KR102647616B1 - Nozzle-coupled Hera structure of silicone container - Google Patents

Abstract

The present invention discloses a nozzle-coupled hera structure of a silicone container. The present invention is designed so that even if the exposed cross section of the tip of the nozzle formed at the tip of the silicone container is cut to be small or large to control the discharge of silicone resin, the hera structure can be easily attached to the tip of the cut nozzle, and accordingly. When the silicone resin is discharged from the silicone container through the silicone gun, the bonding work of the discharged silicone resin is performed and at the same time, the finishing work of trimming through the Hera structure is performed immediately, thereby improving work efficiency by shortening the time of the silicone resin bonding work. , This is to improve the work inconvenience caused by using a separate Hera.

Description

Nozzle-coupled Hera structure of silicone container}

The present invention relates to a Hera structure coupled to the nozzle of a silicone container. More specifically, the Hera structure is safe and secure regardless of the size cut to control the discharge of silicone resin at the nozzle portion coupled to the discharge portion of the silicone container. By ensuring that the silicone resin is discharged through the nozzle and joined firmly, the silicone resin is discharged through the nozzle to perform the bonding process, and at the same time, the trimming and finishing work of the bonded silicone resin can be continuously performed through the hera structure. The nozzle combination type of the silicone container It's about the Hera structure.

In general, adhesive work using silicone is widely used to fill gaps for finishing or to fix window frames or glass in various construction or interior construction projects.

The silicone is a generalized name for silicone resin and is a general term for polymers of silicon organic compounds. It is a material with a wide range of applications because it can withstand high temperatures of 300℃ or low temperatures of -60℃, insulates electricity, and dries water well.

These silicones are used in a variety of ways, such as for insulation in the electrical field or for waterproofing in wet areas in the construction field.

For the above silicone operation, a tube filled with silicone is fastened to a silicone gun, and then the handle and lever are repeatedly pulled, causing the operating member inserted through the main body to sequentially advance forward.

In addition, the tube is filled with silicon, and the inside is a double structure like a syringe. The compression plate at the rear pushes the silicon embedded in the tube body as the operating member advances, and the silicon is discharged through the discharge port.

Meanwhile, in order to discharge silicone from the tube, the end of the outlet is cut and the nozzle is tightened and attached to the silicone gun to discharge silicone.

This silicone is stored in a silicone container, and the silicone container is used while attached to a silicone gun. When the user pulls the flange of the silicone gun, the silicone inside the silicone container is ejected to the outside through the nozzle, filling the gap in the work space. Bonding is achieved by filling.

Then, if a separate tool is not prepared, wear disposable plastic gloves and smooth the injected silicone surface with your fingers. Once the silicone has hardened, remove the masking tape attached to the left and right sides to demarcate the work space. .

The silicone finishing work that has been done as described above takes a lot of time because the worker has to polish the silicone by hand after injecting the silicone, and the finished surface is not consistent depending on the worker's skill level, which spoils the aesthetics. There was a downside to this.

To solve this problem, finishing work was performed using Hera, which is made of raw rubber or urethane material for silicone finishing.

In addition, in order to improve the conventional silicon container and silicon nozzle, Registered Utility Model Publication No. 20-0449598, Registered Patent Publication No. 10-1178376, Open Patent Publication No. 10-2013-0005707, Registered Patent Publication No. 10- As in No. 1538073, a guide part (or scraper) is formed to protrude integrally from the outer peripheral surface of the nozzle, thereby allowing the silicone resin ejected through the nozzle to be spread at a certain width along the joint boundary surface.

However, as in Registered Patent No. 10-1178376, when trying to prevent the outflow of silicon by installing additional wings on the silicon nozzle, silicon discharged from the nozzle is required due to the inclined portions created on the wings extending to the left and right. There was a problem of waste spreading wider than the above, and also, due to maintaining an open structure without a shielding wing at the front, a problem of silicon leaking out to the front of the nozzle and being wasted was also pointed out.

Registered Utility Model Publication No. 20-0196518 (announcement date 2000.09.15.) Registered Utility Model Bulletin No. 20-0449598 (announcement date 2010.07.22.) Registered Patent Publication No. 10-1178376 (announcement date 2012.08.29.) Public Patent Publication No. 10-2013-0005707 (publication date 2013.01.16.) Registered Patent Publication No. 10-1235347 (announcement date 2013.02.20.) Registered Patent Publication No. 10-1538073 (announcement date 2015.07.21.) Registered Patent Publication No. 10-2262600 (announcement date 2021.06.07.)

The present invention to solve the above problems is to securely and tightly attach the Hera structure to the nozzle area coupled with the discharge portion of the silicone container, regardless of the size cut to control the discharge of silicone resin. By doing so, the aim is to provide a nozzle-coupled Hera structure of a silicone container that allows the silicone resin to be discharged through the nozzle to perform the bonding work and at the same time, the trimming and finishing work of the bonded silicone resin can be performed through the Hera structure.

The nozzle-coupled Hera structure of a silicone container, which is a means of solving the problem of the present invention, includes a tubular nozzle coupling portion into which a nozzle is fitted and connected to the tip opening of the silicone container in which the silicone resin is filled, and the tubular nozzle coupling portion in communication with the tubular nozzle coupling portion. Hera body in which an extrusion flow path is formed to guide the discharge of the silicone resin; And, a cover member having an open bottom, one end of which is fitted into the tubular nozzle coupling part and tightly coupled to the side and top of the Hera body; It includes.

Additionally, the Hera body is made of soft polyurethane material.

Additionally, the nozzle coupling portion has elasticity for fitting between the outer peripheral surface of the nozzle or the nozzle cap and is formed integrally with one end of the hera body.

Additionally, a pair of pull handles are formed on the nozzle coupling portion to enlarge the entrance of the nozzle coupling portion to guide the insertion depth of the nozzle into the nozzle coupling portion.

Additionally, the extrusion passage is formed to be inclined from one side of the hera body toward the bottom of the hera body.

Additionally, the cover member is made of a hard polyurethane material with a predetermined elasticity whose inner circumferential surface is covered in close contact with the sides and top of the Hera body.

In addition, a silicone alignment groove is formed at the center of the open bottom end side of the cover member, connected to the end discharge port of the extrusion passage, and disposed at a certain width to align the discharge path of the silicone resin and the silicone application interval.

In addition, a plurality of ring-shaped band portions that apply a first tightening pressure to the nozzle coupling portion are repeatedly formed at regular intervals to bring the inner peripheral surface of the nozzle coupling portion into close contact with the outer surface of the nozzle.

In addition, between the plurality of ring-shaped band portions, a second tightening pressure lower than the first tightening pressure is applied to the tubular nozzle coupling portion so that the inner peripheral surface of the nozzle coupling portion is in close contact with the outer surface of the nozzle. A thin band is formed to prevent the nozzle coupling portion from being pushed.

In addition, inside the ring-shaped band, a C-shaped structure with one side open is accommodated inside the ring-shaped band through a molding process, and a ring-shaped wire is formed to support the ring-shaped band.

In addition, a wire insertion groove is formed on the outer peripheral surface of the ring-shaped band portion, and the ring-shaped wire is mounted and coupled to the wire insertion groove.

According to another aspect, the nozzle-coupled Hera structure of a silicon container, which is a means of solving the problem of the present invention, includes a Hera body in which a silicon discharge space is formed at the bottom; and a nozzle coupling portion formed at one end of the bottom of the hera body and into which the nozzle is fitted so that the tip of the nozzle formed at the tip opening of the silicone container in which the silicone resin is filled is seated in the silicone discharge space. It includes.

Additionally, the Hera body is made of hard polyurethane material.

Additionally, a support having a coupling hole that prevents the hera body from bending is inserted into the hera body.

Additionally, the nozzle coupling portion is a ring-shaped band portion.

In addition, the nozzle coupling part is double-injected with the Hera body to form an integrated structure, and is made of a soft urethane material with a certain elasticity for fitting the nozzle.

Additionally, a pair of pull handles are formed on the nozzle coupling portion to enlarge the entrance of the nozzle coupling portion to guide the insertion depth of the nozzle into the nozzle coupling portion.

As such, the present invention is configured to safely and firmly couple the Hera structure to the nozzle area coupled with the discharge portion of the silicone container, regardless of the cut size, to control the discharge of silicone resin. This is achieved through the silicone gun through the silicone container. When the silicone resin is discharged, the bonding work of the discharged silicone resin is carried out and the finishing work of trimming through the hera structure is carried out immediately, thereby shortening the bonding work time of the silicone resin, increasing work efficiency, and using a separate hera. The effect of improving work inconvenience can be expected.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

Figure 1 is a perspective view showing a Hera structure in a first embodiment of the present invention.
Figure 2 is a cross-sectional schematic diagram showing the nozzle of the silicon container coupled to the Hera structure in the first embodiment of the present invention.
Figure 3 is a bottom view showing the Hera structure in the first embodiment of the present invention.
Figure 4 is a perspective view showing the Hera structure in the second embodiment of the present invention.
Figure 5 is a plan schematic diagram showing the nozzle of the silicon container coupled to the Hera structure in the second embodiment of the present invention.
Figure 6 is a side schematic view showing the nozzle of the silicone container coupled to the Hera structure in the second embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the attached drawings.

Figure 1 is a perspective view showing the Hera structure in the first embodiment of the present invention, Figure 2 is a cross-sectional schematic diagram showing the nozzle of the silicon container coupled to the Hera structure in the first embodiment of the present invention, and Figure 3 is the present invention. A bottom view showing the Hera structure as the first embodiment of the invention is shown.

Referring to the accompanying FIGS. 1 to 3, the nozzle-coupled hera structure of the silicon container according to an embodiment of the present invention includes a hera body 10 and a cover member 20, and/or a ring-shaped band portion 30. ) and a thin band portion 40, and a ring-shaped wire 50 may be further included.

The Hera body 10 is molded from a soft polyurethane material, and has a tubular nozzle coupling portion 11 at one end into which the nozzle 200 formed at the tip opening of the silicone container 100 filled with the silicone resin is fitted. ) is formed, and an extrusion passage 12 that communicates with the nozzle coupling portion 11 and guides the discharge of the silicone resin can be formed inside.

The nozzle coupling portion 11 is integrated with one end of the hera body 10 so that the outer peripheral surface of the nozzle 200 can be fitted or can be bent and deformed while being elastic for fitting with the nozzle cap 201. It is made of a soft polyurethane material, and the nozzle coupling part 11 is provided so that the entrance of the nozzle coupling part 11 can be enlarged to guide the insertion depth of the nozzle 200 into the nozzle coupling part 11. A pair of pull handles 11a can be formed.

That is, since the insertion diameter of the nozzle coupling part 11 can be changed by pulling the pair of pull handles 11a, the tip 200a of the nozzle 200 is exposed in the nozzle coupling part 11. Even if the cutting length is adjusted so that the cross-section is made small or large to control the amount of silicone resin, the nozzle 200 can be fitted regardless of the length.

The extrusion passage 12 may be formed to be inclined from one side of the hera body 10 toward the bottom of the hera body 10, and a discharge port 12a for discharging silicon is formed at its end.

The cover member 20 is molded from a hard polyurethane material with a predetermined elasticity so that its inner circumferential surface is in close contact with the side and top of the hera body 10, and one end is inserted into the tubular nozzle coupling portion 11. As it is combined, the bottom portion that is tightly coupled to the side and top of the Hera body 10 is opened.

At the center of the open bottom front end of the cover member 20, there is a silicone alignment groove of a band-shaped structure connected to the end discharge port 12a of the extrusion passage 12 and for aligning the discharge path of the silicone resin and the silicone application interval. 21) can be formed.

That is, in the Hera structure according to the first embodiment of the present invention, silicone resin is discharged through the nozzle 200, allowing for finishing bonding between various building materials, sealing of gaps, finishing edges, waterproofing, and stretching, vibration, and deformation between members. When the work to absorb and relax is performed, the finishing work of trimming the silicone resin on which the bonding work was performed can be carried out at the same time.

The ring-shaped band portion 30 is formed in plural numbers on the tubular nozzle coupling portion 11 while maintaining regular intervals, so that the inner peripheral surface of the nozzle coupling portion 11 is in close contact with the outer surface of the nozzle 200. A first tightening pressure is applied to the nozzle coupling portion 11.

The thin band portion 40 is formed between the plurality of ring-shaped band portions 30, and the nozzle coupling portion 11 is formed so that the inner peripheral surface of the nozzle coupling portion 11 is in close contact with the outer surface of the nozzle 200. ) while applying a second tightening pressure lower than the first tightening pressure to prevent the nozzle coupling portion 11 from being pushed from the outer surface of the nozzle 200.

The ring-shaped wire 50 is a C-shaped structure with one side open, and supports the ring-shaped band portion 30.

Here, the ring-shaped wire 50 is insert-accommodated inside the ring-shaped band portion 30 through a molding process, or is inserted into the wire insertion groove (not shown) when forming a wire insertion groove (not shown) on the outer peripheral surface of the ring-shaped band portion 30. It can be mounted and combined with.

In this way, the nozzle-coupled hera structure of the silicon container according to the embodiment of the present invention is first installed at the front end of the soft silicon container 100 through the nozzle cap 201, as shown in Figures 1 to 3 attached. In a state where 200 is coupled, the silicon container 100 is mounted on the silicon gun so that the nozzle 200 is exposed to the distal end of the silicon gun.

Thereafter, the nozzle 200 exposed to the outside of the silicon gun is inserted into the tubular nozzle coupling portion 11 of the hera body 10 made of a soft polyurethane material, and then the nozzle 200, which is exposed to the outside of the silicone gun, is inserted into the tubular nozzle coupling portion 11 of the hera body 10 made of a soft polyurethane material. It enters the extrusion passage (12).

That is, when the pair of pull handles 11a formed on the tubular nozzle coupling portion 11 are pulled, the insertion diameter of the tubular nozzle coupling portion 11 changes, and the nozzle 200 flows into the extrusion flow path. As it enters deep into the interior of (12), the tip (200a) of the nozzle (200) is adjacent to the discharge port (12a) formed at the end of the extrusion passage (12).

Here, even if the cutting length is adjusted so that the exposed cross section of the tip 200a of the nozzle 200 is made small or large to control the discharge of silicone resin, the nozzle 200 can be fitted regardless of the length. In addition, the inner peripheral surface of the tubular nozzle coupling portion 11 is formed by the ring-shaped band portion 30, the thin film band portion 30, and the ring-shaped wire 50 formed on the outer peripheral surface of the nozzle coupling pipe 11. While being in close contact with the outer circumferential surface of the nozzle 200, the nozzle 200 can maintain a firm connection that prevents slipping or separation from the nozzle coupling portion 11.

In addition, since the sides and top of the Hera body 20 made of a soft polyurethane material are covered by a cover member 20 molded from a hard polyurethane material, the Hera body 10 has structural stability. It is something that can be maintained.

Meanwhile, the silicone gun is operated while the nozzle 200 is fitted into the nozzle coupling portion 11 of the Hera body 10 as described above, and the silicone resin filled in the silicon container 100 is transferred to the nozzle 200. ), when the silicone resin is discharged to the joint area of the structure through the extrusion passage 12 and the discharge port 12a, it is discharged through the silicone alignment groove 21 extending from the discharge port 12a, thereby reducing the silicone application interval. By aligning the structures, the structure bonding work can be performed, and at the same time, when the operator moves the silicon gun, the Hera body 10, which is a Hera structure coupled to the nozzle 200, trims the silicone resin for bonding the structure. Finishing work can be done right away.

That is, in the Hera structure according to the first embodiment of the present invention, silicone resin is discharged through the nozzle 200, allowing for finishing bonding between various building materials, sealing of gaps, finishing edges, waterproofing, and stretching, vibration, and deformation between members. When the work to absorb and relax is carried out, the finishing work of trimming the silicone resin on which the bonding work was performed can be carried out at the same time.

Meanwhile, the attached FIGS. 4 to 6 show a Hera structure according to a second embodiment of the present invention.

In other words. Figure 4 schematically represents a perspective view showing the Hera structure in the second embodiment of the present invention, and Figure 5 is a plan schematic diagram showing the nozzle of the silicon container coupled to the Hera structure in the second embodiment of the present invention. Figure 6 is a side schematic view showing the nozzle of the silicone container coupled to the Hera structure in the second embodiment of the present invention.

The Hera structure according to the second embodiment of the present invention is made of a hard polyurethane material and includes a Hera body 10' with a silicone discharge space 10a formed at the bottom, and a bottom end of the Hera body 10'. A nozzle combination in which the nozzle 200 is fitted so that the tip 200a of the nozzle 200 formed at the tip opening of the silicone container 100 in which the silicone resin is filled is seated in the silicon discharge space 10a. Includes part 60.

Here, the nozzle coupling part 60 forms an integrated structure with the hera body 10', and is made of a hard urethane material with a certain elasticity for fitting of the nozzle 200, or a soft double-injected material. It can be molded from urethane material.

At this time, a support 70 may be insert molded into the Hera body 10' to prevent bending of the Hera body 10', and the support 70 may have a plurality of coupling holes 72 at a certain level. By providing perforations at intervals, the hera body 10' and the nozzle coupling portion 60, which are molded as one body, are maintained as a single body without being separated from the upper and lower layers by the insert.

The nozzle coupling portion 60 is also preferably configured as a ring-shaped band structure as shown in FIGS. 1 to 3, which is the first embodiment of the present invention.

In addition, the nozzle coupling part 60 includes a pair of devices that enable enlarging the entrance of the nozzle coupling part 60 to guide the insertion depth of the nozzle 200 into the nozzle coupling part 60. A pull handle 61 may be formed.

This can be compared to or the same structure as in the attached FIGS. 1 to 3, which is the first embodiment of the present invention.

That is, in the second embodiment of the present invention, as shown in the attached FIGS. 4 to 6, the nozzle coupling portion 60 is formed to replace the tubular nozzle coupling portion 11, while the first embodiment of the present invention As an element corresponding to the cover member 20 applied in , a support 70 is insert-molded inside the hera body 10', which reinforces the strength of the hera body 10'.

Accordingly, in the second embodiment of the present invention, as in the first embodiment of the present invention, the silicone resin is discharged through the nozzle 200 to provide finishing bonding between various building materials, sealing of gaps, finishing edges, waterproofing, and other materials. When the work to absorb and relieve mutual stretching, vibration, and deformation is performed, the finishing work of trimming the silicone resin on which the bonding work has been performed can be performed at the same time. Hereinafter, the same parts as in the first embodiment of the present invention are given the same reference numerals. By marking with , overlapping explanations have been omitted.

In the above, the technical idea of the nozzle-coupled hera structure of the silicon container of the present invention has been described along with the accompanying drawings, but this is an illustrative description of the most preferred embodiment of the present invention and does not limit the present invention.

Therefore, the present invention is not limited to the specific embodiments described above, and various modifications can be made by anyone skilled in the art without departing from the gist of the invention as claimed in the claims. Of course, such changes fall within the scope of the claims.

10, 10'; Hera body 10a; Silicone discharge space
11; tubular nozzle joints 11a, 61; pull handle
12; Extrusion oil path 12a; outlet
20; cover member 21; Silicone alignment groove
30; Ring-shaped band portion 40; thin film band
50; ring-shaped wire 60; nozzle joint
70; support 72; coupling hole
100; silicone container 200; Nozzle
201; nozzle cap

Claims (16)

A hera body having a tubular nozzle coupling portion into which a nozzle is fitted, which is formed at the tip opening of the silicone container in which the silicone resin is filled, and an extrusion passage that communicates with the nozzle coupling portion to guide discharge of the silicone resin. and,
a cover member with one end fitted into the nozzle coupling part and an open bottom tightly coupled to the side and top of the hera body; Including,
In the nozzle coupling portion, a plurality of ring-shaped band portions are repeatedly formed at regular intervals to apply a first tightening pressure to the tubular nozzle coupling portion so that the inner peripheral surface of the nozzle coupling portion is in close contact with the outer surface of the nozzle,
A pair of pull handles are formed on the nozzle coupling portion to enlarge the entrance of the nozzle coupling portion to guide the insertion depth of the nozzle into the nozzle coupling portion,
Between the ring-shaped band portions that are repeatedly formed, a second tightening pressure lower than the first tightening pressure is applied to the nozzle coupling portion so that the inner peripheral surface of the nozzle coupling portion is in close contact with the outer surface of the nozzle. A nozzle-coupled hera structure of a silicone container, characterized in that a thin band is repeatedly formed to prevent the portion from being pushed. According to claim 1,
A nozzle-coupled hera structure of a silicone container, wherein the hera body is made of a soft polyurethane material. According to claim 1,
The nozzle coupling part is a nozzle coupling type hera structure of a silicone container, characterized in that the outer peripheral surface of the nozzle is fitted or has elasticity for fitting a nozzle cap and is formed integrally with one end of the hera body. According to claim 1,
The nozzle-coupled hera structure of a silicone container, characterized in that the extrusion flow path is formed at an angle from one side of the hera body toward the bottom of the hera body. According to claim 4,
The cover member is a nozzle-coupled hera structure of a silicone container, characterized in that the inner peripheral surface is made of a hard polyurethane material with a predetermined elasticity so that the inner peripheral surface is covered in close contact with the sides and top of the hera body. According to claim 5,
A silicone alignment groove having a certain width is formed in the center of the open bottom tip of the cover member, which is connected to the end discharge port of the extrusion flow path and aligns the discharge path of the silicone resin and the silicone application interval. Nozzle combined hera structure. delete Hera body with a silicone discharge space formed at the bottom; and,
a nozzle coupling portion formed at one end of the bottom of the hera body and into which the nozzle is fitted so that the tip of the nozzle formed at the tip opening of the silicone container in which the silicone resin is filled is seated in the silicone discharge space; Including,
The nozzle coupling portion is a ring-shaped band structure formed repeatedly and forms an integrated structure with the hera body,
A pair of pull handles are formed on the nozzle coupling portion to enlarge the entrance of the nozzle coupling portion to guide the insertion depth of the nozzle into the nozzle coupling portion,
Between the ring-shaped band portions that are repeatedly formed, a second tightening pressure lower than the first tightening pressure applied by the ring-shaped band portion is applied to the nozzle coupling portion so that the inner peripheral surface of the nozzle coupling portion is in close contact with the outer surface of the nozzle. A nozzle-coupled hera structure of a silicone container, characterized in that a thin band is repeatedly formed on the outer surface to prevent the nozzle-coupling portion from being pushed. According to claim 8,
A nozzle-coupled hera structure of a silicone container, wherein the hera body is made of a hard polyurethane material. According to claim 8,
A nozzle-coupled hera structure of a silicone container, characterized in that a support bar is inserted into the hera body to prevent bending of the hera body. delete According to claim 8,
The nozzle coupling part is double-injected with the Hera body to form an integrated structure, and is made of a soft urethane material with a certain elasticity for fitting the nozzle. A nozzle-coupled Hera structure of a silicone container. delete delete According to claim 1 or 8,
Inside the ring-shaped band, a C-shaped structure with one side open is accommodated inside the ring-shaped band through a molding process, and a ring-shaped wire is formed to support the ring-shaped band. structure. According to claim 1 or 8,
A wire insertion groove is formed on the outer peripheral surface of the ring-shaped band portion, and a C-shaped ring-shaped wire open on one side is mounted and coupled to the wire insertion groove to support the ring-shaped band portion.