KR200492297Y1 - Reflux channel structure of linear sliding rail - Google Patents

Abstract

The structure of the return channel of the linear sliding rail of the present invention includes a sliding rail, a sliding block, two or more return pipes, and two end covers, wherein a sliding groove is installed in the center of the bottom of the sliding block, and the sliding block is It is installed over the sliding rail through a sliding groove, at least one sliding channel is installed between the sliding groove and both sides of the sliding rail, and a plurality of balls are installed in the sliding channel to slide, and the sliding block is It is possible to move a reciprocating position on the sliding rail through a ball, and the outer side of each sliding channel is installed to be numerically matched with a sliding channel on the same side on the sliding block, and at the same time, the front and rear ends of the sliding block A plurality of threads are protruded through the straight reflux channel, and a plurality of threads protrude into the inner tube of the reflux tube, and the threads are installed in an odd number of non-divided, so that when the ball passes through the reflux tube, the side of a specific angle by the thread You will be able to rotate the direction.

Description

Reflow channel structure of linear sliding rail {REFLUX CHANNEL STRUCTURE OF LINEAR SLIDING RAIL}

The present invention relates to a structure of a reflux channel of a linear sliding rail, and more particularly, to a structure of a reflux channel of a linear sliding rail that has a long service life and can prevent noise or noise.

Linear sliding rails are mainly used in the field of linear reciprocating motion, and can realize high-precision linear motion in high load situations. The role of the linear sliding rail is to support and guide the moving member (work bed) so that the moving member moves in a reciprocating linear position along a predetermined direction. Since the friction method of the linear sliding rail is rolling friction, the friction coefficient falls to about 1/50 guided by the existing sliding, so that the gap between the kinetic friction force and the static friction force can be further reduced.

In addition, the conventional linear sliding rail mainly includes a sliding rail and a sliding block, wherein a sliding groove is installed in the center of the bottom of the sliding block, the sliding block is installed over the sliding rail through the sliding groove, and A ball sliding channel and a reflux channel used for circulation of a plurality of balls are installed between the sliding rails, and as the balls roll, the frictional force between the sliding block and the sliding rail is reduced to a minimum.

However, the conventional structure as described above has the following problems in practical application.

(1) When the linear sliding rail is operated, the ball is pushed forward one by one only along the running direction of the moving member, so it is difficult to rotate in the lateral direction affected by the reflux channel in the reflux process, so the load of the ball is All are concentrated at the same point, reducing the service life. (2) Since the outer diameter of the bent point of the reflux channel is larger than that of the ball, when the ball is refluxed, the left and right positions of the balls are shifted from each other to form a gap in the eccentric ball diameter of the ball. In addition, the eccentricity forms an irregular motion when the ball is pushed forward, and gives different speeds to the ball, thereby generating annoying noise.

Therefore, the inventor of the present invention provides the present invention by adding design to many years of experience based on creation, reviewing in various aspects, making sample trials, and experimenting, and proceeding with several revisions and improvements.

The technical task to be solved in the present invention is to solve the problem of noise generation during the durability of the conventional linear sliding rail and the ball return.

In the present invention, the following technical solutions are provided to solve the above problem.

The structure of the return channel of the linear sliding rail of the present invention includes a sliding rail, a sliding block, two or more return pipes, and two end covers, wherein a sliding groove is installed in the center of the bottom of the sliding block, and the sliding block is It is installed over the sliding rail through a sliding groove, at least one sliding channel is installed between the sliding groove and both sides of the sliding rail, and a plurality of balls are installed in the sliding channel to slide, and the sliding block is It is possible to move a reciprocating position on the sliding rail through a ball, and the outer side of each sliding channel is installed to be numerically matched with a sliding channel on the same side on the sliding block, and at the same time, the front and rear ends of the sliding block A plurality of threads are protruded through the straight reflux channel, and a plurality of threads protrude into the inner tube of the reflux tube, and the threads are installed in an odd number of non-divided, so that when the ball passes through the reflux tube, the side of a specific angle by the thread Directional rotation is enabled, and the reflux pipe is installed through the reflux channel, and two end covers are assembled and installed on the front and rear surfaces of the sliding block, respectively, and installed in a bent shape on the inner surface thereof. By using the connection of the orbiting groove, the plurality of balls are made to perform a return circulation cloud between the sliding channel and the return pipe. Through this, it is possible to implement the structure of the reflux channel of the linear sliding rail.

The present invention has the following advantages compared to the prior art.

The reflux channel structure of the linear sliding rail of the present invention, when the ball is in the no-load operation of the reflux tube, the ball actively generates a lateral rotation of a specific angle through the guidance of the thread, and the ball is By refluxing up to the sliding channel to prevent a specific part from continuously receiving force when receiving a load, deformation at the point where the ball is always receiving force is prevented, thus effectively extending the service life of the linear sliding rail. , Using a design in which the thread is installed in an odd number of non-divided threads, the ball rotates in the lateral direction and then returns to its original position, or it is repeatedly subjected to a force by circulating in two specific vertical points or four vertical points. When the ball is rotated into the reflux tube from a turning groove having a relatively large outer diameter, concentricity is formed due to natural rotation in the process of pushing the ball, making the ball run regularly at the same speed. Prevents annoying noise or noise from occurring.

1 is a three-dimensional assembly view of the present invention;
2 is a three-dimensional exploded view of the present invention;
3 is an assembly plan view of the present invention;
Figure 4 is an AA cross-sectional view of Figure 3 in the present invention;
5 is a cross-sectional view taken along BB of FIG. 3 in the present invention;
Figure 6 is a cross-sectional view of Figure 5 in the present invention;
7 is a cross-sectional view of a first preferred embodiment of the reflux tube of the present invention;
8 is a cross-sectional view of a relatively preferred second embodiment of the reflux tube of the present invention;
9 is a cross-sectional view of a third preferred embodiment of the reflux tube of the present invention;
10 is an explanatory diagram of an operation in which the ball (only one shown) of the present invention rotates in the lateral direction under the influence of a screw thread in the reflux tube.

In order to help the judges understand the purpose, features, and effects of the present invention, it will be described in more detail below with reference to the accompanying drawings.

1 to 6, the present invention includes a sliding rail 10, a sliding block 20, two or more reflux pipes 30 and two end covers 40, wherein the sliding block ( 20) A sliding groove 21 is installed in the center of the bottom, and the sliding block 20 is installed over the sliding rail 10 through the sliding groove 21, and slides with the sliding groove 21. At least one sliding channel 51 is installed between both sides of the rail 10, and a plurality of balls 50 are installed in the sliding channel 51 to slide, so that the sliding block 20 ) To move the reciprocating position on the sliding rail 10, and the outer side of each sliding channel 51 is installed to be numerically matched with the sliding channel 51 on the same side on the sliding block 20 At the same time, the sliding block 20 passes through the straight return channel 22 of the front and rear ends, and a plurality of threads 31 protrude into the inner tube of the return tube 30, and the threads 31 are It is installed in an odd number that is not divided, so that when the ball 50 passes through the reflux pipe 30, it is possible to rotate laterally at a specific angle by the screw thread 31, and the reflux pipe 30 Is installed through the reflux channel 22, two end covers 40 are assembled and installed on the front and rear ends of the sliding block 20, respectively, and a turning groove installed in a curved shape on the inner side thereof By using the connection of (41), the plurality of balls (50) is made to perform a return circulation cloud between the sliding channel (51) and the return pipe (30).

In the feedback channel structure of the linear sliding rail provided by the present invention, two sliding channels 51 are respectively installed between both sides of the sliding groove 21 and the sliding rail 10, and the reflux channel 22, The return pipe 30 and the turning groove 41 are installed in the same quantity as the two sliding channels 51 on each side.

In the structure of the reflux channel of the linear sliding rail provided by the present invention, the reflux tube 30 is a plastic tube having wear resistance.

In the reflux channel structure of the linear sliding rail provided by the present invention, three threads 31 are installed in the inner tube portion of the reflux tube 30 (shown in Figs. 1 to 7).

In the reflux channel structure of the linear sliding rail provided by the present invention, five threads 31 are installed in the inner tube portion of the reflux tube 30 (shown in FIG. 8).

In the reflux channel structure of the linear sliding rail provided by the present invention, seven threads 31 are installed in the inner tube portion of the reflux tube 30 (shown in FIG. 9).

In the feedback channel structure of the linear sliding rail provided by the present invention, the scrapers 60 are again coupled to the outside of the two end covers 40, respectively.

In the feedback channel structure of the linear sliding rail provided by the present invention, an upper holding member 70 is separately installed between the sliding rail 10 and the sliding block 20.

Through the above structure, when the ball 50 is in the no-load operation of the reflux tube 30, the ball 50 actively generates a lateral rotation of a specific angle through the guidance of the thread 31 And (shown in FIG. 10), when the ball 50 flows back to the sliding channel 51 and receives a load, a specific portion (single point) no longer receives force, so that the ball 50 Since deformation at the point where the force is always applied is prevented, the service life of the linear sliding rail is effectively extended, and the ball 50 is side by using a design in which the screw thread 31 is installed in an odd number that is not divided. It rotates in the direction and then returns to its original position, or prevents repeatedly receiving force by circulating a specific two points up and down or four points up and down, left and right, and the ball 50 is said to be in the turning groove 41 with a relatively large outer diameter. When the ball 50 is rotated into the reflux tube 30, concentricity is formed due to natural rotation in the process of pushing the ball 50, making the top three balls 50 run regularly at the same speed, which is annoying to people. Prevent noise or noise from occurring.

The above is only a relatively preferred embodiment of the present invention, and thus does not limit the scope of the present invention. If modifications, equivalent levels of substitution and improvement are made based on the claims of the present invention, all of them fall within the scope of protection of the present invention.

10: sliding rail 20: sliding block
22: reflux channel 30: reflux tube
40: end cover 50: ball
60: scraper 70: upper holding member
21: sliding groove 31: thread
41: pivot groove 51: sliding channel

Claims (8)

It includes a sliding rail, a sliding block, two or more reflux pipes and two end covers;
Here, a sliding groove is installed in the center of the sliding block bottom, the sliding block is installed across the sliding rail through the sliding groove, and at least one sliding channel is installed between the sliding groove and both sides of the sliding rail, , A plurality of balls are installed to be slid in the sliding channel, so that the sliding block can reciprocate in the sliding rail through the balls, and the outside of each sliding channel slides on the same side on the sliding block. It is installed so as to be numerically matched with the channel, and at the same time passes through the linear reflux channel of the front and rear ends of the sliding block; A plurality of threads protrude into the inner tube portion of the reflux tube, and the threads are installed in an odd number of non-divided, so that when the ball passes through the reflux tube, the lateral rotation of a specific angle can be performed by the threads. , The reflux tube is installed through the reflux channel;
Two end covers are assembled and installed on the front and rear end surfaces of the sliding block, respectively, and the plurality of balls flow back between the sliding channel and the reflux pipe by using a connection of a turning groove installed in a bent shape on the inner surface of the sliding block. Reflow channel structure of a linear sliding rail, characterized in that making it possible to circulate rolling. The method of claim 1,
Linear sliding rail, characterized in that two sliding channels are respectively installed between the sliding groove and both sides of the sliding rail, and the return channel, the return pipe, and the turning groove are installed in the same quantity as the two sliding channels on each side. Structure of the reflux channel. The method of claim 1,
The reflux channel structure of a linear sliding rail, characterized in that the reflux tube is a plastic tube having wear resistance. The method of claim 1,
The return channel structure of the linear sliding rail, characterized in that the three threads are installed in the inner tube portion of the return pipe. The method of claim 1,
The return channel structure of the linear sliding rail, characterized in that the five threads are installed in the inner tube portion of the return pipe. The method of claim 1,
The return channel structure of the linear sliding rail, characterized in that the seven threads are installed in the inner tube portion of the return pipe. The method of claim 1,
The return channel structure of the linear sliding rail, characterized in that the scraper is re-coupled to each of the two end covers outside. The method of claim 1,
The return channel structure of the linear sliding rail, characterized in that the upper holding member is separately installed between the sliding rail and the sliding block.

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