KR20210056937A - Strut bearing manufacturing equipment - Google Patents

Abstract

A production device for producing a strut bearing through a multi-injection process according to an embodiment of the present invention comprises: a first mold part into which an insert having a plurality of through-holes is inserted, and which molds a first injection-mold product formed of a hollow body and a flange part extending from one side of the body; a second mold part for molding a second injection-mold product in which a sealing part is further molded along one side inner and outer peripheral surfaces of the flange part; and a third mold part for molding a third injection-mold product in which a damper part is further formed on the other side of the flange part and on the outside of a part of the body. The first mold part comprises: a first lower mold into which the insert is inserted and fixed; and a first upper mold coupled to the first lower mold to form a first molding space. The first upper mold has an extension forming protrusion forming an extension part extending inwardly from an outer circumferential surface of one side of the flange part. It is possible to realize automation of the entire process, and improve product productivity and reliability.

Description

Strut bearing manufacturing equipment

The present invention relates to an apparatus for manufacturing a strut bearing, and more particularly, to an apparatus for manufacturing a strut bearing through a multiple injection process.

Multi-injection is a manufacturing method for molding a single product with materials of different materials or colors, and is an injection method used as the demand for improving the appearance quality increases.

In the multi-injection method, the injection step of injecting again on the intermediate injection product that has passed through the injection step is carried out several times, and the mold structure is complicated as the mold or core is rotated for the next injection step after the injection step, or the rearrangement of the injection product is required. , There was a problem of increasing man-hours and required time of the manufacturing process.

Accordingly, the multi-injection manufacturing apparatus has increased interest in the method of transferring intermediate injection products using a robot transfer device, and after performing the injection step using a servo robot, an end effector equipped with a chucking unit and a transfer means, By allowing the injection step to be carried out automatically, manpower consumption is reduced and processing time is shortened.

However, even when an injection manufacturing device using a robot transfer device is used, automation can be realized only in some stages depending on the injection conditions, and if the conditions are not met, manpower input is inevitable, resulting in reduced workability and increased production time. There was a problem that product productivity was deteriorated.

The embodiment of the present invention has been devised to solve the above problems, and at the same time, it is possible to achieve triple injection without rearrangement of intermediate injection products while improving the durability and reliability of the product, thereby realizing the automation of the entire manufacturing process. It is an object of the present invention to provide a manufacturing apparatus.

In the manufacturing apparatus for manufacturing a strut bearing through a multi-injection process according to an embodiment of the present invention, in order to solve the above problems, an insert having a plurality of through-holes is inserted, a body having a hollow body, and a body extending from one side of the body. A first mold part for molding a first injection product formed of a flange part; A second mold part for molding a second injection product in which a sealing part is further formed along an inner and outer circumferential surface of one side of the flange part; And a third mold portion for molding a third injection product having a damper portion further formed on the other side of the flange portion and an outer portion of the body portion, wherein the first mold portion is inserted and fixed to the insert. It is formed of a car lower mold and a first upper mold that is coupled to the first lower mold to form a first molding space, and the first upper mold extends inward from an outer circumferential surface of one side of the flange portion. It is characterized in that the expansion portion forming protrusion forming the expansion portion is formed.

The first lower mold may be provided with a first fixing pin having a fixing protrusion penetrating through a part of the through hole, and a first support pin disposed at one side of the remaining through hole, and the first upper part In the mold, the expansion part molding protrusion may be formed corresponding to the position of the support pin and a coupling pin having a coupling hole coupled to the fixing protrusion.

It is preferable that the first fixing pin and the first support pin are formed by mixing to have a predetermined pattern at the position of the through hole, and at least three first fixing pins are spaced apart from each other at a predetermined interval based on the central axis of the hollow. It is preferable that it is formed above.

The first injection product is formed with a first through part in communication with a part of the through hole in the flange part, and a second through part in communication with the expansion part and the rest of the through hole, and the third mold part 1 An injection hole disposed at one side of the through part may be formed, and a third forming space may be formed at the other side of the first through part.

As described above, according to the problem solving means of the present invention, various effects including the following can be expected. However, the present invention is not established when all of the following effects are exhibited.

In the strut bearing manufacturing apparatus according to the present invention, an expansion part forming protrusion forming an expansion part extending inward from one outer circumferential surface of the flange part is formed on the first upper mold to provide a fixed force between the housing and the sealing part.

In addition, the first mold part is provided with a first fixing pin and a coupling pin that are coupled to each other so that a first through part is formed on the outer circumferential surface of the flange part, so that raw materials can be injected to the opposite side of the damper part, thereby triple injection of the second injection product. Of automation.

At least three first fixing pins are spaced apart from each other by a predetermined distance and formed along one side of the flange portion so that each component of the injection product can be molded at a more accurate position, thereby improving the reliability of the product.

1 is a strut bearing manufacturing apparatus according to an embodiment of the present invention.
Figure 2 is an exploded perspective view of the first mold part of Figure 1;
3(a) is a perspective view of the first lower mold of FIG. 2 in a different direction, and FIG. 3(b) is a perspective view of the first upper mold of FIG. 2 in another direction.
4 is a cross-sectional perspective view of a portion of a fixed groove forming portion in a state in which a first injection product is formed in the first mold portion of FIG. 2;
FIG. 5(a) is an enlarged cross-sectional view of a portion in which the first fixing pin of the first mold part of FIG. 2 is disposed, and FIG. 5(b) is a part of the part where the first support pin of the first mold part of FIG. 2 is disposed. Sectional enlarged view.
6 is an exploded perspective view of the second mold part of FIG. 1.
7(a) is a perspective view of the second lower mold and the sealing part of FIG. 6 in different directions, and FIG. 7(b) is a perspective view of the second upper mold of FIG. 6 in another direction.
8 is a cross-sectional view taken along the BB direction in a state in which a second injection product is formed in the second mold part of FIG.
9(a) is an enlarged cross-sectional view of a portion in which the second fixing pin is disposed in the second mold part of FIG. 6, and FIG. 9(b) is a part in which the second support pin is disposed in the second mold part of FIG. 6 Enlarged section of the.
10 is an exploded perspective view of a third mold part of FIG. 1.
11 is a perspective view of the third upper mold of FIG. 10 in another direction.
12 is a perspective view in another direction of the third lower mold and the damper molding portion of FIG. 10.
13(a) is a cross-sectional view in the Ea-Ea direction in a state in which a third injection product is formed in the third mold part of FIG. 10, and FIG. 13(b) is a third injection product in the third mold part of FIG. A cross-sectional view in the Eb-Eb direction in the formed state.
14 is a perspective view of a strut bearing according to an embodiment of the present invention.
15 is an exploded perspective view of FIG. 14;
Fig. 16(a) is a sectional view in the Fa-Fa direction of Fig. 14, and Fig. 16(b) is a sectional view in the Fb-Fb direction of Fig. 14;
17 is a perspective view of the housing of FIG. 15 from another direction.
18 is a cross-sectional view of the damper portion of FIG. 15 in the HH direction.
19 is an enlarged view of the sealing part of FIG. 16(b).

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings. However, detailed descriptions of known functions or configurations in the detailed description will be omitted so as not to distract from the subject matter of the present invention.

In addition, for the convenience of explanation below, the direction in which the lower mold is formed is defined as the lower side, the direction in which the upper mold is formed is defined as the upper side, and the direction in which the central axis of the hollow formed in the housing is extended is defined as the axial direction, and The vertical direction is defined as the radial direction.

1 is a strut bearing manufacturing apparatus according to an embodiment of the present invention.

2 is an exploded perspective view of the first mold part of FIG. 1, FIG. 3(a) is a perspective view of the first upper mold of FIG. 2 in another direction, and FIG. 3(a) is a different perspective view of the first lower mold of FIG. Directional perspective view, FIG. 3(b) is a perspective view in another direction of the first upper mold of FIG. 2, and FIG. 4 is a cross-sectional view of a fixed groove forming part in a state in which a first injection product is formed in the first mold part of FIG. 2 5(a) is an enlarged cross-sectional view of a portion in which the first fixing pin of the first mold part of FIG. 2 is disposed, and FIG. 5(b) is a first support pin of the first mold part of FIG. 2 It is an enlarged cross-sectional view of the part.

6 is an exploded perspective view of the second mold part of FIG. 1, FIG. 7(a) is a perspective view of the second lower mold and sealing part of FIG. 6 in different directions, and FIG. 7(b) is the second upper part of FIG. Another perspective view of the mold, FIG. 8 is a cross-sectional view in the BB direction in a state in which a second injection product is formed in the second mold part of FIG. 6, and FIG. 9(a) is a second mold part in the second mold part of FIG. An enlarged cross-sectional view of a portion in which the fixing pin is disposed, and FIG. 9(b) is an enlarged cross-sectional view of a portion in which the second support pin is disposed in the second mold part of FIG. 6.

10 is an exploded perspective view of the third mold part of FIG. 1, FIG. 11 is a perspective view of the third upper mold of FIG. 10 in another direction, and FIG. 12 is a perspective view of the third lower mold and damper molding part of FIG. 13(a) is a cross-sectional view in the Ea-Ea direction in a state in which a third injection product is formed in the third mold part of FIG. 10, and FIG. 13(b) is a third thread in the third mold part of FIG. It is a cross-sectional view in the Eb-Eb direction with the exhibits formed.

1 to 13, the manufacturing apparatus 10 for manufacturing a strut bearing through a multi-injection process according to an embodiment of the present invention includes an insert 1130 having a plurality of through holes inserted therein, and a hollow 1140 A first mold part 100 for molding a first injection product formed of a formed body 1110 and a flange part 1120 extending from one side of the body 1110, inside and outside one side of the flange part 1120 A second mold part 200 for molding a second injection product in which a sealing part 1200 is further formed along the main surface, and a damper part ( 1300) includes a third mold part 300 for molding a third injection product, wherein the first mold part 100 is a first lower mold to which the insert 1130 is inserted and fixed ( 110) and a first upper mold 120 coupled to the first lower mold 110 to form a first forming space 130, and the first upper mold 120 includes the It is characterized in that the expansion portion molding protrusion 123 is formed to form an expansion portion 1125 extending inward from an outer peripheral surface of one side of the flange portion 1120.

The strut bearing manufacturing apparatus 10 molds a first mold part 100 for molding a first injection product for triple injection, a second mold part 200 for molding a second injection product, and a third injection product. A strut bearing 1000 formed of different materials is produced by including the third mold part 300 and passing through a continuous injection process.

At this time, a transfer robot for transferring the injection product is installed between each mold part, and a chucking unit for seating an insert 1130 or an intermediate injection product in each mold part, and a moving unit for moving the chucking unit forward, backward, left and right Servo robot and moving belt are installed.

Specifically, a transfer robot is installed between each mold part, and the injection product formed in the mold part is combined and removed by a chucking unit, transferred to a moving belt, and cooled while moving along the moving belt. The cooled injection product is fixed to the chucking unit again and moved for the next injection step. At this time, the chucking unit is formed to be rotatable in order to fix the fixed insert or injection product in an accurate position, and is moved by the moving unit.

Therefore, the strut bearing manufacturing apparatus 10 of the present invention allows each step to be automatically performed without the input of manpower, thereby improving the stability of the operator, improving workability, and reducing the time and cost required for production. Significantly improves productivity.

In other words, the strut bearing manufacturing apparatus 10 of the present invention has an effect of remarkably improving the productivity of a product by including a plurality of mold parts and a transfer robot so that the entire process can be performed automatically.

The first mold part 100 is coupled to a first lower mold 110 into which an insert 1130 having a plurality of through holes is inserted and fixed, and a first molding space ( The housing 1100, which is formed of the first upper mold 120 forming a 130, and into which the insert 1130 is inserted, is formed.

At this time, the insert 1130 is formed of a side wall 1131 having a hollow 1140 and formed in a cylindrical shape in the axial direction, and an extension part 1132 extending in the radial direction from one end of the side wall 1131, and extends The portion 1132 has a plurality of through holes formed along the circumferential surface.

The first lower mold 110 includes a first fixing pin 111 having a coupling protrusion 1111 penetrating a portion of the through hole corresponding to the position of the through hole, and a first support disposed on one side of the remaining through hole. It has a pin 112.

Specifically, the insert 1130 is fixed so that the side wall 1131 is disposed inside the first lower mold 110, and the first fixing pin 111 has a coupling protrusion 2111 formed at the upper end of the through hole Is disposed through in the insert 1130 so that the insert 1130 can be accurately fixed in the predetermined first molding space 130, and the first support pin 112 is the lower side of the remaining through-hole not coupled with the first fixing pin 111 It is arranged to be in contact with.

At this time, it is preferable that the first fixing pin 111 is formed of at least three or more arranged in different directions so that the insert 1130 can be fixed at a more accurate position. It is preferable that they are arranged to be spaced the same distance.

In addition, the first fixing pin 111 and the first support pin 112 are formed in a mixture and arranged to have a certain pattern to prevent the insert 1130 from moving during the injection process. Is smoothly supplied to the third molding space 330, and at the same time, the product has an overall uniform physical property, thereby improving reliability.

In the first lower mold 110 of an embodiment, four first fixing pins 111 and eight first support pins 112 are formed, and the first fixing pin 111 is a central axis of the hollow 1140. It is formed to be spaced apart by 90 degrees in the radial direction as a reference, and two first support pins 112 are formed with the same distance between different first fixing pins 111.

In addition, the first lower mold 110 is formed with a contact rib forming portion 113 forming a contact rib 1114 in contact with the damper portion 1300 in the axial direction of the outer circumferential surface of the body 1110, the flange portion 1120 ) A first contact protrusion forming part 114 is formed along the lower side to form a first contact protrusion 1127 in contact with the damper part 1300, and a third contact protrusion forming part 114 is formed along the inner circumferential surface of the lower side of the body 1110. A fixing groove forming part 115 is formed to form a fixing groove 1112 that is coupled to the vehicle lower mold 310.

The fixing groove forming part 115 forms a fixing groove 1112 to which the third lower mold 310 and the second injection product are fastened and fixed on the lower inner circumferential surface of the body 1110 to form the first through part 1121. It should be used as a third inlet 322. Therefore, by allowing the damper part 1300 to be formed in the opposite direction from which the raw material is injected based on the flange part 1120, the process of rearranging the second injection product for the third injection is omitted, thereby realizing the automation of triple injection. To be able to.

The fixing groove 1112 is coupled to the fixing protrusion 3111 formed on the third lower mold 310 so that the second injection product is fixed at the correct position, and the fixing groove forming part 115 is It is preferably formed in at least three or more are formed in different directions and spaced the same distance from each other.

In addition, the fixing groove forming portion 115 is formed to be tapered so that the cross-sectional area increases as it goes upward, so that insertion and removal of each injection product from each injection unit is easier. Four fixed groove forming parts 115 are formed in the first lower mold 110 of an embodiment, and the fixed groove forming parts 115 are formed at intervals of 90 degrees from each other with respect to the central axis of the hollow 1140 do.

The first upper mold 120 is coupled from the upper side of the first lower mold 110 to form a closed first molding space 130, and a hollow for forming a hollow 1140 in the housing 1100 The molding part 124 is formed. At this time, the insert 1130 is fixed to the first molding space 130 so that it is disposed inside the housing 1100 in the first injection product.

At this time, in the first upper mold 120, in order to form the first and second through portions 1121 and 1122 in the flange portion 1120, a coupling pin having a coupling hole 1211 coupled to the coupling protrusion 1111 is formed ( 121) and a first corresponding pin 122 penetrating the expansion part forming protrusion 123 and the expansion part forming protrusion 123 forming the expansion part 1125 corresponding to the position of the first support pin 112 Is formed.

The coupling pin 121 is coupled with the coupling protrusion 1111 penetrating the through hole to communicate with some of the through holes, and forms a first through portion 1121 that is not connected to the outer circumferential surface of the flange portion 1120, and sealing The portion 1200 is not formed. Accordingly, the first through part communicates with the third injection hole 322 formed in the third upper mold 320 so that the damper part 1300 can be formed under the flange part 1120 and at the same time, the damper part 1300 ) To improve the adhesion between the housing 1100 and the damper portion 1300 by forming a locking portion 1311 that can be locked to the first through portion 1121.

The expansion part forming protrusion 123 is formed in the opposite direction of the first support pin 112 to form an expansion part 1125 extending inward from one outer circumferential surface of the flange part 1120, and the flange part 1120 and The adhesion of the sealing part 1200 is improved.

At this time, in order to increase the effect of improving adhesion, the first fixing pin 111, the first support pin 112, the coupling pin 121, and the first corresponding pin 122 are formed to have a larger cross-section than the cross-section of the through-hole and are locked. The part 1311 and the expansion seal 1230 are fixed to each other in the first through part 1121 and the second through part 1122.

The hollow molding part 124 is formed to protrude from the inner circumferential surface of the first upper mold 120 to contact the first lower mold 110 to form a hollow 1140 open to the housing 1100 in the axial direction. And, in order to improve the adhesion of the first mounting portion molding portion 125 and the outer sealing portion 1210 and the flange portion 1120 in which the outer sealing portion 1210 is seated along the outer circumferential surface of one side of the flange portion 1120 A first mounting portion forming portion 125 for forming the second contact protrusion 1124 protruding along the first mounting portion 1123 is formed.

In addition, a seating portion forming portion 127 for forming the second seating portion 1126 on which the connection seal 1240 is seated is formed so that the sealing portion 1200 can be firmly formed on the flange portion 1120.

Therefore, in the strut bearing manufacturing apparatus 10 of the present invention, the first fixing pin 111 and the first support pin 112 are mixed with a certain pattern so that the insert 1130 is fixed at a more accurate position, and at the same time, the first screw. It has the effect of improving the reliability of the product by making the exhibits have the same physical properties as a whole.

In addition, the fixing groove forming part 115 is formed so that the second injection product can be fixed at a more accurate position of the third lower mold 310, thereby increasing product reliability effect and communicating with the third injection port 322. The first through part 1121 is formed to enable the third injection without rearrangement of the second injection product, thereby realizing the automation of the triple injection.

The second mold part 200 includes a second lower mold 210 in which the first injection product is inserted and fixed, and a second molding space 230 that is closed by being coupled to the second lower mold 210. It is formed of a second upper mold 220 to be formed, and a sealing molding part 240 for molding the sealing part 1200 on one side of the first injection product.

The second lower mold 210 has a first contact protrusion 1127 formed under the flange 1120 on the upper side so that the first injection product is fixed at the correct position of the first molding space 130. The first contact protrusion seating portion 213 is formed, and in the portion where one end of the hollow 1140 is inserted by being concave, a fixing groove seating portion 214 in which the fixing groove 1112 is seated is formed, and the housing 1100 is formed. A body fixing protrusion 215 is formed between the contact ribs 1114 to fix it.

In addition, a second fixing pin 211 having an insertion protrusion 2111 penetrating through the first through part 1121 to prevent sealing from being formed in the first through part 1121 and a second through part 1122 In order to prevent the sealing from being formed below the second support pin 212, which is inserted a predetermined distance from the second through part 1122, a second support pin 212 is formed.

Specifically, the second support pin 212 is inserted a predetermined distance below the second through part 1122 and is disposed not to contact the lower side of the through hole so that the sealing is seated inside the second through part 1122. Accordingly, the contact area between the sealing part 1200 and the flange part 1120 is increased, so that the adhesion is improved.

Therefore, the second lower mold 210 of the present invention has a plurality of structures that are complementarily combined with each part of the first injection product, so that the first injection product is placed in a more accurate position in the second molding space 230. At the same time, it improves the reliability of the product by preventing the first injection product from moving during the injection process.

The second upper mold 220 has a second injection hole 222 into which the molten resin forming the sealing part 1200 is injected, and is disposed above the connection part 1126 to form the connection sealing 1240. The connection part molding surface 221 is formed. At this time, the second injection hole 222 is formed on the connection part forming surface 221 so that the sealing part 1200 can be integrally formed.

The sealing molding part 240 is disposed between the second lower mold 210 and the second upper mold 220 and fixed to the second lower mold 210 on the flange part 1120 of the first injection product. A plurality of outer sealing ribs 1211 can be formed at the same time while forming the sealing part 1200 on the side surface.

Therefore, the sealing molding part 240 is formed of a first sealing molding part 241 and a second sealing molding part 242, and the first and second sealing molding parts 241 and 242 are formed to be separated in a radial direction, It is formed to be detachable from the vehicle lower mold 210. However, the shape of the sealing formed by combining the first and second sealing parts 241 and 242 in the sealing molding part 240 may be variously changed according to the shape of the sealing part 1200.

Therefore, the second mold part 200 of the present invention has various structures that are complementarily combined with the first injection product to enable more precise injection, thereby reducing the defect rate of the product and increasing the effect of improving productivity and product reliability. .

The third mold part 300 forms a third lower mold 310 into which a second injection product is inserted and fixed, and a third molding space 330 that is coupled to and sealed with the third lower mold 310 The third upper mold 320 is formed between the third lower mold 310 and the third upper mold 320 to form a damper forming part 340 that forms a damper part 1300, A damper part 1300 is formed below the flange part 1120 to surround a lower side surface of the flange part 1120 and a part of the outer surface of the body 1110.

The third lower mold 310 is inserted into one side of the hollow 1140 of the second injection product and has a positioning part 311 for guiding the fixed position of the second injection product in the third molding space 330. A fixing protrusion 3111 is formed to protrude and coupled to the fixing groove 1112 along the outer circumferential surface of the positioning part 311 is formed.

At this time, the fixing protrusion 3111 is formed to increase the size of its cross-sectional area as it goes upward, so that insertion and removal of the second injection product is easier, and in order to fix the second injection product in a more accurate position, It is preferable to be formed of at least three or more disposed in different directions, and at this time, the fixing protrusions 3111 are preferably formed to be spaced apart from each other by a predetermined interval.

In addition, it is preferable that the fixing groove 1112 and the fixing protrusion 3111 are formed complementarily, formed in a polygonal shape, and formed in contact with each other in a plurality of directions. However, in consideration of the convenience and fixing power of manufacturing, the fixing groove 1112 and the fixing protrusion 3111 of one embodiment have a rhombic shape formed so that three sides are in contact, and are formed in four so that they are 90 degrees from each other based on the central axis of the hollow. It is formed by being spaced apart.

The third upper mold 320 is coupled to the upper side of the third lower mold 310, and forms a third molding space 330 that is sealed to the third lower mold 310 by coupling. 1 A third injection hole 322 is penetrated to correspond to the position of the through part 1121, and the sealing part 1200 seated on the expansion part 1125 corresponding to the position of the first through part 1121 is formed on the lower side. ) Pressing protrusion 321 is formed.

The pressing protrusions 321 are formed in plural and protrude from the inner surface of the third upper mold 320 to press the upper surface of the expansion seal 1230 seated on each expansion part 1125, and the damper part 1300 ) Minimizes the occurrence rate of defects in the sealing part 1200 due to an increase in pressure generated during formation. Therefore, the shape of the pressing protrusion 321 is formed the same as the expansion portion 1125, but the size is preferably formed to be smaller than the expansion portion (1125).

Specifically, by the combination of the third lower mold 310 and the third upper mold 320, the pressing protrusion 321 is disposed outside the expansion sealing 1230, and pressurizes the first through part 1121 As the molten resin is injected through the expansion seal 1230 by the pressure generated from the lower side of the flange unit 1120 in the upward direction, the expansion seal 1230 is prevented from being separated from the expansion unit 1125.

Therefore, in the strut bearing manufacturing apparatus 10 of the present invention, the molten resin forming the damper part 1300 is injected from the upper side of the flange part 1120 with the first through part 1121, but the damper part 1300 is The triple injection manufacturing apparatus of the strut bearing 1000 by allowing it to be formed on the lower side of the flange portion 1120 so that it can be fixed to the third mold portion 300 without rearrangement of the second injection after the second injection. 10) to realize automation.

Accordingly, the production speed of the product is improved by excluding the rearrangement process of rotating the second injection product removed from the second lower mold 210 in order to form the damper part 1300 under the conventional flange part 1120, It has the effect of remarkably improving the productivity of the product by minimizing the intervention of manpower to improve workability and reduce production cost.

Accordingly, the strut bearing manufacturing apparatus 10 of the present invention realizes the automation of triple injection by excluding the process of rearranging the position of the intermediate injection when fixing the intermediate injection to each mold part used in the injection process.

Accordingly, it has the effect of improving productivity by significantly reducing the production cost and production time of the product, and improving product reliability by improving the adhesion of each component.

14 is a perspective view of a strut bearing according to an embodiment of the present invention, FIG. 15 is an exploded perspective view of FIG. 14, FIG. 16(a) is a cross-sectional view in the Fa-Fa direction of FIG. 14, and FIG. 16(b) is It is a cross-sectional view in the Fb-Fb direction. 17 is a perspective view of the housing of FIG. 15 from another direction, FIG. 18 is a cross-sectional view of the damper portion of FIG. 15 in the H-H direction, and FIG. 19 is an enlarged view of the sealing portion of FIG. 16(b).

14 to 19, the strut bearing 1000 produced by the strut bearing manufacturing apparatus according to an embodiment of the present invention has an insert 1130 having a plurality of through holes inserted therein, and a body having a hollow 1140 formed therein. A housing 1100 formed of a flange portion 1120 extending from one side of the body 1110, a sealing portion 1200 formed along an inner and outer circumferential surface of one side of the flange portion 1120, and the A damper part 1300 formed to surround the other side of the flange part 1120 and a part of the body 1110, and the flange part 1120 is a first through part 1121 communicating with a part of the through hole. ), and an extension part 1125 extending inward from one outer circumferential surface, a second through part 1122 communicating with the remaining through hole is formed, and the sealing part 1200 is formed along the outer circumferential surface The outer sealing part 1210 that is formed, the inner sealing part 1220 formed along the inner circumferential surface, and the expansion sealing 1230 which is seated on the expansion part 1125 and pressed to have a concave surface 1231 formed therein. It is characterized.

At this time, it is preferable that a fixing groove 1112 coupled to the third lower mold 310 is further formed on the inner circumferential surface of the other side of the body 1110.

The housing 1100 is formed of a body 1110 having a hollow 1140 formed therein, and a flange portion 1120 bent in the body 1110 and extending in a radial direction, and an insert 1130 having a plurality of through holes formed therein. It is formed by being inserted.

The body 1110 has a cylindrical shape open in the axial direction, and a contact rib 1114 protruding to increase the contact area with the damper unit 1300 is formed on the outer surface, and a third lower mold ( 310) and a fixing groove 1112 to be locked is formed, and a bearing and a locking protrusion 1113 fixed to the upper cup are formed on the upper inner circumferential surface.

The flange portion 1120 has a disk shape in which a hollow 1140 is formed by extending in a radial direction from an upper side of the body 1110, and is formed by mixing a first through portion 1121 and a second through portion 1122, In order to increase the contact area with the sealing part 1200 and the damper part 1300, a second contact protrusion 1124, an extension part 1125, a connection part 1132, and a first contact protrusion 1127 are formed.

The first through part 1121 communicates with the through hole and is formed to penetrate the flange part 1120 and is used when fixing to the first and second mold parts 100 and 200, and the third part of the third mold part 300 It communicates with the difference injection port 322 so that the damper part 1300 can be molded below the flange part 1120.

The second through part 1122 communicates with the through hole, and an expansion part 1125 on which the expansion seal 1230 is seated is formed on the upper side of the flange part 1120, so that the sealing part 1200 and the housing 1100 are Improves adhesion.

To this end, the extension part 1125 is formed in a radial direction from the first seating part 1123 toward the central axis. In addition, in order to further improve adhesion, the second through-hole 1122 has a larger cross-sectional area than the through-hole so that it can be structurally locked and fixed, and one side of the extension 1125 is bent to increase the attachment area. Is formed.

The first seating portion 1123 is formed along the outer circumferential surface of the upper side of the flange portion 1120 so that the outer sealing portion 1210 is seated, and a second contact protrusion 1124 along the first seating portion 1123 to improve adhesion. ) Are spaced apart to form a plurality of protrusions.

In addition, a connection part 1132 connecting the outer sealing part 1210 and the inner sealing part 1220 is formed so that each component of the sealing part 1200 can be integrally formed, and the first contact protrusion along the lower side A protrusion 1127 is formed to increase the contact area with the damper part 1300 to improve adhesion to the damper part 1300.

The insert 1130 includes a sidewall 1131 formed with a hollow 1140 and disposed inside the body 1110, and an extension 1132 formed extending from the sidewall 1131 and disposed inside the flange 1120 And a plurality of through-holes are formed along the extension part 1132 to improve the rigidity of the housing 1100 against loads in the axial direction and in the radial direction, and at the same time, each injection product can be fixed to each mold part.

The sealing part 1200 includes an outer sealing part 1210 formed along an outer circumferential surface of one side of the flange part 1120, an inner sealing part 1220 formed along the inner circumferential surface, and an expansion seal seated on the expansion part 1125. It is formed of a connection seal 1240 that connects the outer sealing portion 1210 and the inner sealing portion 1220 to the outer sealing portion 1210 and the inner sealing portion 1220 through an expansion seal 1230 and an expansion seal 1230.

At this time, the upper side of the expansion seal 1230 is pressed by a pressing protrusion 321 to prevent the expansion unit 1125 and the expansion seal 1230 from being separated by the pressure generated during the molding of the damper unit 1300 to be concave. It is formed with a surface 1231.

In other words, the expansion sealing 1230 is compressed in the inside of the second through part 1122 by the pressing protrusion 321 to improve adhesion to the inner surface of the second through part 1122, and inside the second through part ( A structure that can be locked and fixed with the inner surface of 1122) is formed to increase the effect of improving adhesion.

The damper unit 1300 includes a first support surface 1310 disposed outside the lower side of the flange unit 1120 to support an axial load, and a second support surface 1320 formed outside the body 1110 It is formed by attenuating the load generated in the vehicle operation, etc.

At this time, in order to improve the adhesion between the damper unit 1300 and the housing 1100, the first support surface 1310 includes a locking portion 1311 that is fixed to the first through portion 1121 and the flange portion 1120. A first seating groove 1312 in which the first contact protrusion 1127 formed on the lower side is seated, and a seating protrusion 1313 that is inserted and seated at one side of the second through portion 1122 are formed, and the second A rib groove 1321 formed complementary to the contact rib 1114 is formed on the support surface 1320.

Therefore, the strut bearing 1000 of the present invention has a concave surface 1231 of the expansion seal 1230 to significantly reduce the defect rate that may occur during the manufacturing process, thereby improving product productivity, and the housing 1100 and the damper unit 1300 ) Has the effect of improving the reliability and durability of the product by providing a plurality of structures that are complementarily bonded to improve adhesion.

In the above, preferred embodiments of the present invention have been exemplarily described, but the scope of the present invention is not limited to such specific embodiments, and it is possible to appropriately change within the scope described in the claims is not limited to the protection scope of the present invention. Corresponds.

10 manufacturing device
100 1st mold ledger
110 1st lower mold 111 1st fixing pin 1111 Connecting protrusion
112 1st support pin 113 Contact rib forming part
114 First contact protrusion forming part 115 Fixed groove forming part
120 1st upper mold 121 coupling pin 1211 coupling hole
122 1st mating pin 123 Expansion part molding protrusion 124 Hollow molding part
125 First mounting part molding 126 Second contact protruding part
127 2nd seating part forming part 130 1st forming space
200 2nd mold part
210 2nd lower mold 211 2nd fixing pin 2111 Insertion protrusion
212 Second support pin 213 First contact protrusion seat 214 Fixing groove seat
215 Body fixing protrusion 220 2nd upper mold 221 Connection part molding surface
222 2nd injection port 230 2nd molding space 240 Sealing molding part
241 First sealing part 242 Second sealing part
300 3rd mold part
310 3rd lower mold 311 Positioning part 3111 Fixing protrusion
320 3rd upper mold 321 Push protrusion 322 3rd injection port
330 3rd molding space 340 Damper molding part
1000 strut bearing
1100 Housing 1110 Body 1111 Contact rib
1112 Fixing groove 1113 Protrusion
1120 Flange part
1121 1st penetration part 1122 2nd penetration part 1123 1st seating part
1124 Second contact protrusion 1125 Expansion part 1126 Second seating part
1127 First contact protrusion 1130 Insert 1131 Side wall
1132 Extension 1140 Hollow
1200 Sealing part 1210 Outer sealing part 1211 Outer sealing rib
1220 Inner sealing part 1221 Inner sealing rib
1230 Expansion sealing 1231 Concave surface 1240 Connection sealing
1300 Damper part 1310 1st support surface 1311 Hooking part
13111 2nd locking protrusion 13112 Support protrusion 13113 Connecting protrusion
1312 1st seating groove 1313 Seating protrusion
1320 Second support surface 1321 Contact rib

Claims (5)

In a manufacturing apparatus for manufacturing a strut bearing through a multiple injection process,
A first mold portion for molding a first injection product formed of a body having a hollow body and a flange portion extending from one side of the body into which inserts having a plurality of through holes are inserted;
A second mold part for molding a second injection product in which a sealing part is further formed along an inner and outer circumferential surface of one side of the flange part; And
Including; a third mold part for molding a third injection product in which a damper part is further formed on the other side of the flange part and an outer part of the body,
The first mold part
It is formed of a first lower mold into which the insert is inserted and fixed, and a first upper mold coupled to the first lower mold to form a first forming space, and the first upper mold includes the flange portion. Strut bearing manufacturing apparatus, characterized in that the expansion portion forming protrusion forming an expansion portion extending inward from one outer circumferential surface is formed.
The method of claim 1,
In the first lower mold
A first fixing pin having a fixing protrusion penetrating through some of the through-holes is formed, and a first supporting pin disposed on one side of the remaining through-holes,
In the first upper mold
Strut bearing manufacturing apparatus, characterized in that the expansion portion forming protrusion is formed corresponding to the position of the support pin and a coupling pin having a coupling hole coupled to the fixing protrusion.
The method of claim 2,
Strut bearing manufacturing apparatus, characterized in that the first fixing pin and the first support pin are formed mixed to have a predetermined pattern at the position of the through hole.
The method of claim 2,
The first fixing pin is
Strut bearing manufacturing apparatus, characterized in that at least three or more are spaced apart from each other at a predetermined interval based on the central axis of the hollow.
The method of claim 1,
The first injection product
A first through part communicating with some of the through holes and a second through part communicating with the expansion part and the remaining through holes are formed in the flange part,
The third mold part
The strut bearing manufacturing apparatus, characterized in that an injection hole disposed on one side of the first through part is formed, and a third forming space is formed in the other side of the first through part.

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