KR200465130Y1 - Silicon injection apparatus - Google Patents

Abstract

The present invention is detachably coupled to the main body is coupled to the cartridge containing the silicon, the connection body having a nozzle at the end; A movable bracket formed at an opposite end to surround the outer circumferential surface of the connecting body while allowing elastic deformation, and being reciprocated along the longitudinal direction of the connecting body; A moving support bar formed along a longitudinal direction of the connection body in a shape corresponding to the moving groove formed on the inner side of the moving bracket to support the reciprocation of the moving bracket; A pressure plate that is rotatably coupled to one side of the moving bracket to press the injected silicon toward the work target surface; And an extension piece extending from both ends of the moving bracket to face each other and interlocking with each other in conjunction with the elastic deformation of the moving bracket, to cleanly perform the silicon construction on the surface to be worked from the structure. In addition, the present invention relates to a silicon injector for freely controlling the thickness of silicon to be constructed.

Description

Silicon Injector {SILICON INJECTION APPARATUS}

The present invention relates to a silicon injector, and more particularly, to a silicon injector to be able to cleanly perform the silicon construction on the work target surface, as well as to freely control the thickness of the silicon to be constructed.

Silicone is usually used for the construction of windows and doors, to fill cracks and gaps, and for places where airtightness is required.

The operator performs the sealing operation by fixing the cartridge to a so-called silicon gun, and operating the lever provided in the silicon gun to apply the silicon contained in the cartridge to the work target surface while pressurizing and spraying the silicon contained in the cartridge in one direction.

However, the general silicon gun had no function of controlling the construction state of the silicon once the silicon was applied to the work surface.

Therefore, the general silicon gun is very different in the construction state of the applied silicone according to the skill level, so if the less skilled worker applied the silicon on the work surface, the construction surface of the silicon is not smooth to cause leakage and construction defects thereafter. Will be.

In addition, since the silicon gun is sprayed from the nozzle, the general silicon gun has no function of adjusting the thickness of the injected silicon, thereby providing a cause that the construction surface of the silicon is not smooth as described above.

Patent Application No. 10-1999-0038838 Utility Model Application No. 20-2009-0003979 Utility Model Application No. 20-2010-0006172

The present invention is designed to improve the above problems, it is to provide a silicon injector to be able to perform a clean silicon construction on the work target surface, as well as to freely control the thickness of the silicon to be constructed.

In order to achieve the above object, the present invention, a removable body coupled to the cartridge is coupled to the body containing the silicon, the connection body having a nozzle at the end; A movable bracket formed at an opposite end to surround the outer circumferential surface of the connecting body while allowing elastic deformation, and being reciprocated along the longitudinal direction of the connecting body; A moving support bar formed along a longitudinal direction of the connection body in a shape corresponding to the moving groove formed on the inner side of the moving bracket to support the reciprocation of the moving bracket; A pressure plate that is rotatably coupled to one side of the moving bracket to press the injected silicon toward the work target surface; And an extension piece extending from both ends of the moving bracket to face each other, and allowing the mutually adjacent or spaced apart in conjunction with the elastic deformation of the moving bracket.

Here, the silicon injection device according to an embodiment of the present invention, a plurality of positioning grooves formed at equal intervals along the longitudinal direction of the moving support bar, and protruding in a shape corresponding to the positioning groove from the moving groove of the moving bracket It is preferable to further include a positioning protrusion.

At this time, the silicon injector according to an embodiment of the present invention, it is preferable to further include a fixing pin that is detachably coupled through each of the extension pieces.

In addition, according to another embodiment of the present invention, the cartridge assembly is silicon; A main body to which the cartridge assembly is detachably coupled; A first unit that is expandable from one end of the main body and presses the cartridge assembly in one direction; And a connection body detachably coupled to the cartridge assembly, having a nozzle at an end thereof, and a connecting body coupled to a moving bracket reciprocating along the longitudinal direction, and a pressing plate for rotatably coupled to the moving bracket to press the injected silicon toward the work target surface. It may also provide a silicon injector comprising a second unit.

On the other hand, according to another embodiment of the present invention, a cartridge containing silicon; A main body detachably coupled to the cartridge and elastically adjustable in length; A connecting body detachably coupled to the cartridge, having a nozzle at an end thereof, and a connecting body coupled to a moving bracket reciprocating along the longitudinal direction, and a pressing plate for rotatably coupled to the moving bracket to press the injected silicon toward the work target surface; 1 unit; And a second unit selectively detachably coupled to the cartridge or the main body and exerting an air pressure to push the silicon toward the first unit. The silicon injector may be provided.

According to the present invention of the configuration as described above, from the configuration of the pressure plate that is rotatably coupled to the connection body provided with a nozzle at the end can be made to apply the silicon to a uniform thickness on the work target surface.

In addition, the present invention allows the operator to properly adjust the position of the pressure plate from the mutual coupling structure of the movable bracket and the movable support bar and to fix the extension pieces by contacting each other so that the pressure control applied to the silicon sprayed on the work surface can be varied. do.

1 is a perspective view showing the structure of a silicon injector according to an embodiment of the present invention
2 is a conceptual view showing the structure of a silicon injector according to another embodiment of the present invention
3 is a conceptual view showing the structure of a silicon injector according to another embodiment of the present invention

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the present invention.

1 is a perspective view showing the structure of a silicon injector according to an embodiment of the present invention.

The present invention can be seen that the structure including a connecting body 10, the moving bracket 20, the moving support bar 30, the pressure plate 40 and the extension piece 50 as shown.

The connection body 10 is detachably coupled to the main body 600 to which the cartridge 500 containing the silicon (see FIG. 3) is coupled, and the nozzle 700 is provided at an end thereof. It provides a space in which the support bar 30 is formed.

The moving bracket 20 is formed in a ring shape facing both ends to surround the outer circumferential surface of the connecting body 10 while allowing elastic deformation, and to be reciprocated along the longitudinal direction of the connecting body 10, and the pressure plate 40 to be described later. It provides space for mounting.

The moving support bar 30 is formed along the longitudinal direction of the connecting body 10 in a shape corresponding to the moving groove 22 formed on the inner side of the moving bracket 20 to support the reciprocation of the moving bracket 20. Do this.

The pressure plate 40 is rotatably coupled to one side of the moving bracket 20 to press the injected silicon toward the work target surface side to serve to apply the silicon to the work target surface (hereinafter not shown) with a uniform thickness. do.

The extension pieces 50 extend from both ends of the moving bracket 20 to face each other, and are members that allow mutual proximity or separation from each other in conjunction with the elastic deformation of the moving bracket 20.

On the other hand, the moving bracket 20 and the plurality of positioning grooves 31 formed at equal intervals along the longitudinal direction of the moving support bar 30 so that the position can be adjusted while reciprocating along the forming direction of the moving support bar 30 and In addition, the embodiment in which the positioning protrusions 21 protruding from the moving grooves 22 of the moving brackets 20 in a shape corresponding to the positioning grooves 31 may be applied to each other.

In addition, the silicon injector according to an embodiment of the present invention preferably further includes a fixing pin 52 which is detachably coupled through each of the extension pieces 50.

Therefore, the worker couples the connecting body 10 to the main body 600, separates the fixing pin 52 from the extension piece 50 once, and the extension pieces 50 are spaced apart from each other so that the inner diameter of the moving bracket 20 is increased. The moving bracket 20 is moved to an appropriate position along the moving support bar 30 by deforming in a larger direction.

Next, the operator checks the state in which the positioning projection 21 is coupled to the positioning groove 31, fastens the fixing pin 52 to the extension piece 50, and then moves the pressure plate 40 to the moving bracket 20. ) To be inclined at an appropriate angle with the end of the nozzle 700, and then pressurized from the cartridge 500 to be sprayed through the nozzle 700 to be installed on the work target surface.

The present invention is applicable to the embodiment as described above, mounting the connection body 10 according to an embodiment of the present invention to the cartridge assembly 600, as shown in Figure 2, or the hopper of the cartridge 500 as shown in FIG. Application of the embodiment to mount the connection body 10 according to an embodiment of the present invention to 510 is also possible.

First, the present invention, as shown in Figure 2, the first unit 100 is mounted to one end of the main body 500 to which the cartridge assembly 600 is detachably coupled to press the silicon in one direction, the second to the cartridge assembly 600 Application of the embodiment in which the unit 200 is mounted and sprays the pressurized silicon through the nozzle 700 is also possible.

The main body 500 provides a space in which the cartridge assembly 600 in which silicon is embedded is detachably coupled and in which the first and second units 100 and 200 to be described later are mounted.

The first unit 100 is stretchable from one end of the main body 500 and serves to press the cartridge assembly 600 in one direction.

The second unit 200 is detachably coupled to the cartridge assembly 600, the nozzle 700 is provided at the end and the connecting body 10 is coupled to the moving bracket 20 reciprocating along the longitudinal direction, and the moving bracket 20 It is to include a pressing plate 40 for pressing the silicon injected to be rotatably coupled to the toward the working target surface side.

Therefore, the operator properly adjusts the length of the entire apparatus using the first unit 100, and then adjusts the appropriate injection angle and position to press the second unit 200.

Thereafter, when the operator presses the silicon of the cartridge assembly 600 in one direction with the first unit 100, the silicon is injected through the second unit 200, and the injected silicon changes the moving direction of the second unit 200. Accordingly, the pressure plate 40 is to press the silicon in close contact with the work target surface.

On the other hand, the cartridge assembly 600 may be used by selecting the appropriate two types as shown.

That is, the cartridge assembly 600 is used to transfer the silicon released in the vacuum packaging form to the hopper 610, and the like, and the cartridge 800 containing silicon at the time of release the receiving frame 640 The embodiment can be selectively carried out so that it can be used as it is mounted on.

Specifically, the cartridge assembly 600 may be provided with a claw 620 in the hopper 610, and the pressure cylinder 630 may apply a structure in which the silicon in the hopper 610 is pressed in one direction.

The hopper 610 forms an internal space in which silicon is embedded, one end of which is coupled to the first unit 100, and the other end of which includes an outlet 612 that is detachably coupled to the second unit 200.

The protrusion piece 620 protrudes from the hopper 610 to correspond to at least one or more slots 520 formed on the bottom surface of the main body 500.

The pressure cylinder 630 is detachably coupled to an end of the unit rod 123 constituting the first unit 100 and the pressure rod 124 which will be described later to pressurize toward the outlet 612 from one end of the hopper 610. It is.

In addition, the cartridge assembly 600 is specifically, a protrusion piece 650 is provided in the receiving frame 640 for seating the cartridge 800, the pressing piece 660 is a structure for pressing the silicon in the cartridge 800 in one direction. You can also apply

Receiving frame 640 is provided with a fixing ring 642 at both ends, and provides a space in which the cartridge 800, the silicon embedded therein is detachably coupled.

The protrusion piece 650 protrudes from the receiving frame 640 to correspond to at least one or more slots 520 formed on the bottom surface of the main body 500.

The pressing piece 660 is detachably coupled with the first unit 100 to pressurize toward one end of the cartridge 800 from one end of the cartridge 800 seated on the receiving frame 640.

Here, the second unit 200 to be described later is detachably coupled to the other end of the cartridge 800.

At this time, the slot 520 has a narrower width than the slot 520 from one side of the secondary slot 522 is formed, between the neck piece 620 and the hopper 610 is narrower than the neck piece 620 neck 622 ) Is provided, and the neck 652 having a narrower width than the stone piece 650 is preferably provided between the stone piece 650 and the receiving frame 640.

Therefore, after the protrusion pieces 620 and 650 are accommodated in the slot 520 and the necks 622 and 652 move to the ends of the auxiliary slots 522, the fixing lever 510 provided on one side of the main body 500 can be manipulated. Although not shown, a hook for protruding inwardly of the main body 500 at the end of the fixing lever 510 is fixed to the necks 622 and 652 to secure the fastening of the cartridge assembly 600 to the main body 500. Can be done.

On the other hand, the first unit 100 is mounted on the main body 500 as described above to properly stretch the length of the entire device, and serves to press the silicon of the cartridge assembly 600 in one direction, the stretch assembly ( It can be seen that the structure including the 110 and the pressing assembly 120.

The stretchable assembly 110 includes a cylinder 111 mounted at one end of the main body 500, a stretchable rod 112 extending in and out of the cylinder 111 so as to extend or contract from the cylinder 111, and a stretchable rod mounted on the cylinder 111. And a button switch 113 for determining the extended or retracted position of the 112.

The pressing assembly 120 is coupled to the pressing lever 122 and the bracket 112 'rotatably coupled to the fixed lever 121 extending from the bracket 112' provided at the end of the elastic rod 112. And it is provided with the pressure rod 124 which the edge part moves toward the other end side of the main body 500 by operation of the pressure lever 122. As shown in FIG.

In addition, the pressure rod 124 has a plurality of unit rods (123, 123 ') of different diameters are built in so that the unit rods (123, 123') to correspond to the maximum extension length and the maximum contraction length of the elastic rod 112 It is preferred that each is stretched or shrunk in a telescopic manner.

Here, although not specifically illustrated in each of the unit rods 123 and 123 ', a plurality of holes are formed in the lengthwise direction, and the safety pins are fitted into the holes to press the silicon of the cartridge assembly 600 in one direction. Each of the unit bars 123 and 123 'constituting the pressure bar 124 is not contracted, and thus the length set initially can be maintained as it is.

On the other hand, according to the present invention, as shown in FIG. 3, the first unit 100 detachably coupled to the hopper 510 of the cartridge 500 presses the silicon applied to the work target surface (hereinafter, not shown), and the second unit 200. It is also possible to apply an embodiment in which) pressurizes the silicon in the cartridge 500 to the first unit 100 side by the air pressure.

The main body 600 is a cartridge 500 in which silicon is embedded and is detachably coupled and stretchable to be adjustable in length, and provides a space in which the first and second units 100 and 200 to be described later are mounted.

The first unit 100 is detachably coupled to the hopper 510 of the cartridge 500, the nozzle 700 is provided at the end and the connecting body 10 is coupled to the moving bracket 20 reciprocating along the longitudinal direction, It includes a pressing plate 40 for rotatably coupled to the moving bracket 20 to press the injected silicon toward the work target surface side.

The second unit 200 is selectively detachably coupled to the cartridge 500 or the main body 600, and acts on air pressure for pushing the silicon toward the first unit 100.

Therefore, the operator stretches and contracts the main body 600 properly to adjust the overall length, and then adjusts the position to press the first unit 100.

Thereafter, when the operator applies air pressure to the cartridge 500 through the second unit 200, silicon is injected through the first unit 100, and the injected silicon is formed along the moving direction of the first unit 100. While the pressing plate 40 of the unit 100 is pressed, the silicon is brought into close contact with the work target surface.

As described above, the cartridge 500 accommodates the silicon to be applied to the work target surface, and it can be understood that the cartridge 500 includes the hopper 510 and the air injection hole 530.

The hopper 510 forms an internal space in which silicon is embedded, one end of which is in communication with the second unit 200, and the other end of which is provided with an outlet that is detachably coupled to the first unit 100.

The air inlet 530 is formed at one end of the hopper 510 so as to be detachable from the second unit 200, and an air pressure is applied from one end of the hopper 510 toward the outlet 512.

Meanwhile, as described above, the main body 600 is stretchable to adjust the length of the entire apparatus, and has a structure in which a rod 630 is disposed between the first detachment port 610 and the second detachment port 620.

The first detachment opening 610 is a member detachably coupled to the cartridge 500, the second detachment opening 620 is coupled to the end of the rod 630, and the rod 630 is separated from the first detachment opening 610. It is a member that allows overall length adjustment while entering and leaving.

As described above, it can be seen that the present invention has a basic technical idea to provide a silicon injector that can cleanly perform a silicon construction on a work target surface and also freely control the thickness of the silicon to be constructed. .

Needless to say, many other modifications and applications are possible for those skilled in the art within the scope of the basic technical idea of the present invention.

10 ... Connection body
20.Moving Bracket
30.Moving Support Bar
40.Pressure plate
50 ... Extended

Claims (5)

A connection body 10 detachably coupled to a main body 600 to which a cartridge 500 for accommodating silicon is coupled and having a nozzle 700 at an end thereof;
A movable bracket 20 formed at opposite ends to surround the outer circumferential surface of the connection body 10 while allowing elastic deformation and reciprocating along the longitudinal direction of the connection body 10;
The moving support bar 30 is formed along the longitudinal direction of the connecting body 10 in a shape corresponding to the moving groove 22 formed on the inner side of the moving bracket 20 to support the reciprocation of the moving bracket 20. );
A plurality of positioning grooves 31 formed at equal intervals along the longitudinal direction of the movable support bar 30;
A positioning protrusion (21) protruding from the moving groove (22) of the moving bracket (20) in a shape corresponding to the positioning groove (31);
A pressing plate 40 which is rotatably coupled to one side of the moving bracket 20 to press the injected silicon toward the work target surface side; And
And an extension piece 50 extending from both ends of the moving bracket 20 so as to face each other and interlocking with each other in conjunction with an elastic deformation of the moving bracket 20. Device.
delete The method according to claim 1,
The silicon injector,
Silicon injection device characterized in that it further comprises a fixing pin 52 which is detachably coupled through each of the extension pieces (50).
delete delete

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