side is connected to the first connection nozzle 210, the diameter increases toward the center and the expanded nozzle portion and the expanded nozzle portion is reduced in diameter again It may be configured to have a structure in which the tapered nozzle portion is formed to extend and the diameter is reduced to the outlet. Of course, the order of the extended nozzle part and the tapered nozzle part can be changed.

Fig. 4B is a variation of Fig. 4A, showing an angle adjusting connecting nozzle having a non-inclined wedge-shaped protrusion.

As shown in FIG. 4B, in the nozzle of FIG. 4B, the wedge-shaped protrusions W211 ′ and W311 ′ of the first connection nozzle 210 ′ and the second connection nozzle 330 ′ protrude upward and are symmetrical to each other. It is formed and does not incline in either direction.

As described in the nozzle of FIG. 2B, the angle adjusting connecting nozzle having the non-inclined wedge-shaped protrusions W211 'and W311' in FIG. 4B is also valuable as one embodiment.

Figure 5 shows another embodiment of the connecting nozzle for angle adjustment according to the present invention.

Another embodiment of the connection nozzle for adjusting the angle of FIG. 5 is provided to the second connection nozzle 350 while using the inclined coupling of the first connection nozzle 220 and the second connection nozzle 350 disclosed in the prior art. This is a connection nozzle for angle adjustment that can be used by combining existing nozzles.

One side of the first connection nozzle 220 is coupled to the outlet 410 of the container. In FIG. 5, although the first connection nozzle 220 and the container outlet portion 410 are illustrated by screw coupling, wedge coupling is also possible. The other side of the first connection nozzle 220 is provided with a coupling for coupling with the second connection nozzle (350). The engaging portion is configured to be inclined at an end thereof, and an engaging protrusion P221 protruding outward is formed at the outer periphery of the end portion.

The second connection nozzle 350 has a coupling part coupled to the first connection nozzle 220 on one side thereof, and a coupling depression corresponding to the coupling protrusion P221 of the first connection nozzle 220 is formed at an inner circumferential surface of the end of the coupling part. Part R351 is formed. The coupling protrusion P221 of the first connection nozzle 220 is press-bonded to the coupling depression R351 of the second connection nozzle 350, and at this time, a compression machine is used.

The first connection nozzle 220 and the second connection nozzle 350 are inclinedly coupled, and the bending angle is changed according to the relative amount of rotation. For example, when the inclination angle is 45 °, the bending angle may vary from the straight direction (180 °) to the right angle direction (90 °).

Semi-circular protrusions P211 which control the rotation and the amount of rotation between the first connection nozzle 220 and the second connection nozzle 350 on the inclined coupling surface of the first connection nozzle 220 and the second connection nozzle 350. ) And depression R311 are formed symmetrically. The function, material, etc. of the protrusion part P211 and the depression part R311 are the same as that mentioned above.

The other side of the second connection nozzle 350 is formed with a nozzle coupling portion to which the existing nozzle 340 is coupled to the outer peripheral surface. Since the existing nozzle 340 is usually screwed to the container outlet 410, it is preferable that the nozzle coupling portion of the second connection nozzle 350 also forms a thread on the outer circumferential surface thereof. Of course, if the coupling portion of the existing nozzle 340 is formed as a wedge-shaped protrusion, the nozzle coupling portion of the second connection nozzle 350 may also be configured as a wedge-shaped protrusion.

The existing nozzle 340 connected to the second connection nozzle 350 uses a tapered nozzle that decreases in diameter as it goes to the outlet. Of course, it is also possible to use a composite nozzle in which the central diameter of the expansion nozzle portion and the tapered nozzle portion that decreases in diameter as it goes to the outlet can be used, and only the expansion nozzle portion of the central diameter can be used.

6A and 6B show another embodiment of a nozzle having a wedge shaped engagement.

The nozzle of FIG. 6A includes a first connection nozzle 360 and a second connection nozzle 370.

The first connection nozzle 360 includes a container coupling part connected to the container outlet part 410 and an extension coupling part connected to the second connection nozzle 370.

A plurality of threads S211 are formed on the inner circumferential surface of the container coupling portion, and a plurality of threads S411 corresponding to the threads S211 of the container coupling portion are formed on the outer circumferential surface of the container outlet portion 410.

In FIG. 6A, the container outlet part 410 and the first connection nozzle 360 are illustrated by screw coupling, but the container outlet part 410 and the first connection nozzle 360 may be coupled by the wedge coupling. In this case, the wedge-shaped protrusions respectively formed at the container outlet portion 410 and the first connection nozzle 360 are inclined in the direction of the container, whereby the first connection nozzle 360 is easily at the container outlet portion 410. The first connection nozzle 360 is not easily separated from the container outlet 410 after the coupling.

A plurality of wedge-shaped protrusions W361 are formed on the inner circumferential surface of the extension coupling portion of the first connection nozzle 360, and a plurality of wedge-shaped protrusions W371 are formed on the outer circumferential surface of the inner coupling portion of the second connection nozzle 370. Is formed.

The inner coupling portion of the second connection nozzle 370 is coupled to the extension coupling portion of the first connection nozzle 360 in a wedge shape, and may rotate along the protrusion of the wedge. Since the engagement surface of the first connection nozzle 360 and the second connection nozzle 370 is not inclined, even when the second connection nozzle 370 rotates, the bending angle of the second connection nozzle 370 does not change according to the amount of rotation. Do not. However, since the tapered nozzle extending on the other side of the second connection nozzle 370 is inclined at a predetermined angle, the tapered nozzle is also inclined when the second connection nozzle 370 rotates at the first connection nozzle 360. Rotate in the bent state.

As shown in FIG. 6A, each of the wedge-shaped protrusions W361 and W371 of the extension coupling portion and the inner coupling portion are inclined toward the container outlet portion 410, which causes the second connection nozzle 370 to become the first connection nozzle ( 360 can be easily coupled, and after coupling, the second connection nozzle 370 is not easily separated from the first connection nozzle 360.

A plurality of semicircular depressions and protrusions are provided on the coupling surface of the first connection nozzle 360 and the second connection nozzle 370 to control the rotation and the amount of rotation between the first connection nozzle 360 and the second connection nozzle 370. Are respectively formed to correspond. Since the function and the material of the protrusion and the recess are the same as described above, detailed description thereof will be omitted.

FIG. 6B is a modification of FIG. 6A and shows a nozzle having a different structure of the second connection nozzle.

The nozzle of FIG. 6B is a modified shape of the second connection nozzle 380 in the nozzle of FIG. 6A, and two types of nozzles 381 and 383 are combined. That is, one side is connected to the first connection nozzle 360, the diameter of the expanded nozzle portion 381 and the expanded nozzle portion 381 in the form of a diameter decreases as the diameter increases toward the center, the diameter of the expanded nozzle portion 381 is formed to go to the outlet The tapered nozzle portion 383 is made smaller. In the case of using the nozzle of Fig. 6B, the tapered nozzle and the expandable nozzle can be cut and used as appropriate for the use environment and needs.

In FIG. 6B, the second connection nozzle 380 is formed to extend in the order of the expansion nozzle part 381 and the tapered nozzle part 383. However, if necessary, the joining order is changed to change the tapered nozzle part 383 and the expansion type. It can extend in the order of the nozzle part 381.

While the invention has been described in terms of several embodiments, it is to be understood that the invention is not limited thereto. Those skilled in the art will be able to make various modifications or changes based on the present embodiment. Therefore, the scope of the present invention should be determined by the claims below, and such variations or modifications made by those skilled in the art may be interpreted as being included in the scope of the present invention.

210: first connection nozzle W211, W311: wedge-shaped protrusion
P211, R311: semi-circular protrusion, depression
320: expanded nozzle portion 323: tapered nozzle portion

Claims (6)

A nozzle coupled to a container,
One side is coupled to the container, the other side has a first wedge engaging portion inclined in the direction of preventing separation, the first connection nozzle, the first connection nozzle; And
One side has a second wedge coupling portion which is inclined in a direction of preventing separation and is wedge-coupled to the first wedge coupling portion, is coupled to the inclined coupling surface of the first connection nozzle and is bent while rotating along the inclined coupling surface A second connection nozzle,
The first and second connection nozzles, characterized in that provided with a plurality of protrusions and depressions on the inclined coupling surface, the container nozzle. The method of claim 1, wherein the second connection nozzle
The other side is provided with a threaded coupling portion, characterized in that the threaded coupling portion is screwed to the third connection nozzle, the container nozzle. The method of claim 1, wherein the other side of the second connection nozzle
Centered swollen nozzle portion; And
A nozzle for a container, characterized by consisting of a tapered nozzle portion that decreases in diameter toward the outlet. delete delete delete

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