JP3170521U - Linear slide rail with no-load path positioning structure - Google Patents

Abstract

A linear slide rail is provided which is easy to assemble a circulation module and does not move outward along a radial direction due to a collision of a rolling body. A slide module includes a rail and a slider module. The slider module includes one slide block and two circulation modules, and is arranged on both outer sides in the radial direction of the slide block. Are each provided with one positioning structure (or concave groove) 12. The circulation module is divided into an end cap part and a circulation pipe part B, and has a substantially L shape. The end cap part is attached to an end surface of the slide block 1 in the axial direction, and By combining the tube portion B with the positioning structure 12, the degree of freedom in the radial direction C is restricted. [Selection] Figure 6

Description

The present invention relates to a linear slide rail, and more particularly to a linear slide rail having a rotational localization structure.

Please refer to FIG. The known linear slide rail includes one rail 1, one slider 2, two circulation members 3, and two end caps 4. The rail 1 is provided with two rolling grooves 11. The slider 2 is provided on the rail 1, and rolling grooves 21 corresponding to the rolling grooves 1 of the rail 1 are provided on both inner sides of the slider 2. The rolling groove 11 and the rolling groove 21 constitute one load path. Further, on both outer sides of the slider 2, a slider half-circulation path 22 is provided. The circulating member 3 is attached to the position of the slider semi-circulating path 22, and the circulating member 3 is provided with a circulating member semi-circulating path 31 corresponding to the slider semi-circulating path 22. The slider half-circulation path 22 and the circulation member half-circulation path 31 constitute one circulation path. Further, hook portions 32 are provided at both ends of the half-circulation path 31 for the circulation member. The two end caps 4 are respectively installed on both end surfaces of the slider 2. The end cap 4 has two catch holes 41 and two flow paths 42, and the catch holes 41 serve to hook the catch portions 32, and fix both the end caps 4 and the both flow members 3 to each other. Thus, one rectangular frame is formed. Moreover, the slider 2 is installed between the frames, and the load path and one end of the circulation path are joined to both ends of the circulation path 42, respectively. Then, the circulation path 42, the load path, and the circulation path constitute one circulation path. A plurality of rolling bodies 5 are installed in this circulation path. Thereby, the slider 2 is reciprocated on the rail 1.

However, the known linear slide rail has the following problems.
(1) The assembly of the circulation module (or the circulation member and the end cap) has a complicated structure. Since the end cap and the circulating member are combined by the hook method, if a trouble occurs between these two components, it is necessary to remove both components, and during the removal, they are caught using a hand tool. The catching part must be removed from the catching hole, and if the operator works with excessive force, the catching part may be damaged. In addition, since the surface of the circulating member and the end cap are easily damaged, in order to eliminate the user's complaints and complaints, both components must be replaced with new ones, resulting in wasted members and cost. There was a problem that it could become bulky.

(2) The rolling bodies easily collide with each other in the circulation path, and this collision phenomenon becomes prominent particularly when the rolling bodies enter the half-circulation path of the circulation member from the U-shaped circulation path. This is because, since the semi-circulation path of the circulation member is an unloaded path, the rolling element is not constrained, and a radial force is generated when it collides with the half-circulation path. There is no stereotaxic structure, so the circulating member is likely to move outward along the radial direction due to the collision of the rolling elements. As a result, a floating gap is generated in the circulation path, and foreign matter enters the gap. This causes a problem of poor circulation of the rolling element. In the worst case, the slider cannot reciprocate.

Therefore, the main object of the present invention is to provide a circulating localization structure that allows the circulation module to be removed or assembled easily and quickly, and that the circulation module does not move outward along the radial direction due to the collision of the rolling elements. To provide a linear slide rail.

In order to achieve the above object, claim 1 of the present invention is a linear slide rail having a circulating localization structure including a rail and a slider module, and the rail extends in one direction. The elongated direction is defined as the axial direction, the direction perpendicular to the axial direction is defined as the radial direction, each rolling groove is provided on both inner sides, the slider module, It is installed on the rail and can reciprocate with respect to the rail, and consists of one slide block and two circulation modules. The inner side of the slide block corresponds to the rolling groove of the rail. Each rolling groove is provided, and the rolling groove of the rail and the rolling groove of the slide block constitute one load path, and the radial direction A circulation orientation structure is provided on the outside, and the circulation module includes an end cap part and a circulation pipe part, and the end cap part is attached to an end face in the axial direction of the slide block, and two circulation modules are provided. A linear frame having a circulating localization structure is characterized in that the rectangular pipe is combined to form a rectangular frame, and the freedom of radial direction is constrained by combining the circulating pipe portion with the circulating localization structure.・ Provide slide rails.

Claim 2 of the present invention is that, in claim 1, the circulation pipe part has one quantity, one end is joined to one side surface of the end cap part, and the other end is defined as a coupling end, A linear slide rail having a flow localization structure is provided in which the circulation module is formed in a substantially L shape by being exposed.

Claim 3 of the present invention is that, in claim 1, there are two quantities of the circulation pipe part, each one end is joined to one side surface of the end cap part, and each other end is defined as a coupling end. A linear slide rail having a circulating localization structure is provided in which the circulation module is formed in a substantially U shape by being exposed in the air.

According to a fourth aspect of the present invention, in the second aspect, the circulation module includes an outer circulation member and an inner circulation member, and the outer circulation member includes a first end cap and a first extending portion. One extending portion has one end joined to one side surface of the first end cap and the other end exposed in the air, so that the outer circulation member is formed in a substantially L shape, and the inner circulation member Includes a second end cap and a second extending portion, and the second extending portion has one end joined to one surface of the second end cap and the other end exposed in the air. The circulation member is formed in a substantially L shape, and the first end cap and the second end cap are stacked to constitute the end cap portion, and the first extending portion and the second extending portion. Combining parts with each other Accordingly, characterized in that it constitutes the circumfluence pipe unit, to provide a linear slide rail having a circumfluence positioning structures.

According to a fifth aspect of the present invention, in the fourth aspect, the first end cap is provided with two first half-circulation paths, and the second end cap corresponds to the two first half-circulation paths. Two second half-circulation paths are provided, and the first half-circulation path and the second half-circulation path constitute one circulation path, and the first extension portion includes one first half-circulation path. The second extending portion is provided with a second semi-pipe corresponding to the first semi-pipe, and the first semi-pipe and the second half p The two ends of the two circulation paths are respectively coupled to the both ends of the circulation pipe line and the load path, thereby forming one circulation path and installing a plurality of rolling elements in the circulation path. Provided is a linear slide rail having a circulating localization structure.

The present invention has the above-described configuration. The circulation module can be easily and quickly removed or assembled, and the circulation module does not move outward along the radial direction due to the collision of the rolling body. There is an effect.

1 is an overall exploded perspective view of a known linear slide rail system. (Example 1) which is the disassembled perspective view (the 1) of the linear slide rail provided with the circulation localization structure of this invention. (Example 1) which is the disassembled perspective view (the 2) of the linear slide rail provided with the circulation localization structure of this invention. (Example 1) which is a cross-sectional view of the slide block of the slider module which concerns on this invention. 1 is an overall exploded perspective view of a linear slide rail system of the present invention (Example 1). (Example 1) which is a cross-sectional view of the linear slide rail provided with the current orientation structure of this invention. (Example 2) which is a cross-sectional view of the slide block of the slider module which concerns on this invention. It is a disassembled perspective view of the circulation module of this invention (Example 3).

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

As shown in FIGS. 2 to 6, the linear slide rail having the circulating localization structure of the present invention includes a rail 3 and a slider module.

The rail 3 is elongated in one direction and has an elongated shape, the extending direction is defined as the axial direction X, the direction perpendicular to the axial direction X is defined as the radial direction C, and the rolling grooves are formed on both outer sides. 31 is provided.

The slider module is provided on the rail 3 and can reciprocate with respect to the rail 3. The slider module includes one slide block 1 and two circulation modules 2, and rolling grooves 11 corresponding to the rolling grooves 31 of the rail 3 are provided on both inner sides of the slide block 1. The rolling groove 31 and the rolling groove 11 constitute one load path 90, and the circulating localization structure 12 is provided on both outer sides in the radial direction C. This circulating localization structure 12 may be a continuous concave groove or a continuous convex block, or a discontinuous concave groove or a discontinuous convex block. In this embodiment, the circulating localization structure 12 is a continuous concave groove. This is because it is relatively easy to produce a continuous groove because the slide block is manufactured by injection molding. In addition, when manufacturing a discontinuous form, it is necessary to process using a machine stand, but this discontinuous form is also the characteristics of this invention.

The circulation module 2 includes an outer circulation member 21 and an inner circulation member 22, and the outer circulation member 21 includes a first end cap 211 and a first extending portion 212. The first extending portion 212 has one end joined to one side surface of the first end cap 211 and the other end exposed in the air, so that the outer circulation member 21 is formed in an approximately L shape. The first end cap 211 is provided with two first half circulation paths 2111, and the first extending portion 212 is provided with one first half pipe 2121. The inner circulation member 22 includes a second end cap 221 and a second extending portion 222. The second extending portion 222 has one end joined to one side surface of the second end cap 221 and the other end exposed in the air, so that the inner circulation member 22 is formed in an approximately L shape. The second end cap 221 is provided with two second half-circulation paths 2211 corresponding to the two first half-circulation paths 2111. The second extending portion 222 is provided with a second half pipe 2221 corresponding to the first half pipe 2121. Moreover, one end cap portion A is formed by stacking the first end cap 211 and the second end cap 221. The first extending portion 212 and the second extending portion 222 are combined with each other to constitute one circulation pipe portion B.

The end cap part A has a circulation path (not shown) composed of the first half-circulation path 2111 and the second half-circulation path 2211, and the circulation path is substantially U-shaped. The circulation pipe section B has a circulation pipe B1 (see FIG. 6) including the first half pipe 2121 and the second half pipe 2221. When the outer circulation member 21 and the inner circulation member 22 are combined, one end of the circulation pipe B is joined to one side surface of the end cap part A, and the other end is defined as a coupling end, which is exposed in the air. The circulation module 2 is formed in a substantially L shape. Moreover, when the circulation module 2 and the slide block 1 are assembled, one end of the end cap part A is attached to the end face in the axial direction X of the slide block 1, and the connecting pipe B is the end of the coupling end B2. It is combined with another end of the cap part A (see FIG. 3). Moreover, one rectangular frame (see FIG. 3) is formed by combining the two circulation modules 2. In addition, both ends of the circulation path are coupled to the circulation path B1 and the load path 90, respectively. The two circulation paths are connected to the load path 90 and both ends of the circulation pipe B1 to form one circulation path, and a plurality of rolling bodies 5 are installed in the circulation path. The rolling body 5 rolls between the slide block 1 and the rail 3 as a transmission medium. Thereby, the slide block 1 can be smoothly reciprocated on the rail 3.

Furthermore, in the prior art, in order to solve the problem that the circulation member (or the circulation module) moves outward along the radial direction due to the collision of the rolling bodies, the circulation pipe portion B is fitted in the circulation localization structure 12, Thereby, the freedom degree of the radial direction C of the circulation pipe part B can be restrained. And no matter how the rolling body 5 collides with the circulation pipe B1, no radial displacement occurs in the circulation pipe B. Therefore, it can avoid that a foreign material penetrate | invades into a circulation path, a rolling body can roll more smoothly in a circulation path, and the service life can be extended.

In the second embodiment of the present invention, as shown in FIG. 7, the shape of the circulating localization structure 12 of the slide block 1 is different from that of the first embodiment, and is formed of a convex block. This convex block may be a continuous convex block or a plurality of independent convex blocks. In consideration of the processability of the convex block, a continuous convex block is preferable.

In the third embodiment of the present invention, as shown in FIG. 8, the structure of the circulation module is different from that of the first embodiment. This circulation module includes an outer circulation member 21 and an inner circulation member 22. The outer circulation member 21 includes one first end cap 211 and two first extending portions 212. The two first extending portions 212 have one end joined to one surface of the first end cap 211 and the other end exposed in the air, so that the outer circulation member 21 is formed in a substantially U shape. The The first end cap 211 is provided with two first half flow paths 2111. Two first half pipes 2121 are respectively provided in the two first extending portions 212.

The inner circulation member 22 includes one second end cap 221 and two second extending portions 222. The two second extending portions 222 have one end joined to one side surface of the second end cap 221 and the other end exposed in the air, so that the inner circulation member 22 is formed in a substantially U shape. The The second end cap 221 is provided with two second half-circulation paths 2211 corresponding to the two first half-circulation paths 2111. The two second extending portions 222 are provided with second half pipes 2221 corresponding to the first half pipes 2121. In addition, the first end cap 211 and the second end cap 221 are stacked to constitute one end cap portion. The first extending portion 212 and the second extending portion 222 are combined with each other to constitute one circulation pipe portion. The end cap portion has a circulation path composed of the first half-circulation path 2111 and the second half-circulation path 2211, and the circulation path has a substantially U-shape. The circulation pipe section has a circulation pipe line composed of the first half pipe line 2121 and the second half pipe line 2221. By combining the outer circulation member 21 and the inner circulation member 22, one end of each of the two circulation conduits is bonded to one surface of the end cap portion, and the other end is defined as a coupling end, and is exposed in the air. Thus, the circulation module 2 is formed in a substantially U shape. Moreover, when the circulation module 2 and the slide block 1 are assembled, one end of the end cap portion is attached to the end surface of the slide block 1 in the axial direction X, and the two circulation pipe portions of one of the circulation modules are coupled. The end is coupled to the coupling end of both the circulation pipe portions of the other circulation module. One rectangular frame is constructed by assembling both circulation modules. Other configurations and assembly are the same as those in the first embodiment, and detailed description thereof is omitted.

<Prior art>
DESCRIPTION OF SYMBOLS 1 ... Rail, 11 ... Rolling groove, 2 ... Slider, 21 ... Rolling groove, 22 ... Semi-circulation path for sliders, 3 ... Circulation member, 31 ... For circulation member Semicircular flow path, 32... Catching portion, 4... End cap, 41... Catching hole, 42.
<Invention>
DESCRIPTION OF SYMBOLS 1 ... Slide block, 11 ... Rolling groove, 12 ... Circulation localization structure, 2 ... Circulation module, 21 ... Outer circulation member, 211 ... 1st end cap, 2111 ... First semi-circulation path, 212... First extending portion, 2121... First semi-pipe, 22... Inner circulation member, 221. Circulating path, 222... Second extending portion, 2221... Second semi-pipe, 3. Rail, 31... Rolling groove, 5. ... End cap part, B ... Circulation pipe part, B1 ... Circulation pipe line, B2 ... Coupling end, C ... Radial direction, X ... Axial direction.

Claims (5)

A linear slide rail having a circulating localization structure including a rail and a slider module,
The rail is elongated in one direction and has a long shape, the extending direction is defined as the axial direction, the direction perpendicular to the axial direction is defined as the radial direction, and the rolling grooves are formed on both outer sides of the rail. Is provided,
The slider module is installed on the rail and can reciprocate with respect to the rail, and includes one slide block and two circulation modules.
Another rolling groove corresponding to the rolling groove of the rail is provided on both inner sides of the slide block, and one load path is formed by the rolling groove of the rail and the rolling groove of the slide block. And a gyrating localization structure is provided on both radially outer sides of the slide block,
The circulation module includes an end cap portion and a circulation pipe portion, and the end cap portion is attached to an end surface in the axial direction of the slide block, and a single rectangular frame is obtained by combining the two circulation modules. Form the
A linear slide rail having a recurrent localization structure, wherein the recirculation tube portion is combined with the recurrent localization structure to restrict a degree of freedom in a radial direction. The circulation pipe part has one quantity, one end is joined to one side surface of the end cap part, the other end is defined as a coupling end, and the circulation module is substantially L-shaped. The linear slide rail having the circulating localization structure according to claim 1, wherein the linear slide rail is formed in a shape. The circulation pipe part has two quantities, each one end is joined to one side surface of the end cap part, each other end is defined as a coupling end, and the circulation module is exposed in the air. The linear slide rail having the circulating localization structure according to claim 1, wherein the linear slide rail is formed in a substantially U shape. The circulation module includes an outer circulation member and an inner circulation member, and the outer circulation member includes a first end cap and a first extending portion, and the first extending portion has one end of the first end cap. The outer circulation member is formed in a substantially L shape by joining the one side surface and the other end exposed in the air, and the inner circulation member includes a second end cap and a second extending portion. The second extending portion has one end joined to one side surface of the second end cap and the other end exposed in the air, so that the inner circulation member is formed in a substantially L shape, In addition, by stacking the first end cap and the second end cap, the end cap portion is configured, and the first extension portion and the second extension portion are combined with each other, whereby the circulation pipe portion is To make up The symptom, linear slide rail having a circumfluence localization structure according to claim 2. The first end cap is provided with two first half-circulation paths, and the second end cap is provided with two second half-circulation paths corresponding to the two first half-circulation paths, The first half-circulation path and the second half-circulation path constitute one circulation path, the first extension portion is provided with one first half-pipe, and the second extension portion is provided with the above-mentioned A second semi-pipe corresponding to the first half-pipe is provided, and the first half-pipe and the second half-pipe constitute a single flow-pipe, and both ends of the two flow-pipes are 5. The circulating localization structure according to claim 4, wherein one circulation path is configured by coupling with both ends of the circulation pipe and the load path, and a plurality of rolling elements are installed in the circulation path. Linear slide rail with