JP4173403B2 - Linear motion device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a linear motion device comprising a guide rail, a slider, and a plurality of rolling elements, wherein the slider is formed by integrating two or more members formed as separate members in an assembly process.
[0002]
[Prior art]
A conventional example of a linear guide device is shown in FIG. As shown in this figure, the linear guide device includes a guide rail 1, a slider (also referred to as “bearing”) 2, and a plurality of balls (rolling elements) 3.
The guide rail 1 has rolling grooves 11 extending in parallel to the longitudinal direction on both side surfaces. The slider 2 includes leg portions 2A arranged on both sides in the width direction of the guide rail 1, and a horizontal portion 2B connecting the both leg portions 2A. The horizontal portion 2B is arranged on one end side (in this figure, the upper surface side of the guide rail 1) in the thickness direction of the guide rail 1 (direction perpendicular to both the length direction and the width direction). Then, both inner side surfaces of the slider 2 are disposed opposite to both side surfaces of the guide rail 1.
[0003]
The slider 2 is divided into a main body 21 and an end cap 22 in the linear movement direction, and the end caps 22 are disposed at both ends of the main body 21 in the linear movement direction. A rolling groove 21 a that faces the rolling groove 11 of the guide rail 1 is formed on both inner side surfaces of the main body 21. These rolling grooves 11 and 21a form the rolling passage 12 of the ball 3.
A straight return passage 21 b is formed outside the rolling groove 21 a of the main body 21 of the slider 2. A semicircular arc direction changing path 22a is formed in portions (outer portions of the leg portions 2A) arranged on both side surfaces of the guide rail 1 of the end cap 22. The rolling path 12 and the return path 21b are communicated with each other through the direction changing path 22a, and a circulation path 25 that circulates the ball 3 infinitely is formed through these paths. This linear guide device has four circulation paths (two to four rows), and the slider 2 slides along the guide rail 1 as the ball 3 rolls along each circulation path.
[0004]
In the conventional linear guide device, the return passage 21b is formed by drilling the metal main body 21, but this work takes time and cost.
On the other hand, in Patent Document 1, at least a width direction outer side portion (a portion where the return passage is formed) of the leg portion is integrally formed with the block body as a molded body made of synthetic resin, and thus, from synthetic resin. It is described that the return path to be formed forms a slider composed of an undivided body.
[0005]
Further, as an improved invention of this slider, Patent Document 2 discloses that a locking groove is provided in the block body in order to prevent the molded body made of synthetic resin from being peeled off from the block body and causing displacement. Has been. It is described that by adopting such a configuration, the connection between the molded body and the block body becomes strong, and generation of noise accompanying ball circulation can be prevented.
[0006]
Further, in Patent Document 3, a metal block having a leg portion in the width direction outer side (side surface forming portion) and end surface forming portions arranged at both ends in the linear motion direction of the block body as a molded body made of synthetic resin is disclosed. In a slider integrally formed with a body, it is disclosed that an upper surface forming portion that connects both end surface forming portions with the upper surface of a block body is integrally formed simultaneously with a side surface forming portion and an end surface forming portion. By adopting such a configuration, even if the side surface forming portion where the return passage is formed contracts and this contracting force acts on the end surface forming portion, the upper surface forming portion resists the contracting force and the end surface forming portion. It is described that the end face forming portion is prevented from floating with respect to the end face of the block body.
[0007]
Further, Patent Document 4 describes a linear guide device in which a slider includes a first component member and a second component member, and both members are screwed. The second component member includes an inner leg having a rolling groove and forming an inner portion in the width direction of the leg portion, and a portion forming a main portion of the horizontal portion. The first component member has a structure in which an outer cap and an end cap, which are arranged in contact with the outer side of the inner leg in the width direction and form the outer side portion of the leg portion in the width direction, are integrated.
[0008]
In this slider, the return path (return path) includes a groove (straight ball guide surface) opened on the upper side (horizontal part side) provided on the outer leg (connection portion) of the first component member, and the first component member. The lower surface of the portion (main body portion) disposed above the groove and the surface disposed on the side of the groove of the inner leg of the first component member (the laterally outer surface of the downward projecting portion) are formed. ing.
[0009]
[Patent Document 1]
JP 7-317762 A
[Patent Document 2]
JP-A-9-291937
[Patent Document 3]
Japanese Patent Laid-Open No. 10-47343
[Patent Document 4]
JP-A-5-248433
[0010]
[Problems to be solved by the invention]
Of the sliders described in the above publications, those in which a molded body made of a synthetic resin is integrally formed with a block body are placed in the mold with the block body as a core, and then the synthetic resin is injection molded into the mold. Obtained by “insert molding”. Therefore, when the block body is set in the mold by this insert molding, a high positioning accuracy of the block body with respect to the mold is required. Further, since the molded body is fixed to the block body by integral molding, correction after molding is difficult. Furthermore, the structure of the integrally molded mold is complicated.
Thus, the linear guide device having a slider in which a molded body made of a synthetic resin is integrally formed with a block body has room for improvement in terms of productivity.
[0011]
In addition, as in the slider described in Patent Document 4, two members formed as separate members are integrated by screwing or the like in the assembly process, and a molded body made of synthetic resin is integrally molded into a block body. Although it is advantageous in terms of productivity as compared with the slider, misalignment may occur during assembly due to processing errors. This misalignment may cause problems in the operability and noise characteristics of the linear guide device.
The present invention has been made to solve the above-described problems of the prior art, and is operated in a linear motion apparatus having a slider in which two or more members formed by separate members are integrated in an assembly process. The objective is to achieve weight reduction and cost reduction without deteriorating performance and noise characteristics.
[0012]
[Means for Solving the Problems]
In order to solve the above problems, the present invention comprises a guide rail, a slider, and a plurality of rolling elements, and rolling grooves of the rolling elements are formed on both side surfaces in the width direction of the guide rail. It consists of leg portions arranged on both sides in the width direction of the rail, and a horizontal portion arranged on one end side in the thickness direction of the guide rail and connecting the both leg portions. A rolling groove of the rolling element is formed by the rolling groove and the rolling groove of the guide rail, and a return path of the rolling element is formed at the both leg portions, The part is also formed with a direction changing path that connects the return path and the rolling path, and the rolling element rolls in a circulation path constituted by the rolling path, the return path, and the direction changing path. One of the guide rail and the slider In the linear motion device for moving, to provide a linear motion device, characterized by the following ▲ 1 ▼ ~ ▲ 6 ▼.
[0013]
(1) The slider is disposed on the metal main body, a synthetic resin frame that is detachably fitted to the outside of the main body, and both ends of the frame in the linear motion direction. And an end cap made of synthetic resin fixed to the main body.
(2) The frame is composed of an outer leg that forms an outer portion in the width direction of the leg portion, and a horizontal portion of the frame that forms an end portion in the linear movement direction of the horizontal portion. It has an inner groove, and has a convex part (for example, a convex part parallel to the return path) inside both outer legs.
(3) The main body includes an inner leg that forms an inner portion in the width direction of the leg portion, and a main body horizontal portion that forms a main portion of the horizontal portion, and has rolling grooves inside both inner legs, and the convex portion. (For example, a recess parallel to the rolling groove) on the outside of both inner legs, and the projection and the projection are fitted into the recess so that the main body and the frame body An interference fit between the inner legs of the body and the outer legs of the frame Integrated.
[0014]
(4) The end cap is composed of an end leg that forms an end portion in the linear movement direction of the leg portion and a horizontal end cap portion that forms an end portion in the linear movement direction of the horizontal portion, and changes direction to the frame body side of both end legs. Has an outer groove on the road.
(5) The longest outer dimension in the slider width direction between the lower ends of the inner legs of the main body in the slider width direction is formed larger than the shortest dimension in the slider width direction between the convex parts of the frame, The attachment / detachment is performed by elastically deforming the frame body and withdrawing / inserting the leg portion side of the main body from the frame body horizontal portion side.
(6) The frame body has the inner groove On the frame horizontal part side and the opposite side The end cap has a substantially semi-disc-shaped flange portion, and the end cap has the outer groove In Above each Receive the circumference of the buttocks each It has a concave surface, and the peripheral surface and the concave surface are formed in a shape in which a gap is generated between the peripheral surface and the concave surface when an end cap is attached to the frame body in which the main body is not integrated.
[0015]
In the linear motion device of the present invention, it is preferable that the peripheral surface and the concave surface are formed so that at least a part of both is in contact.
In the linear motion device of the present invention, the end cap In , Said of the frame Buttock A plate-like portion covering the outer surface of the frame, the gap between the peripheral surface of the frame body and the concave surface of the end cap is covered by the plate-like portion, and the direction change path is sealed in the thickness direction of the slider. Is preferred.
[0016]
In the linear motion device of the present invention, it is preferable that the end cap be positioned with respect to the frame body by the end cap horizontal portion and the frame horizontal portion.
In the linear motion device of the present invention, the horizontal portion of the slider is composed of the frame horizontal portion, the main body horizontal portion and the end cap horizontal portion described above. It refers to the horizontal part of the entire slider.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described.
FIG. 1 is a perspective view showing a linear guide device (linear motion device) corresponding to an embodiment of the present invention. This linear guide device includes a guide rail 1, a slider 2, and a plurality of balls (rolling elements) 3.
The guide rail 1 has rolling grooves 11 extending in parallel to the longitudinal direction on both side surfaces. The slider 2 includes leg portions 2A arranged on both sides in the width direction of the guide rail 1, and a horizontal portion 2B connecting the both leg portions 2A. The horizontal portion 2B is disposed on one end side in the thickness direction of the guide rail 1 (in this figure, on the upper surface side of the guide rail 1). Then, both inner side surfaces of the slider 2 are disposed opposite to both side surfaces of the guide rail 1.
[0018]
A rolling groove 21 a facing the rolling groove 11 of the guide rail 1 is formed on the inner surface of both the leg portions 2 </ b> A of the slider 2. These rolling grooves 11 and 21a form the rolling passage 12 of the ball 3.
A ball return passage 21b is formed in a straight line on the outer portions of both legs 2A, and a direction changing passage 22a that connects the return passage 21b and the rolling passage 12 is formed. The return path 21b, the rolling path 12, and the direction changing path 22a constitute a circulation path 25 for circulating the ball 3 infinitely. This linear guide device is provided with two circulation paths (one pair in two rows), and the slider 2 slides along the guide rail 1 when the ball 3 rolls along each circulation path.
[0019]
The slider 2 of this embodiment is composed of a metal main body 4, a synthetic resin frame 5, and a synthetic resin end cap 6. A side seal 7 is attached to the outside of the end cap 6.
The disassembled state of the slider 2 is shown in a perspective view in FIG. FIG. 3 shows a partial cross-sectional front view of the state in which the main body 4 is integrated with the frame 5. Moreover, the front view of the main body 4 is shown in FIG. 4, and the sectional view on the AA line of FIG. 3 corresponds to a cross-sectional view taken along the line AA in FIG. 2 in a state in which the main body 4 is integrated with the frame 5.
[0020]
As shown in these drawings, the main body 4 includes an inner leg 41 that forms an inner portion in the width direction of both leg portions 2A and a main body horizontal portion 42 that forms a main portion of the horizontal portion 2B of the entire slider. Further, a rolling groove 21 a is formed inside the inner leg 41, and a recess 43 parallel to the rolling groove 21 a is provided outside the inner leg 41. A tapered surface 44 having a small dimension on the concave portion 43 side is formed between the concave portion 43 and the end surface in the width direction of the main body horizontal portion 42.
[0021]
Further, two female screws 45 are formed on both end surfaces of the main body horizontal portion 42 in the linear movement direction. The two female screws 45 are arranged at a predetermined interval in the width direction. A concave portion 46 is formed in the slider width direction central portion of the upper surface of the main body horizontal portion 42, and two female screw holes 47a for attaching other members such as a table are formed in the outer portions 47 on both sides of the concave portion 46 in the linear motion direction. Are formed at predetermined intervals.
[0022]
The main body 4 is manufactured by cutting a material made of a metal such as SUS440C after drawing.
The frame 5 includes an outer leg 51 that forms an outer portion in the width direction of both legs 2A, and a frame horizontal portion 52 that forms an end portion in the linear motion direction of the horizontal portion 2B of the entire slider.
The outer leg 51 includes a first part 51a and a second part 51b. The first part 51a is disposed so as to connect the two horizontal frame parts 52, and a return passage 21b is formed therein. The second part 51b of the outer leg 51 is a protrusion protruding from the linear movement direction end face 51T of the first part 51a, and an inner groove 53 of the direction changing path 22a continuous with the return path 21b is formed in the second part 51b. ing. This inner groove 53 In The substantially semicircular plate-like collar portions 53a and 53b are formed.
[0023]
In other words, the second portion 51b is present in a protruding state on the linear movement direction end surface 51T of the first portion 51a of the outer leg 51, and the flange portion 53a and the frame on the frame body horizontal portion 52 side (upper side) of the second portion 51b. A gap 51e (see FIG. 3) exists between the body horizontal portion 52 and the body horizontal portion 52. Moreover, the lower part 53b (the side opposite to the frame horizontal part 52) of the second part 51b is at a position higher than the lower surface of the first part 51a, and the inner leg 41 of the main body 4 is the lower surface of the first part 51a. Extends to the same position.
[0024]
Further, the linearly moving direction end surface 51T of the first portion 51a of the outer leg 51 and the lower surface (surface on the outer leg 51 side) 51t of the frame horizontal portion 52 are orthogonal to each other, and a step portion 51c is formed at this position. Furthermore, the upper surface (the surface on the frame body horizontal portion 52 side) of the first portion 51 a is formed on a tapered surface 51 d that fits with the tapered surface 44 of the main body 4.
Further, a convex portion 54 parallel to the return passage 21b is formed inside the first portion 51a of the outer leg 51. A through hole 55 corresponding to the female screw 45 of the main body 4 is formed in the frame horizontal portion 52. A recess 56 for positioning the end cap 6 and a through hole 56 a penetrating through the center of the recess 56 are formed at both ends in the width direction of the horizontal frame portion 52. A through hole 57 is formed at the center in the width direction of the frame horizontal portion 52. The through hole 57 is a hole communicating with a through hole (grease nipple mounting hole) 67 provided in the end cap 6.
[0025]
The frame 5 is produced by injection molding a synthetic resin such as POM.
The end caps 6 are members disposed at both ends of the frame body 5 in the linear motion direction. The end caps 61 form the linear motion direction end portions of both the leg portions 2A, and the linear motion end of the horizontal portion 2B of the entire slider. The end cap horizontal portion 62 forms a part.
On the frame body side of the end leg 61, a substantially rectangular parallelepiped protrusion 63 that fits into the step portion 51c of the frame body 5 is formed. The protrusion 63 is open on the frame body side, and an outer groove (semi-arc-shaped recess) 63a of the direction changing path 22a is formed therein. The end of the outer groove 63a on the inner side in the slider width direction is a tongue 63b that scoops up the ball 3 from the rolling groove 12.
[0026]
Further, the outer groove 63 a Are formed with arcuate concave surfaces 63c that receive the circumferential surfaces of the flanges 53a and 53b of the frame 5. Also, the outer groove 63 a A plate-like portion 63d disposed in the gap 51e of the end surface 51T of the frame body 5 when fitted to the step portion 51c of the frame body 5, and a plate-like portion 63e disposed below the lower flange portion 53b are formed. The Please Yes. And this protrusion 63 is formed so that the outer surface of both collar parts 53a and 53b of the frame 5 may fit in the inner surface of both plate-shaped parts 63d and 63e without gap when it is fitted to the step part 51c of the frame 5. Has been.
[0027]
Further, as shown in FIGS. 6 and 7, the arcuate peripheral surface 53 c of the flanges 53 a and 53 b of the frame 5 and the arcuate concave surface 63 c of the end cap 6 that receives this are a frame in which the main body 4 is not integrated. When the end cap 6 is attached to the body 5, the gap t is formed between them.
FIG. 6 shows a rear view of the state in which the end cap 6 is attached to the frame 5 in which the main body 4 is not integrated. FIG. 7 is a view in which the plate-like portion 63e is removed from the view of FIG. In this example, the peripheral surface 53c of the flanges 53a and 53b and the concave surface 63c receiving the same are formed in a concentric circular arc shape, and the radius R6 of the circular arc forming the concave surface 63c is made larger than the radius R5 of the circular arc forming the peripheral surface 53c.
[0028]
A through hole 65 corresponding to the female screw 45 of the main body 4 is formed in the end cap horizontal portion 62. On the inner surface of both end portions in the width direction of the end cap horizontal portion 62, a projection 66 for positioning with the frame 5 and a through hole 66a penetrating the center of the projection 66 are formed. By fitting the projection 66 into the recess 56 of the frame body 5, the through hole 56 a of the frame body 5 and the through hole 66 a of the end cap 6 communicate with each other.
[0029]
Further, a through hole 67 is formed in the center portion in the width direction of the end cap horizontal portion 62. The through hole 67 is a grease nipple mounting hole, the through hole 57 of the frame 5 is formed so as to communicate with this, and the side seal 7 is also formed with a through hole 71 communicating therewith. A convex portion 69 for positioning with the side seal 7 is formed on the outer surface of the end leg 61.
[0030]
The end cap 6 is manufactured by injection molding a synthetic resin such as POM.
Here, regarding the dimensional relationship between the main body 4 and the frame body 5, the longest outer dimension in the slider width direction between the lower end portions of the inner legs 41 of the main body 4 (the end portion on the side farther from the main body horizontal portion 42 than the concave portion 43) W1 (shown in FIG. 4) is formed larger than the shortest dimension W2 (shown in FIG. 5) in the slider width direction between the convex portions 54 of the frame 5.
[0031]
The assembly of the slider 2 is performed manually or by pressing. In the case of manual work, first, the inner leg (the leg part side of the main body) 41 of the main body 4 is inserted into the frame body 5 from the frame horizontal part 52 side. The thumb is applied to one of the lower surface of the first portion 51a of the outer leg 51 of the frame body 5, the index finger and the middle finger are applied to the other, and both the left and right hands simultaneously apply a force in a direction to bring the thumb, the index finger and the middle finger close together. Add.
[0032]
Thereby, the frame 5 is elastically deformed as shown in FIG. 8, and the convex portion 54 of the frame 5 is fitted into the concave portion 43 of the main body 4. Further, the inner leg 41 of the main body 4 and the first member 51a of the outer leg 51 of the frame body 5 are fitted, and the tapered surface 44 of the main body 4 and the tapered surface 51d of the frame body 5 are fitted. The outer surface of the main body horizontal portion 42 and the inner surface of the frame horizontal portion 52 of the frame 5 are fitted. In this way, the main body 4 and the frame body 5 are easily integrated, and positioning in the width direction, the linear motion direction, and the vertical direction (thickness direction) is precisely performed.
[0033]
Further, when removing the main body 4 from the frame body 5, one end of the integrated product in the linear motion direction is held with one hand and the other end is held with the other hand. A thumb is placed on the lower surface of the horizontal portion 42, an index finger and a middle finger are placed on the upper surface of the frame horizontal portion 52 of the frame 5, a force that pushes the main body horizontal portion 42 upward with the thumb, and a frame frame body with the index finger and middle finger A force for pressing the upper surface of the horizontal portion 52 downward is simultaneously applied. Thereby, the frame 5 is elastically deformed as shown in FIG. 8, and the fitting of each part of the main body 4 and the frame 5 is released.
[0034]
After the main body 4 and the frame body 5 are integrated as described above, the end caps 6 are disposed at both ends of the frame body 4 in the linear movement direction, and the projections 66 of the end cap 6 are fitted into the recesses 56 of the frame body 5. Thus, the protrusion 63 of the end cap 6 is fitted into the stepped portion 51 c of the frame body 5. Further, the plate-like material 64 of the end cap 6 is fitted into the lower surface of the frame horizontal portion 52 of the frame 5, and the through hole 55 of the frame horizontal portion 52 of the frame 5 and the through hole 65 of the end cap 6 communicate with each other. To do. Further, the through hole 56a of the frame 5 and the through hole 66a of the end cap 6 communicate with each other.
[0035]
Then, the screw 18 is passed through the through holes 55 and 65 from the outside of the end cap 6 and the tip thereof is screwed into the female screw 45 of the main body 4, whereby the end cap 6 and the frame 5 are fixed to the main body 4 by the screw 18. The slider 2 is assembled.
The linear guide device shown in FIG. 1 is assembled using the slider 2, the ball 3, the guide rail 1, the side seal 7, and the holding wire W thus assembled. In that case, first, the ball 3 is put in the return path 21b, the direction changing path 22a and the rolling groove 21a of the slider 2, and the ball 3 put in the rolling groove 21a is held by the holding wire W, and then the slider is moved. 2 is installed in the guide rail 1.
[0036]
Next, the side seal 7 is positioned on the slider 2 using the convex portion 69 of the end cap 6, and the side seal 7 is fixed to the slider 2 with the tapping screw 72 using the through holes 56 a and 66 a. Next, the grease nipple is inserted into the through hole (grease nipple mounting hole) 67 of the end cap 6 through the through hole 71 of the side seal 7.
[0037]
Here, in the linear guide device of this embodiment, the main body 4 and the frame body 5 are integrated by “an interference fit” between the inner leg 41 of the main body 4 and the outer leg 51 of the frame body 5 as described above. Therefore, the frame 5 in a state where the main body 4 is integrated is deformed so that the outer leg 51 opens outward in the width direction. When the peripheral surface 53c of the flange portions 53a and 53b and the concave surface 63c receiving the same are formed in a circular arc shape having the same radius and the same concentricity, the protrusion 63 of the end cap 6 is formed with respect to the step portion 51c of the frame body 5 by this deformation. It will not fit in the correct position.
[0038]
On the other hand, in the linear guide device of this embodiment, since the radius R6 of the arc that forms the concave surface 63c is larger than the radius R5 of the arc that forms the peripheral surface 53c, the protrusion 63 of the end cap 6 is formed on the frame 5. With respect to the step part 51c, it can be reliably inserted in an exact position.
In the linear guide device of this embodiment, the radius R6 of the arc forming the concave surface 63c is larger than the radius R5 of the arc forming the peripheral surface 53c, so that the protrusion 63 of the end cap 6 is connected to the step portion 51c of the frame 5. There is a gap t between the two in the state of being fitted in, but both sides of the frame 5 Part 5 The outer surface of 3a, 53b , D Since the direction change path is sealed in the thickness direction of the slider, it is covered with the plate-like parts 63d and 63e of the end cap 6, so that the lubricant in the circulation path leaks from the gap or foreign matter enters from the gap. Is prevented.
[0039]
Furthermore, the positioning of the end cap 6 with respect to the frame 5 is not the leg portion (the end leg 61 of the end cap 6 and the outer leg 51 of the frame body 5) in which the above deformation occurs, but the horizontal portion (end cap horizontal portion 62). Since the projection 66 and the recess 56) of the frame horizontal portion 52), the positioning is performed accurately.
In addition, the slider 2 includes the main body 4 having the rolling groove 21a, the frame 5 having the return passage 21b and the inner groove 53 of the direction changing path 22a, and the end cap 6 having the outer groove 63a of the direction changing path 22a. Compared with the slider described in Japanese Patent Laid-Open No. 7-317762, in which a molded body including a return passage portion (a portion corresponding to the frame body 5 in this embodiment) is integrally molded with a block body. The rolling groove shape can be easily corrected after molding.
[0040]
Further, since the frame body 5 is formed as a single body, the moldability is better than in the case of integral molding, and the structure of the mold can be simplified. In addition, since the production of the frame 5 proceeds independently of the production of the main body 4, it is possible to adopt a production system that pursues molding efficiency. Further, the main body 4 and the frame body 5 can be easily attached and detached manually as described above, and the frame body 5 can be easily and securely fixed to the main body 4 together with the end cap 6 by screwing. Thus, the slider 2 of this embodiment is advantageous in terms of productivity as compared with the slider described in JP-A-7-317762.
[0041]
In the above-described embodiment, the peripheral surface 53c of the flange 53a and the concave surface 63c receiving the same are concentrically different from each other ("the radius R5 of the arc forming the peripheral surface 53c"<"the radius R6 of the arc forming the concave surface 63c). Although the gap t is provided between the peripheral surface 53c and the concave surface 63c by using the circular arc shape, the way of providing the gap between the peripheral surface 53c and the concave surface 63c is not limited to this.
[0042]
For example, as shown in FIG. 9, the arc O of the peripheral surface 53c of the flanges 53a and 53b and the arc of the concave surface 63c that receives this are set to the center O while setting “radius R5 <radius R6”. _Five , O ₆ By shifting, a part of the peripheral surface 53c and the concave surface 63c may be in contact with each other. In the example of FIG. 9, the outer side in the slider width direction is the contact portion S, and a gap t is generated on the inner side in the slider width direction. In this case, since the contact portion S has a positioning action, positioning when the end cap 6 is attached to the frame body 5 can be easily performed, and the position of the end cap 6 when vibration occurs due to the presence of the contact portion S. There is also an effect that it is difficult to cause the deviation.
[0043]
Alternatively, as shown in FIGS. 10 and 11, the center positions of the arcs of the peripheral surfaces 53c of the flanges 53a and 53b and the arcs of the concave surfaces 63c that receive them are changed, and either one is not a single arc but the same radius. Two arcs whose center positions are changed may be connected so that the peripheral surface 53c and a part of the concave surface 63c are in contact with each other.
In the example of FIG. 10, the arcs of the peripheral surfaces 53c of the flange portions 53a and 53b are centered on the center of the flange portions 53a and 53b in the slider width direction with the radius R5. _Five The concave surface 63c is formed by connecting two circular arcs having the same radius R5 and changing the center position. The outer side portion of the concave surface 63c in the slider width direction is the center O of the arc of the peripheral surface 53c. _Five O outside the slider width direction by L ₆₁ And the concave portion 63c on the inner side in the slider width direction is the center O of the arc of the peripheral surface 53c. _Five O on the inner side in the slider width direction by L ₆₂ It consists of an arc E2 centered at. A connection point between the arcs E1 and E2 is a contact portion S.
[0044]
In the example of FIG. 11, the arc of the concave surface 63c is centered on the center of the flanges 53a and 53b in the slider width direction with the radius R6. ₆ The peripheral surface 53c is shaped to connect two circular arcs having the same radius R6 and changing the center position. The outer side portion of the circumferential surface 53c in the slider width direction is the center O of the arc of the concave surface 63c. ₆ O on the inner side in the slider width direction by L ₅₂ And the inner part of the circumferential surface 53c in the slider width direction is the center O of the arc of the concave surface 63c. ₆ O outside the slider width direction by L ₅₁ It consists of an arc E2 centered at. A connection point between the arcs E1 and E2 is a contact portion S.
[0045]
Among these methods, when a part of the peripheral surface 53c and the concave surface 63c are brought into contact with each other by the method of FIG. 10, the semicircular peripheral surface 53c can move in the slider width direction in the concave surface 63c. The end cap 6 is deformed when the end cap 6 is attached to the frame 5 in the state due to deformation (deformation in which the outer leg 51 opens outward in the width direction) generated in the frame 5 in a state where the main body 4 is integrated. do not do. Thereby, the protrusion 63 of the end cap 6 can be more reliably fitted into the stepped portion 51c of the frame body 5 at an accurate position.
[0046]
In the above embodiment, the slider is assembled by fixing the frame 5 and the end cap 6 to the main body 4 with screws. However, the slider composed of the main body, the frame and the end cap uses screws. It can also be assembled without. For example, the frame 5, the end cap 6, and the main body 4 may be fixed by a method using welding of synthetic resins.
[0047]
In the embodiment, the tapered surface 44 is provided between the main body horizontal portion 42 and the concave portion 43 of the main body 4, and the tapered surface 51 d fitted to the tapered surface 44 is provided on the frame body 5. As a result, the adhesion when the main body 4 and the frame 5 are integrated is improved, and when used as a linear guide device, the vibration due to the circulation of the ball 3 is absorbed and the noise characteristics are improved. An effect is obtained.
[0048]
However, the tapered surface 44 is not an essential requirement of the present invention, and the boundary between the main body horizontal portion 42 and the inner leg 41 (above the recess 43) may be formed at a right angle.
In this embodiment, a linear guide device (linear motion device) having two circulation paths (one pair in two rows) is described. However, the linear motion device of the present invention is characterized by the number of circulation paths. Of course, a linear guide device having four (two to four rows) or more is naturally included in the linear motion device of the present invention.
[0049]
【The invention's effect】
As described above, according to the present invention, in a linear motion device having a slider in which two or more members formed by separate members are integrated in an assembly process, without deteriorating operability and noise characteristics, Weight reduction and cost reduction are achieved.
[Brief description of the drawings]
FIG. 1 is a perspective view showing a linear guide device (linear motion device) corresponding to an embodiment of the present invention.
FIG. 2 is a view showing an embodiment of a slider constituting the linear guide device of FIG. 1, and is a perspective view showing an exploded state of the slider.
3 is a partial cross-sectional front view showing a state in which the main body of the slider is integrated with the frame, and the left side portion corresponds to a cross-sectional view taken along the line AA in FIG.
4 is a front view showing a main body constituting the slider of FIG. 2;
5 is a view showing a frame constituting the slider of FIG. 2, and corresponds to a cross-sectional view taken along line AA of FIG.
FIG. 6 is a rear view of the slider showing a state in which an end cap is attached to a frame body in which the main body is not integrated.
7 is a view in which the plate-like portion of the end cap is removed from the view of FIG. 6. FIG.
8 is a cross-sectional view showing an elastically deformed state of the frame body of FIG.
FIG. 9 is a diagram showing another example of how to provide a gap between the peripheral surface of the flange portion of the frame body and the concave surface of the end cap that receives it.
FIG. 10 is a diagram showing another example of how to provide a gap between the peripheral surface of the flange portion of the frame body and the concave surface of the end cap that receives the flange surface.
FIG. 11 is a diagram showing another example of how to provide a gap between the peripheral surface of the flange portion of the frame body and the concave surface of the end cap that receives the flange surface.
FIG. 12 is a perspective view showing a conventional example of a linear guide device.
[Explanation of symbols]
1 Guide rail
11 Rolling groove
12 ball rolling path
18 Screw (Male thread)
2 Slider
2A Slider leg
2B Horizontal part of slider
21a Rolling groove
21b Ball return path
22a Direction change path
25 Circulation route
3 balls (rolling elements)
4 Body
41 Inner leg (inner width part of leg)
42 Horizontal body
43 Concave part parallel to rolling groove
44 Tapered surface
45 Female thread
46 recess
47 Outside parts on both sides of the recess
47a Female thread hole
5 Frame
51 Outer leg (outer part of the leg in the width direction)
51a First part of outer leg
51b Second part of outer leg
51c Step
51d Tapered surface
51e clearance
51T Linear motion end face of the first part
51t Underside of frame horizontal part (surface on outer leg side)
52 Horizontal part of frame
53 Inner groove of direction change path
53a Upper (horizontal side) collar
53b Lower buttocks
53c circumference
54 Convex section parallel to return passage
55 Through-hole corresponding to female screw of main body
56 Recess for positioning with end cap
56a Through hole
57 Through hole
6 End cap
61 End leg (end part of linear movement direction of leg)
62 Horizontal end cap
63 Protrusion
63a Outer groove of direction change path
63b tongue
63c concave
63d Upper (horizontal part) plate-like part
63e Lower plate-shaped part
65 Through-hole corresponding to the female thread of the body
66 Protrusions for positioning with the frame
66a Through hole
67 Through hole (Grease nipple mounting hole)
69 Projection for positioning with side seal
7 Side seal
71 Through hole
72 Tapping screw
W Holding wire
W1 Longest outer dimension in the slider width direction between the lower ends of the inner legs
The shortest dimension in the slider width direction between the convex parts of the W2 frame

Claims (4)

Consists of a guide rail, a slider, and a plurality of rolling elements,
Rolling grooves for rolling elements are formed on both side surfaces of the guide rail in the width direction,
The slider is composed of leg portions arranged on both sides in the width direction of the guide rail, and a horizontal portion arranged on one end side in the thickness direction of the guide rail and connecting both leg portions,
A rolling groove disposed opposite to the rolling groove of the guide rail is provided on the inner side surfaces of the both leg portions, and a rolling passage of the rolling element is formed by the rolling groove and the rolling groove of the guide rail, Both legs are formed with return passages for rolling elements, and both legs are also formed with direction changing paths for communicating the return passages with the rolling passages.
In a linear motion device in which one of a guide rail and a slider linearly moves relative to the other by rolling a rolling element in a circulation path constituted by the rolling path, a return path, and a direction changing path. ,
The slider is placed on the metal main body, a synthetic resin frame that is detachably fitted to the outside of the main body, and both ends of the frame in the linear motion direction, and is fixed to the main body via the frame. An end cap made of synthetic resin,
The frame body is composed of an outer leg that forms an outer portion in the width direction of the leg portion and a horizontal portion of the frame body that forms an end portion in the linear motion direction of the horizontal portion. Having a convex portion on the inside of both outer legs,
The main body includes an inner leg that forms an inner portion in the width direction of the leg portion and a main body horizontal portion that forms a main portion of the horizontal portion, and has a rolling groove inside both inner legs, and corresponds to the convex portion. The main body and the frame body are integrated by an interference fit between the inner leg of the main body and the outer leg of the frame body by having a concave portion on the outer side of both inner legs and fitting the convex portion into the concave portion.
The end cap includes an end leg that forms an end portion of the leg portion in the linear movement direction, and an end cap horizontal portion that forms an end portion of the horizontal portion in the linear movement direction. With side grooves,
The longest outer dimension in the slider width direction between the lower ends of the inner legs of the main body in the slider width direction is larger than the shortest dimension in the slider width direction between the convex parts of the frame, , By elastically deforming the frame body, by taking in and out the leg side of the main body from the frame horizontal part side,
The frame has the frame horizontal portion substantially semicircular plate-shaped flange portion on the opposite side of said groove, said end cap, receiving the peripheral surface of each flange portion to the outer groove Each concave surface,
The linear motion is characterized in that the peripheral surface and the concave surface are formed in a shape in which a gap is formed between the peripheral surface and the concave surface when an end cap is attached to the frame body in which a main body is not integrated. apparatus.   The linear motion device according to claim 1, wherein the peripheral surface and the concave surface are formed such that at least a part of both is in contact. Said end cap comprises a plate-like portion covering the outer surface of the flange portion of the frame body, this plate-like portion, a clearance between the concave surface of the peripheral surface and the end cap of the frame body is covered, the direction changing passage is The linear motion device according to claim 1, wherein the slider is sealed in a thickness direction of the slider.   The linear motion device according to claim 1, wherein the end cap is positioned relative to the frame by a horizontal end cap portion and a horizontal frame portion.

Images