KR200206377Y1 - Sliding pin structure of disc brake with taper - Google Patents

Abstract

The present invention relates to a sliding pin structure of a disc brake that can prevent bending deformation of the sliding pin by minimizing the bending stress of the sliding pin according to the bending load transmitted from the pinhole during brake operation. In the sliding pin structure of the disc brake, the sliding pin which is slidably coupled to the pin hole of the guide portion to press each pad located at both ends of the disk while flowing along the guide portion of the caliper bracket is fixed to the caliper body, It provides a disc brake sliding pin structure in which the taper is tapered toward the distal end.

Description

Sliding pin structure of disc brake with taper

The present invention relates to a sliding pin of an automobile disc brake, and more particularly, by forming a taper toward the distal end of a sliding pin of a caliper body engaged with a pin hole of a caliper bracket. It relates to a sliding pin structure of a disk brake having a taper to minimize the occurrence of bending stress of the sliding pin due to the bending load transmitted from the pinhole.

In general, a vehicle is provided with a braking device that serves to slow down or stop the vehicle speed while driving.

The brake system is a booster that doubles the pedal effort by using the vacuum pressure (engine suction pressure) generated by the power of the engine, creates pressure in each brake circuit, and changes the volume of the brake oil. It consists of a master cylinder that quickly compensates for the loss of circuit pressure and a wheel cylinder that stops the rotation of the wheel by the brake oil pressure and reduces the rotation speed.

The wheel cylinder is in close contact with an inner peripheral surface of the cylindrical drum synchronously rotating with the wheel wheels to close the brake shoe installed in the inner side of the wheel brake to generate a braking force, or to close the pad to the disk-shaped disk synchronously rotating with the wheel wheel It is installed in the disc brake that generates the braking force to activate the brake.

Here, a typical example of a conventional disc brake is illustrated in FIGS. 1 and 2, which will be briefly described as follows.

As shown in the figure, the disc brake is largely installed to rotate synchronously with the wheel wheel, and the inner and outer pads 125 which are fixed to the inner knuckle arm of the wheel wheel and slide with both sides of the disk 110 interposed therebetween ( Caliper bracket 120 having a 126 and a caliper sliding through the caliper bracket 120 to bring the inner and outer pads 125 and 126 into contact with the disk 110 by the action of the piston 132 according to the hydraulic pressure. The body 130 is comprised large.

At the lower end of the caliper bracket 120, a support part 121 having a through hole 122 is formed to be fixed to the knuckle arm through a bolt, and guide parts 123 having pin holes 123a are formed at both ends of the upper part. The inside of the guide part 123 is provided with a guide bracket 124 on which the inner and outer pads 125 and 126 slide.

A cylinder 131 is formed in the center of the caliper body 130 in the sliding direction of the inner and outer pads 125 and 126, and a piston 132 is provided in the cylinder 131 to enter the cylinder 131. The inner pads 125 and 126 are slid toward the disk 110 by the injected hydraulic pressure, and fastening holes 133 corresponding to the pin holes 123a are formed at both ends thereof, such that the pin holes of the guide part 123 are formed. A sliding pin 134 coupled to the 123a is fixed to the fastening hole 133 through the bolt 135. In addition, the lower end of the caliper body 130, the contact portion 138 is the outer side to contact the outer pad 126 to the outer surface of the disk 110 in response to the piston 132 during the operation of the piston 132. It extends to the pad 126 side and supports the back side thereof.

According to the conventional disc brake configured as described above, the pressure of the vacuum booster acting upon the stepping of the brake pedal injects the brake oil of the master cylinder into the cylinder 131 of the caliper body 130. At this time, the piston 132 is in close contact with the disk 110 while advancing by the injected brake oil.

While the inner pad 125 is in close contact with the disk 110, the caliper body 130 reacts backward with respect to the forward action of the piston 132 by the pressure of the brake oil. In this case, the caliper body 130 moves backwards while sliding in the pin hole 123a of the guide part 123 of the caliper bracket 120 through the sliding pin 134. The close contact portion 138 formed at the lower portion of the caliper body 130 moving backward pulls the outer pad 126 to closely contact the outer surface of the disk 110.

According to the above process, the contact of the disk 110 of the inner and outer pads 125 and 126 stops the rotational motion of the disk 110 or decreases the rotational speed through friction.

However, the sliding pin 134 sliding the pinhole 123a of the caliper bracket 120 while being fixed to the caliper body 130 has a cross-sectional area of the same straight shape in the longitudinal direction, and from the pinhole 123a during brake operation. Bending stress acted on the sliding pin 134 by the bending load transmitted. As described above, the sliding pin 134 in which the bending stress is applied causes bending in an extreme case, and thus the flow in the pinhole 123a was not smooth.

Therefore, the present invention has been devised in view of the conventional problems as described above, it is possible to minimize the bending stress of the sliding pin according to the bending load transmitted from the pinhole during brake operation to prevent bending deformation of the sliding pin. It is to provide a sliding pin structure of the disc brake.

1 is a perspective view of a partially cut bottom view showing a conventional disc brake

Figure 2 is a cross-sectional view showing the structure of the sliding pin and the pinhole of the conventional disc brake

3 is a cross-sectional view of the main portion showing the sliding pin structure of the disk brake according to an embodiment of the present invention

Figure 4 is a partial cutaway cross-sectional view showing a sliding pin structure of the disk brake according to another embodiment of the present invention

Explanation of symbols on the main parts of the drawings

34, 37: sliding pins 34a, 37a: taper

34b, 37b: Groove 34c, 37c: Rubber Bush

The present invention for achieving the above object is a caliper body is a sliding pin which is slidably coupled to the pinhole of the guide portion to press each pad located at both ends of the disk while flowing along the guide portion of the caliper bracket the caliper body In the sliding pin structure of the disk brake is fixed to, the sliding pin provides a disk brake sliding pin structure that is tapered toward the distal side.

Hereinafter, an embodiment of the present invention will be described in more detail based on the accompanying drawings.

3 is a view illustrating a sliding pin structure of a disc brake having a taper according to an embodiment of the present invention, which is fixed to both side ends of the caliper body 30 by bolts 35 to guide portions of the caliper bracket 20. On the sliding pin 34 slidably coupled to the pinhole 23a formed at 23, a taper 34a is formed on the distal end side, and an annular groove 34b is formed on the outer circumferential surface of the taper 34a, and the annular shape An annular rubber bush 34c having a diameter larger than the outer diameter of the sliding pin 34 is installed in the groove 34b.

Accordingly, the sliding pin 34 is inclined downward toward the taper 34a, i.e., the distal end thereof, to gradually form a small diameter, and the bending load generated from the pinhole 23a during the brake operation is the sliding pin 34 directly. It is not delivered to) and is blocked and extinguished by a gap between the pinhole 23a and the taper 34a. At this time, the rubber bush 34c fitted to the outside of the taper 34a compensates for the cap between the pinholes 23a by the taper 34a to absorb vibrations according to the gap.

4 is a view illustrating a sliding pin structure of a disc brake having a taper according to another embodiment of the present invention, in which the sliding pin 37 is different from the taper 34a formed on the entirety of the sliding pin 34 in one embodiment. The taper 37a is partially formed only at the distal end side of the taper, and an annular groove 37b is formed on the outer circumferential surface of the taper 37a, and the diameter larger than the outer diameter of the sliding pin 37 is formed in the annular groove 37b. An annular rubber bush 37c is installed. That is, the taper 37a is formed only on a part of the distal end of the sliding pin 34 through which the bending load is concentrated from the pinhole, thereby blocking the bending load, and maintaining the diameter corresponding to the pinhole in the remaining portion, thereby providing a taper during brake operation. 37a) to reduce the vibration caused by the gap between the pinhole.

As described above, the present invention forms a taper toward the distal end of the sliding pin of the caliper body coupled with the pinhole of the caliper bracket, thereby minimizing the occurrence of bending stress of the sliding pin due to the bending load from the pinhole during brake operation. have.

Therefore, the present invention can prevent bending deformation of the sliding pin, thereby making it possible to smoothly make sliding contact between the sliding pin and the pinhole and improve the performance of the disc brake.

Although the present invention has been shown and described in connection with specific embodiments, it is common knowledge in the art that various modifications and changes can be made without departing from the spirit and scope of the invention as indicated by the appended utility model registration claims. Anyone who has a can easily know.

Claims (3)

In the sliding pin structure of the disc brake, the sliding pin which is slidably coupled to the pinhole of the guide part to press each pad located at both ends of the disk while the caliper body flows along the guide part of the caliper bracket, , Disk brake sliding pin structure characterized in that the tapered is formed in the sliding pin toward the distal end side. The disk brake sliding pin structure of claim 1, wherein the taper is formed only at the distal end portion. 3. The sliding pin structure of a disc brake according to claim 1 or 2, wherein an annular groove is formed on an outer circumferential surface of the taper, and an annular rubber bush is provided in contact with the pinhole.