KR102053810B1 - Ball Joint Injection Mold Apparatus Having Sliding Inner Core - Google Patents

Abstract

The present invention relates to a ball joint injection mold apparatus having a sliding inner core that surrounds a ball stud by sliding, even though the diameter of the tip portion of the inner core of the ball stud does not secure sufficient space between the outer and outer diameters of the stop-shoulder. As the size increases and decreases according to the sliding movement, the top portion of the inner core can be pushed into the fastening ring groove of the socket to secure the fastening ring without securing a minimum space.

Description

Ball Joint Injection Mold Apparatus with Sliding Inner Core {Ball Joint Injection Mold Apparatus Having Sliding Inner Core}

The present invention relates to a ball joint injection mold apparatus having a sliding inner core that surrounds a ball stud by sliding.

Ball joints are widely used as a joint means having the function of a joint. Typically, ball joints consist of sockets, ball studs, caps, and ball seats.

In general, a ball joint includes a ball stud having a stud portion, a ball seat into which a ball of the ball stud is inserted, a socket surrounding the ball sheet, a socket and a plug thereof.

In the case of a mold apparatus having a conventional cylindrical inner core, as shown in FIG. 9, when sufficient space A is secured between the outer circumference of the stop-shoulder 11 of the ball stud 10 and the inner diameter of the socket opening, the lower mold The fastening ring 30 is installed on the ring seating surface 21 of the inner core tip of the inner core tip, and the inner core pushes the fastening ring 30 through the ring seating surface to the ring groove 41 formed on the inner surface of the socket 40. It is possible to insert 30.

However, when the diameter of the stop-shoulder 11 of the ball stud 10 is approximately equal to the maximum diameter of the ball 12, for example, the space between the stop-shoulder 11 and the inner diameter of the socket 40 cannot be sufficiently secured by 2 mm or more. In this case, the fastening ring 30 cannot be fastened to the ball joint with a conventional mold having a fixed inner core structure.

Therefore, it is necessary to manufacture a new method of inner core that can solve the above problems.

The matters described as the background art are merely for the purpose of enhancing the understanding of the background of the present invention and should not be taken as acknowledging that they correspond to the related arts already known to those skilled in the art.

An object of the present invention is to provide a ball joint injection mold apparatus having a sliding inner core for fastening a fastening ring to a socket of a ball joint to which a ball stud having a large stop-shoulder is applied.

Ball joint injection mold apparatus for performing injection molding of a ball sheet by injecting an injection melt into a ball sheet forming space between the ball part and the inner circumferential surface of the socket in a state where a ball stud including a stud part having a ball part and a stop-shoulder is inserted into the socket Includes a support, a mold and an inner core.

The support supports the ball stud so that at least the ball portion of the ball stud is held in the injection mold apparatus.

The main mold includes an upper mold having an injection gate and a lower mold having a receiving portion for receiving a socket into which a ball stud is inserted.

The inner core consists of at least one pair sliding obliquely relative to the ball stud to close at least one side of the ball seat forming space.

 The inner core may slide in diagonal lines at both left and right sides and may be seated while contacting the lower part of the ball unit.

 The inner core has a ball contact portion in contact with the ball portion formed at the tip portion to prevent the outflow of the injection molding during the injection molding of the ball sheet. In addition, the stop-shoulder may have an outer diameter larger than that of the area where the ball contact portion contacts the ball portion.

 The inner core further includes a ring tip portion for moving the fastening ring, which is closest to the first seating groove of the socket, to the second seating groove.

The inner core includes a stop-shoulder receiving portion that increases in width downward.

In addition, a ball joint manufacturing method for injection molding a ball sheet by injecting an injection melt into a ball sheet forming space between a ball part and an inner circumferential surface of the socket while a ball stud including a stud part having a ball part and a stop-shoulder is inserted into the socket Supporting the stud part of the stud as a support part, coupling the fastening ring to the first seating groove in the socket, installing the socket while covering the ball part of the ball stud, and fastening ring as the at least one pair of inner cores moves diagonally The first seating groove is pushed by the inner core from the second seating groove to shrink and move, and at the same time closing one side of the ball sheet forming space with the tip of the inner core, injection molding is injected into the socket.

According to the ball joint injection mold apparatus having the sliding inner core having the structure as described above, the diameter of the tip portion is sliding movement of the inner core even if the space between the diameter and the inner diameter of the stop-shoulder of the ball stud is not secured. As the size increases and decreases, the top portion of the inner core can be pushed into the fastening ring groove of the socket to secure the fastening ring without securing a minimum space.

In addition, it is possible to achieve the effect of fastening the fastening ring to the injection-type ball joint more universally without design constraints due to the ball stud stop-shoulder outer peripheral diameter.

In addition, it is possible to mount the fastening ring to the second seating groove through the ring tip part in a state where the fastening ring is closest to the first seating groove in the socket. have.

1 is a view showing a ball joint having a large stop-shoulder in a ball joint injection mold apparatus having a sliding inner core according to an embodiment of the present invention.
2 is a view showing the inner core in the ball joint injection mold apparatus having a sliding inner core according to an embodiment of the present invention.
3 is a view showing a state before the inner core wraps the ball stud in the ball joint injection mold apparatus having a sliding inner core according to an embodiment of the present invention.
4 is a view illustrating a state immediately before the inner core of the ball joint injection mold apparatus having the sliding inner core according to the embodiment of the present invention pushes the fastening ring mounted to the first seating groove.
5 is a view showing a state in which the inner core of the ball joint injection mold apparatus having a sliding inner core according to an embodiment of the present invention is separated from the first seating groove.
6 is a view illustrating a state in which an inner core of a ball joint injection mold apparatus having a sliding inner core according to an embodiment of the present invention moves a fastening ring to a second seating groove.
7 is a view showing a ball sheet formed between the socket and the ball in the ball joint injection mold apparatus having a sliding inner core according to an embodiment of the present invention.
8 is a view showing a process in which the ball joint is made in the ball joint injection mold apparatus having a sliding inner core according to an embodiment of the present invention.
9 is a view showing a conventional inner core.

Hereinafter, a ball joint injection mold apparatus having a sliding inner core according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

Ball joint injection mold apparatus having a sliding inner core according to the present invention includes a ball joint, a support and an inner core.

Referring to FIG. 1, the ball joint includes a ball stud, a ball seat 130, a socket 120, and a fastening ring 140.

The ball stud includes the ball part 100 and the stud part 110. The stud portion 110 includes a stop-shoulder 115 having a diameter comparable to the maximum diameter of the ball portion 100.

The stop-shoulder 115 may have an outer diameter greater than that of the area in which the ball contact portion contacts the ball portion. That is, the stop-shoulder 115 may be approximately equal to or larger than the maximum diameter of the ball portion formed in the ball stud.

The ball seat 130 serves to surround the ball stud so that the ball stud slips and rotates.

The socket 120 is seated by inserting the ball sheet, is formed in the circumferential direction in the lower portion of the first seating groove 150 and the first seating groove 150 formed in the circumferential direction on the inner circumferential surface of the inlet, the first seating groove And a second seating groove 160 having a diameter smaller than 150.

The diameter of the first seating groove 150 may be the same as the diameter of the fastening ring 140.

The first inclined portion 170 may be formed on an upper portion of the first seating groove 150, and the first inclined portion 170 may be connected to an upper surface of the first seating groove 150 and an upper surface of the socket 120. The part may be curved.

When the upper part of the first seating groove 150 and the upper surface of the socket 120 are connected to each other, a portion of the first seating groove 150 is curved, so that when the fastening ring 140 is coupled to the first seating groove 150, a human hand does not need any additional equipment. The fastening ring 140 has an effect that can be coupled to the first seating groove 150.

Between the first seating groove 150 and the second seating groove 160 further includes a second inclined portion 180 connecting the lower portion of the first seating groove 150 and the top of the second seating groove 160. do. The second inclined portion 180 is curved in a portion where the lower portion of the first seating groove 150 and the upper portion of the second seating groove 160 are connected to each other.

As the portion connecting the lower portion of the first seating groove 150 and the top of the second seating groove 160 is curved, the fastening ring 140 closest to the first seating groove 150 is the tip portion of the slide inner core. When it is mounted to the second seating groove 160 may be installed without damaging the inner surface of the socket 120. In addition, when the fastening ring 140 is pushed from the first seating groove 150 to the second seating groove 160, it does not have to apply a large force.

The fastening ring 140 is smaller than the maximum diameter of the ball part 100 and is moved in a state seated in the first seating groove 150 to be seated in the second seating groove 160. Fastening ring 140 is a state in which one side of the circumcision is cut open to some extent, and may be larger than the diameter of the ball portion 100 before being fastened to the socket 120, even in a state seated in the first seating groove 150 The diameter of the ball portion 100 may be larger. When the fastening ring 140 is pushed by the tip of the inner core and contracted to be seated in the second seating groove 160, the fastening ring 140 becomes smaller than the maximum diameter of the ball part 100 so that the ball part 100 is outside the socket 120. It plays a role of not falling out.

The support part 240 supports the stud part 110 of the ball stud.

2 to 3, the inner core 190 includes a stop-shoulder accommodating portion 200 therein to surround the stop-shoulder 115 and is slidably moved to close and open. As shown in FIG. 2, the stop-shoulder accommodating part 200 may be configured to increase in width downward to accommodate the stop-shoulder 115 having a large diameter.

The inner core 190 is slid diagonally from both left and right sides to be in contact with the lower portion of the ball part 100.

The inner core 190 has a ball contact portion 220 in contact with the ball portion 100 is formed in the tip portion 210 to prevent the outflow of the injection molding during the injection molding of the ball sheet 130. The ball contact part 220 may be formed in the same curved surface as the circumference of the ball part 100.

The inner core 190 further includes a ring tip portion 230 for moving the fastening ring 140 most closely attached to the socket 120 to the ring seating groove. As the inner core 190 moves diagonally, the ring tip 230 formed at the upper end of the inner core 190 has a second seating ring 140 mounted on the first seating groove 150 of the socket 120. The fastening ring 140 is mounted to the second seating groove 160 while being pushed into the groove 160. The fastening ring 140 is elastically contracted when moved from the first seating groove 150 to the second seating groove 160.

In addition, the ball joint injection mold apparatus having the sliding inner core 190 fastens the fastening ring 140 to the second seating groove 160 in the first seating groove 150 through the following steps. Done.

2 to 6, first, the stud portion 110 of the ball stud is inserted into the support portion 240. (S100)

When the stud part 110 is inserted into the support part 240, the socket 120 is installed in the socket accommodating part 265 of the lower mold 260. In this case, as described above, the socket 120 is fitted to the first seating groove 150 of the socket 120 before the socket 120 is inserted into the socket accommodating part 265.

After that, the socket 120 is fixed while the upper mold 250 including the injection gate 270 covers the upper portion (the upper portion in the drawing) of the socket 120. (S120)

As the inner core 190 moves diagonally as shown in FIG. 3, the inner core 190 moves while surrounding the stop-shoulder 115 of the bolster.

As shown in FIG. 4, when the inner core 190 rises obliquely, the ring tip 230 contacts the fastening ring 140 that is closest to the first seating groove 150 of the socket 120.

As shown in FIG. 5, the inner core 190 is elastically contracted as the fastening ring 140 is separated from the first seating groove 150 while being further raised diagonally.

When the inner core 190 moves to the end in diagonal lines, as shown in FIG. 6, the ball contact part 220 formed on the tip part 210 contacts the ball part 100 so that the injection product does not flow out of the socket 120 and the ring tip part ( 230, the fastening ring 140 is moved to the second seating groove 160. (S130)

Finally, when the injection is injected into the socket 120, a ball seat 130 surrounding the ball is formed between the socket 120 and the ball portion 100, as shown in Figure 7 (S140)

After the ball joint is completed, the inner core 190 is opened while sliding down diagonally again so as to take out the completed ball joint.

While the invention has been shown and described with respect to particular embodiments, it will be appreciated that various changes and modifications can be made in the art without departing from the spirit of the invention provided by the following claims. It will be self-evident for those of ordinary knowledge.

100: ball part
110: stud part
115: stop-shoulder
120: socket
130: ball seat
140: fastening ring
150: first seating groove
160: second seating groove
170: first slope
180: second slope
190: inner core
200: stop-shoulder receiving portion
210: tip portion
220: ball contact
230: ring tip portion
240: support
250: upper mold
260: lower mold
265: socket housing
270: injection gate

Claims (6)

Ball joint injection mold apparatus for performing injection molding of a ball sheet by injecting injection melt into a ball sheet forming space between the ball portion and the inner circumferential surface of the socket in a state where a ball stud including a stud portion having a ball portion and a stop-shoulder is inserted into the socket To
A support for supporting the ball stud so that at least the ball portion of the ball stud is held in the injection mold apparatus;
A casting mold including a receiving part and an injection gate for receiving the socket into which the ball stud is inserted;
At least a pair of inner cores sliding diagonally with respect to the ball stud to close at least one side of the ball seat forming space
Ball joint injection mold apparatus comprising a. The method of claim 1,
The inner core is a ball joint injection mold apparatus, characterized in that seated in contact with the lower portion of the ball portion by sliding diagonally on both sides. The method of claim 1,
The inner core has a ball contact portion in contact with the ball portion formed in the tip portion to prevent leakage of the injection molding during the injection molding of the ball sheet, and the stop-shoulder has an outer diameter larger than the outer diameter of the area where the ball contact portion is in contact with the ball portion. Ball joint injection mold apparatus characterized in that it has a. The method of claim 1,
The inner core further comprises a ring tip portion for moving the fastening ring that is closest to the first seating groove of the socket to the second seating groove. The method of claim 1,
The inner core is a ball joint injection mold apparatus, characterized in that it comprises a stop-shoulder receiving portion that increases in width downward. In the ball joint manufacturing method for injection molding the ball sheet by injecting an injection melt into the ball sheet forming space between the ball portion and the inner peripheral surface of the socket in a state where the ball stud including a stud portion having a ball portion and a stop-shoulder is inserted into the socket,
Supporting the stud portion of the ball stud with a support portion;
Coupling the fastening ring to the first seating groove in the socket;
Installing the socket while covering the ball part of the ball stud;
At least one pair of inner cores are moved diagonally, and the fastening ring is pushed and contracted by the inner core from the first seating groove to the second seating groove, and at one side of the ball seat forming space with the tip of the inner core. Closing the door;
Injecting an injection melt into the socket;
Ball joint manufacturing method comprising a.

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