KR19990031918U - Split Piston Pin - Google Patents

Abstract

The present invention relates to a split piston pin, the present invention is a piston pin for connecting the piston and the connecting rod, the piston 11 is divided into a first piston 13 and a second piston 14, The first piston 13 is provided with a connector 17 on the opposite side; Forming a coupler (20) screwed to the connector (17) in the second piston pin (14) opposite the first piston pin (13); Both piston pins 13 and 14 in a coupled state are coupled to support the small end of the connecting rod 12 and at the same time characterized in that the flange portion 21, 22 is formed to prevent the separation from the piston coupling portion It is done.

Therefore, by eliminating the snap ring coupled to prevent the left and right deviation of the piston pin and by splitting the piston pin to form a flange portion having the compression force of the compression spring in each, to solve the noise problem caused by the piston pin shaking during the piston reciprocating motion By forming an oil passage in the piston pin, the cooling efficiency of the piston pin and the piston can be improved.

Description

Split Piston Pin

The present invention relates to a piston pin, and more particularly, the piston pin connecting the piston and the connecting rod to prevent the left and right pull and shake caused during vertical reciprocating movement to solve the noise problem and the oil flows fast inside the piston pin It relates to a split piston pin (Piston pin) to be passed through to improve the cooling efficiency of the piston.

In general, the piston pin is a pin connecting the piston and the connecting rod is formed to be inserted into the small end of the piston boss and the connecting rod to transfer the pressure received from the piston to the connecting rod.

Since the piston pin reciprocates in the cylinder at high speed with the piston, the piston pin must be light in weight and high in strength to withstand the large loads to be changed.

In addition, the piston pin and the connecting rod coupling structure, as shown in Figure 1, both ends are fixed to the piston (3) in the state in which the piston pin (1) engaging the connecting rod (2), Snap rings 4 are coupled to both ends such that the piston pin 1 is prevented from deviating from the left and right with respect to the piston 3.

The conventional piston pin as described above simply connects the connecting rod and the piston, and the piston pin coupled to the piston by a snap ring during the reciprocating motion of the connecting rod and the piston causes left and right movements and vibrations. The snap ring provided at the left and right ends is in contact with the piston causing noise.

In addition, the piston is overheated due to the frictional heat of the coupling portion of the piston pin and the connecting rod according to the high speed movement of the piston.

The present invention is devised to solve the above problems, by eliminating the snap ring coupled to prevent the left and right deviation of the piston pin, so as to solve the noise problem caused by the piston pin shaking during piston reciprocating movement, inside the piston pin It is an object of the present invention to provide a split piston pin that can improve the cooling efficiency of the piston pin by forming an oil through hole in it.

1 is a cross-sectional view showing a conventional coupling state between the piston pin and the connecting rod,

2 is a perspective view showing a piston pin according to the present invention,

Figure 3 is a piston pin and connecting rod coupled state according to the present invention.

Explanation of symbols for main parts of the drawings

DESCRIPTION OF SYMBOLS 10 Piston pin 11: Piston 12: Connecting rod 13: 1st piston pin 14: 2nd piston pin 15: Plunger 16: Compression spring 17: Connector 18: Thread part 19, 19 ': Horizontal oil passage 20: Coupling member 21, Reference Signs List 22 flange portion 23 vertical oil passage 24 oil passage 25 slide hole 26 coupling groove 27 return spring

The present invention for achieving the above object, in the piston pin for connecting the piston and the connecting rod, the piston pin is divided into a first piston pin and a second piston pin, the first piston pin is connected to the opposite side The second piston pin opposite to the first piston pin is formed to form a coupler that is screwed with the connector. Both piston pins in a coupled state are coupled to and supported by a small end of the connecting rod. It is characterized in that the flange portion is formed to prevent the departure from the portion.

According to another aspect of the present invention, the inner side of the first and second piston pins coupled to each other to form a horizontal oil passage having a predetermined section in the central axial direction so as to communicate with the oil passage through the connecting rod, the horizontal oil The left and right ends of the passage are in communication with each other by a vertical oil passage penetrating the flange portion up and down.

According to another aspect of the present invention, on both outer sides of the flange portion to form a plurality of slide holes in communication with the vertical oil passage around the circumference around the axial direction, respectively, opening and closing the oil passage in the slide hole To insert a plunger, the plunger is characterized in that one side is supported by a compression spring supported on the inner wall of the piston.

According to another aspect of the present invention, both of the first and second piston pin is characterized in that the coupling groove for coupling them is formed.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 is an exploded perspective view showing a piston pin according to the present invention, Figure 3 is a cross-sectional view showing a piston pin and the connecting rod coupled state inside the piston.

As shown, the present invention includes a piston 11, a connecting rod 12, first and second piston pins 13 and 14 coupled to each other, and a plunger 15, and a compression spring 16. It is configured by.

Inside the piston 11, the small end of the connecting rod 12 is coupled by a piston pin 10, and the piston pin 10 is connected to each other by the first piston pin 13 and the second piston pin 14. Screwed together.

The first piston pin 13 has a connector 17 protrudingly formed on one side thereof, and the connector 17 has a screw portion 18 formed on an inner circumferential surface thereof, and a horizontal oil passage 19 in an axial direction inside the center direction thereof. ) Is formed.

In addition, the second piston pin 14 facing the first piston pin 13 is provided with a bolt-shaped coupler 20 at one side to be screwed with the threaded portion 18 of the connector 17. Inwardly, an oil passage 19 ′ connected to the horizontal oil passage 19 of the first piston pin 13 is formed.

In addition, the first and second piston pins 13 and 14 are formed with flange portions 21 and 22, respectively, and the flange portions 21 and 22 guide small-end coupling of the connecting rod 12. And it is formed to prevent left and right separation inside the piston (11).

In addition, the flanges 21 and 22 penetrate vertical oil passages 23 that are vertical in the vertical direction, and the center portions thereof communicate with both sides of the horizontal oil passages 19, respectively.

Here, the horizontal oil passage 19 has a structure in which a central portion communicates with the oil passage 24 provided in the connecting rod 12.

On the other hand, each of the two outer sides of the flange portion (21) 22, a plurality of slide holes 25 are formed on the outer circumference around the axial direction, respectively, the slide hole 25 is the vertical oil It is formed to communicate with the passage 23, the plunger 15 is inserted into the slide hole 25 for opening and closing the vertical oil passage 23 by the elastic force according to the oil pressure. The plunger 15 is supported by a compression spring 16 whose one side is supported on the inner wall of the piston 11.

Reference numeral 27 denotes a return spring for supporting the plunger 15 in the slide hole 25 of the flanges 21 and 22 to improve the opening and closing force of the oil through the vertical oil passage 23.

In addition, coupling grooves 26 are formed on both sidewalls of the first and second piston pins 13 and 14 to couple them to each other.

Referring to the operation state according to the configuration of the subject innovation in detail as follows.

When the piston 11 moves up and down in the cylinder liner part, the piston 11 moves up and down linearly along the cylinder liner part, and at the same time, the connecting rod 12 is a piston pin screwed to each other while eccentrically rotating the crankshaft. It will rotate (10).

At this time, the piston pin 10 as shown in Figure 3 so that both flange portions (21, 22) is prevented left and right pulled by the holding force of the plunger 15 and the compression spring 16 to prevent noise. At the same time, when oil is passed through the vertical oil passage 23 formed in the flange portion 15 when the piston 11 descends, the plunger 15 compresses the compression spring 16 and the vertical oil passage 23 respectively. Will be opened.

Then, the oil flowing into the oil passage 24 of the connecting rod 12 is rapidly moved by the high velocity of oil through the vertical oil passage 23 of both flange portions 21 and 22. It is delivered to the horizontal oil passage (19) (19 ') to improve the cooling efficiency of the piston pin (10).

Therefore, the split piston pin according to the present invention, by removing the snap ring coupled to prevent the left and right deviation of the piston pin and splits the piston pin to form a flange portion having the compression force of the compression spring on each, piston reciprocating motion To solve the noise problem caused by the vibration of the piston pin, and by forming an oil passage inside the piston pin, there is an effect to improve the cooling efficiency of the piston pin and the piston.

Claims (4)

In the piston pin connecting the piston and the connecting rod, The piston pin is divided into a first piston pin and a second piston pin, the first piston pin forming a connector on an opposite side; Forming a coupler that is screwed with the connector in the second piston pin opposite the first piston pin; Split piston pins, characterized in that the two ends of the piston pin in the coupled state is coupled to the small end of the connecting rod is formed at the same time the flange portion is prevented from being separated from the piston coupling portion. According to claim 1, wherein the inner side of the first and second piston pins coupled to each other to form a horizontal oil passage having a predetermined section in the central axial direction so as to communicate with the oil passage through the connecting rod, The left and right ends are divided piston pins so as to be in communication with each other by a vertical oil passage penetrating the flange portion up and down. 3. The divided piston pin of claim 2, wherein coupling grooves for coupling the first and second piston pins are formed on both sidewalls of the first and second piston pins. 3. The plunger according to claim 2, wherein a plurality of slide holes are formed on both outer sides of the flange portion so as to communicate with the vertical oil passages on the outer circumference of the axial direction, respectively, and the oil holes are opened and closed on the slide holes. Inserting, the plunger is divided piston pin, characterized in that one side is supported by a compression spring supported on the inner wall of the piston.