KR20230008312A - A structure for stud pin hole mold - Google Patents

Abstract

The present invention relates to a stud pinhole mold structure, and more specifically, to a stud pinhole mold structure which has a separable stud pinhole. Provided is a stud pinhole mold structure for mounting stud pins on a tire during a curing process. The stud pinhole mold structure comprises: a stud hole housing part (200) inserted and installed on a base mold (100) to have the same height as a tread surface of the tire, wherein the stud hole housing part (200) is detachably installed on the base mold (100); and a stud pin (300) which has one side inserted and fixed to the stud hole housing part (200) and the other side protruding out of the outside of the base mold (100) toward an opposite side of the stud hole housing part (200), wherein instead of being directly fixed to the base mold (100), the stud pin (300) is inserted and fixed to the stud hole housing part (200) previously fixed to the base mold (100). Accordingly, even when the stud pin (300) is bent or damaged, which may occur, the stud hole housing part (200) can be separated from the base mold (100). Therefore, the stud pin (300) can be changed even without damage to the base mold (100).

Description

Stud pin hole mold structure {A structure for stud pin hole mold}

The present invention relates to a stud pinhole mold structure, and more particularly, to a stud pinhole mold structure in which a stud pin holder is detachable.

In the case of conventionally produced studable tires, stud holes on molds are implanted and tap-type, and problems such as bending or breaking of tire stud holes occur after tire vulcanization.

When such a problem occurs, repair may not be possible, and even if it is repaired, there is a fatal problem that defects continuously occur due to durability degradation.

In other words, in the case of the conventional method, when the stud hole is bent or broken, it is difficult to restore the welding, so there is a problem in that the mold itself must be newly manufactured.

In particular, since the stud hole is difficult to detect from the outside of the tire, a tire having a defective stud hole may cause a big problem due to customer claims or safety reasons after sale.

KR 1093759 B1

In order to overcome the above problems of the prior art, the present invention provides a stud pinhole mold structure for supplementing the disadvantages of studable tires among winter tires and preventing defects during production and protecting mold damage that has its purpose.

In the stud pinhole mold structure for mounting the stud pin of a tire in the curing process, it is inserted into and installed in the base mold 100 to have the same height as the tread surface of the tire, and is detachably installed in the base mold 100 stud hole housing part 200; a stud pin 300 having one side inserted into and fixed to the stud hole housing part 200 and the other side protruding out of the base mold 100 toward the opposite side of the stud hole housing part 200; Includes a stud pinhole mold structure comprising a.

In addition, the stud hole housing part 200 includes an insertion hole accommodating one side of the stud pin 300, and the lower part of the insertion hole is an inner inclined part forming a tapered surface connecting the inner sidewall from the insertion hole (206); It includes a stud pinhole mold structure characterized by having a.

In addition, the stud hole housing part 200 includes a first diameter part 204 protruding in a direction spaced apart from the tread surface forming part 101 formed on the base mold 100 at a lower end; Including, but including a stud pin hole mold structure characterized in that the outer diameter of the second diameter portion 207 forming the insertion hole of the stud hole housing portion 200 is larger than the diameter of the first diameter portion 204 do.

In addition, the stud hole housing part 200 includes a stud pin hole mold structure characterized in that it has a hollow cylindrical shape having a predetermined thickness.

In addition, the stud hole housing part 200 includes a stud pin hole mold structure characterized in that it is screwed to the base mold 100.

In addition, the stud hole housing part 200 includes a stud pin hole mold structure characterized in that it is fastened to the base mold 100 through an interference fit.

In addition, the stud hole housing part 200 includes a stud pin hole mold structure characterized in that it is fastened to the base mold 100 in a tap manner.

In addition, the base mold 100 includes a first inner wall portion 102 to which the outer circumferential surface of the long radius of the stud hole housing portion 200 is in close contact; a second inner wall portion 103 on which the lower surface of the stud hole housing portion 200 is seated; a third inner wall portion 104 formed as a through hole so as to be able to enter the lower surface of the stud hole housing portion 200; Through-hole portion 105 that allows entry of the separation means 400 that contacts the lower surface of the stud hole housing portion 200 and allows the stud hole housing portion 200 to separate from the base mold 100. ); A stud pinhole mold structure comprising a.

In addition, the separating means 400 is formed in a rod shape and impacts the stud hole housing part 200 so that the stud hole housing part 200 can be separated from the base mold 100. contain the structure

In addition, the separation means 400 is screwed to the lower surface of the stud hole housing 200 to rotate the stud hole housing 200 so that the stud hole housing 200 is removed from the base mold 100. It includes a stud pinhole mold structure characterized in that it is separable.

According to the present invention as described above, there are the following effects.

First, the stud pin 300 is not directly fixed to the base mold 100, but is inserted and fixed into the stud hole housing part 200 pre-fixed to the base mold 100, so that the stud pin 300 may occur. Since the stud hole housing part 200 can be separated from the base mold 100 even when the pin 300 is whipped or damaged, the stud pin 300 can be replaced without damaging the base mold 100. exerted

Second, when the stud pin 300 is inserted downward toward the insertion hole, the lower end of the leg part 306 can be in close contact with the inner lower surface part 202 and the inner inclined part 206, so more secure fixation. The advantage of making this possible is demonstrated.

Third, since the leg part 306 contacts the tread surface adjacent part 201, the advantage of being able to designate the limit of the insertion depth into which the stud pin 300 is inserted into the insertion hole is exhibited.

1 is a cross-sectional view in which a stud pin 300 according to a preferred embodiment of the present invention is coupled to a stud hole housing part 200 provided in a base mold 100
2 is a part of a cross section in which a stud pin 300 according to a preferred embodiment of the present invention is coupled to a stud hole housing part 200 provided in a base mold 100.
3 shows that the stud pin 300 according to a preferred embodiment of the present invention is coupled to the stud hole housing part 200 provided in the base mold 100, and the stud pin 300 is removed using the separating means 400. Appearance for separation from the hole housing part 200

Since the present invention can make various changes and have various embodiments, specific embodiments will be illustrated in the drawings and described in detail in the detailed description. However, this is not intended to limit the present invention to specific embodiments, and should be understood to include all modifications, equivalents, or substitutes included in the spirit and technical scope of the present invention.

In describing each figure, like reference numbers are used for like elements.

Terms such as first and second may be used to describe various components, but the components should not be limited by the terms. These terms are only used for the purpose of distinguishing one component from another.

For example, a first element may be termed a second element, and similarly, a second element may be termed a first element, without departing from the scope of the present invention. The term "and/or" includes any combination of a plurality of related listed items or any of a plurality of related listed items.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs.

Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related art, and unless explicitly defined in this application, it should not be interpreted in an ideal or excessively formal meaning. Should not be.

Referring to the directionality to be described below, “downward” or “downward direction” refers to a direction from the head part 301 to the body part 302 based on FIG. 1, and “diameter” refers to the “downward direction” It can be understood as meaning the radius in the direction (horizontal direction) forming a right angle to the "downward direction" or "downward direction."

On the other hand, "taper" can be shifted from "below" or "downward" to making an inclination toward the horizontal direction.

The base mold 100 may include a tread surface forming unit 101 forming a tread surface of a tire.

The stud pin 300 may include a head part 301, a body part 302, a first taper part 303, a second taper part 304, a flange part 305 and a leg part 306. .

The head portion 301 has a T-shaped cross section at the upper end of the body portion 302, and the lower surface of the head portion 301 while the body portion 302 has a diameter smaller than that of the head portion 301. extends downwards from

The first tapered portion 303 is formed as a tapered surface such that its diameter increases from the bottom of the body portion 302 downward.

The second taper portion 304 has a larger diameter than the first taper portion 303 and has a larger diameter than the diameter of the head portion 301 and is tapered so that the diameter increases as it goes downward.

The leg portion 306 extends short from the outermost edge of the flange portion 305 in a downward direction perpendicular to the horizontal direction.

The outermost diameter of the flange portion 305 may be the largest among the diameters of the stud pin 300 .

The lower surface of the flange portion 305 is in close contact with the adjacent portion 201 of the tread surface.

The leg portion 306 extends long downward from the lower surface of the flange portion 305, and may preferably have a larger diameter than the diameter of the body portion 302.

Meanwhile, the length of the leg portion 306 may be the same as that of the body portion 302 .

In addition, the diameter of the leg portion 306 may be larger than the outermost diameter of the head portion 301 .

The end shape of the lower part of the leg part 306 may be formed to be tapered so that the diameter decreases as it goes downward.

This is to be closely fixed to the inner lower surface portion 202 and the stepped portion 205 formed in the stud hole housing portion 200 to be described later.

The stud hole housing part 200 includes a tread surface adjacent part 201, an inner lower surface part 202, a root part 203, a first diameter part 204, a stepped part 205, an inner inclined part 206, and It may include a second diameter portion 207 .

The tread surface adjacent portion 201 may have the same curvature as the tread surface forming portion 101 , and the lower surface of the flange portion 305 of the stud pin 300 is in close contact with the tread surface adjacent portion 201 .

The stud hole housing part 200 has an insertion hole accommodating the leg part 306 formed therein, and the inner lower surface part 202 is the bottom surface of the insertion hole.

The inner inclined portion 206 may be formed as a tapered surface connecting the inner sidewall from the insertion hole.

The first diameter portion 204 forms the lowermost portion of the stud hole housing portion 200 and protrudes downward, and the root portion 203 forms the lowermost portion of the first diameter portion 204 .

The second diameter part 207 is a part forming the outermost part of the stud hole housing part 200, and is a hollow cylinder having a predetermined thickness as a whole, and it may be preferable to be detachably fixed inside the base mold 100. there is.

The stepped portion 205 is a portion connecting the first diameter portion 204 and the second diameter portion 207 and extends horizontally.

The stepped portion 205 prevents the stud hole housing portion 200 from being disengaged in a downward direction when the stud hole housing portion 200 is fixed to the base mold 100 .

In other words, the stud hole housing part 200 may be separated from the base mold 100 by moving in the direction indicated by an arrow in FIG. 3 , that is, upward.

That is, the stud hole housing part 200 can be detachably installed on the base mold 100 .

Next, referring to FIG. 2 , fixing the stud pin 300 to the stud hole housing 200 will be described.

The leg part 306 formed on the stud pin 300 is inserted into the insertion hole formed in the stud hole housing part 200 .

In other words, the leg portion 306 is inserted into the insertion hole, which is a space formed by the inner wall of the inner lower surface portion 202, the inner inclined portion 206, and the second diameter portion 207.

At this time, when the stud pin 300 is inserted downward toward the insertion hole, the lower end of the leg portion 306 is more alert because it can be in close contact with the inner lower surface portion 202 and the inner inclined portion 206. The advantage of being able to be fixed is exhibited.

On the other hand, since the leg portion 306 contacts the tread surface adjacent portion 201, the advantage of being able to designate the limit of the insertion depth into which the stud pin 300 is inserted into the insertion hole is exhibited.

Therefore, the stud pin 300 can be easily and accurately inserted into and fixed to the insertion hole provided in the stud hole housing part 200 .

The leg portion 306 may be tapped or force-fitted into the insertion hole of the stud hole housing portion 200 .

On the other hand, a screw thread (not shown) is provided on the outer circumferential surface of the leg portion 306, and it may be preferable that the screw thread (not shown) formed in the insertion hole of the stud hole housing part 200 can be screwed.

In this way, the stud pin 300 is not directly fixed to the base mold 100, but is inserted and fixed into the stud hole housing part 200 pre-fixed to the base mold 100. Since the stud hole housing part 200 can be separated from the base mold 100 even when the pin 300 is whipped or damaged, the stud pin 300 can be replaced without damaging the base mold 100. exerted

Meanwhile, as shown in FIG. 3 , the separating means 400 may be used as a method of separating the stud hole housing part 200 from the base mold 100 .

That is, the stud hole housing part 200 may be detachably closely fixed to the first inner wall part 102 and the second inner wall part 103 formed in the base mold 100 .

At this time, a through hole portion 105 is formed in the base mold 100 , and the through hole portion 105 is a long and narrow through hole that penetrates the center of the second inner wall portion 103 .

Therefore, since the separation means 400 has a smaller diameter than the inner diameter of the through-hole portion 105, it is inserted through the through-hole portion 105 and can contact the lower surface of the stud hole housing portion 200.

Therefore, when the stud hole housing part 200 is pressed in the direction of the arrow using the separation means 400 in order to be separated from the base mold 100, the stud hole housing part 200 moves upward from the base mold 100. As it breaks away, it becomes separable.

On the other hand, as described above, if the stud hole housing part 200 is fixed to the base mold 100 by applying a screw thread (not shown), the separating means 400 rotates the stud hole housing part 200. It may be a possible driver.

100: base mold
101: tread surface forming unit
102: first inner wall portion
103: second inner wall portion
104: third inner wall portion
105: through hole
200: stud hole housing part
201: adjacent portion of the tread surface
202: inner lower surface
203: root
204: first diameter part
205: stepped part
206: inner slope
207: second diameter part
300: stud pin
301: head part
302: body part
303: first taper part
304: second taper part
305: flange part
306: leg part
400: separation means

Claims (10)

In the stud pin hole mold structure for mounting the stud pin of the tire in the curing process,
a stud hole housing part 200 inserted into and installed in the base mold 100 to have the same height as the tread surface of the tire and detachably installed in the base mold 100;
a stud pin 300 having one side inserted into and fixed to the stud hole housing part 200 and the other side protruding out of the base mold 100 toward the opposite side of the stud hole housing part 200; including,
Stud pinhole mold structure.
According to claim 1,
The stud hole housing part 200 includes an insertion hole accommodating one side of the stud pin 300,
The lower portion of the insertion hole has an inner inclined portion 206 forming a tapered surface connecting the inner sidewall from the insertion hole; characterized by having
Stud pinhole mold structure.
According to claim 2,
The stud hole housing part 200 includes a first diameter part 204 protruding in a direction spaced apart from the tread surface forming part 101 formed on the base mold 100 at a lower end; Including,
Characterized in that the outer diameter of the second diameter portion 207 forming the insertion hole of the stud hole housing portion 200 is larger than the diameter of the first diameter portion 204,
Stud pinhole mold structure.
According to claim 1,
Characterized in that the stud hole housing portion 200 is a hollow cylindrical shape having a predetermined thickness,
Stud pinhole mold structure.
According to claim 1,
Characterized in that the stud hole housing part 200 is screwed to the base mold 100,
Stud pinhole mold structure.
According to claim 1,
Characterized in that the stud hole housing part 200 is fastened to the base mold 100 by an interference fit.
Stud pinhole mold structure.
According to claim 1,
Characterized in that the stud hole housing part 200 is fastened to the base mold 100 in a tap manner.
Stud pinhole mold structure.
According to claim 1,
The base mold 100 includes a first inner wall portion 102 to which the outer circumferential surface of the long radius of the stud hole housing portion 200 is in close contact;
a second inner wall portion 103 on which the lower surface of the stud hole housing portion 200 is seated;
a third inner wall portion 104 formed as a through hole so as to be able to enter the lower surface of the stud hole housing portion 200;
Through-hole portion 105 that allows entry of the separation means 400 that contacts the lower surface of the stud hole housing portion 200 and allows the stud hole housing portion 200 to separate from the base mold 100. ); Characterized in that it includes,
Stud pinhole mold structure.
According to claim 8,
Characterized in that the separation means 400 is formed in a rod shape and impacts the stud hole housing portion 200 so that the stud hole housing portion 200 can be separated from the base mold 100.
Stud pinhole mold structure.
According to claim 8,
The separation means 400 is screwed to the lower surface of the stud hole housing 200 to rotate the stud hole housing 200 so that the stud hole housing 200 can be separated from the base mold 100. characterized in that,
Stud pinhole mold structure.

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