JP2004108537A - Method of manufacturing linear guide device, and linear guide device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To integrally weld a frame body in which a main body is fitted, an end cap and a top cover without processing a contact face of the main body with the top cover with high accuracy, in assembling a slider of a linear guide device. <P>SOLUTION: The relationship of dimensions of a projection (welding margin) 82 of the top cover 8 and a recessed part 65a of the end cap in which the projection is fitted, are determined in such manner that a dimension in the projecting direction of the projection 82 is larger than a dimension in the depth direction of the recessed part 65a, and the projection 82 is freely fitted to the recessed part 65a. Whereby the frame body 50 to which the main body 40 is internally fitted, the end cap 60 and the top cover 8 can be integrated by welding without grinding a face (contact face with outer member, of main body) of the recessed part 46A of a main body horizontal part 42. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a linear guide device including a guide rail, a slider, and a plurality of rolling elements.
[0002]
[Prior art]
FIG. 12 shows a conventional example of a linear guide device. As shown in this figure, the linear guide device includes a guide rail 1, a slider (also referred to as a "bearing") 2, and a plurality of balls (rolling elements) 3.
The guide rail 1 has rolling grooves 11 extending on both sides in parallel with the longitudinal direction. The slider 2 includes leg portions 2A arranged on both sides of the guide rail 1 in the width direction, and a horizontal portion 2B connecting the leg portions 2A. The horizontal portion 2B is disposed on one end side (in the figure, on the upper surface side of the guide rail 1) in the thickness direction (the direction perpendicular to both the length direction and the width direction) of the guide rail 1. Then, both inner side surfaces of the slider 2 are opposed 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 motion direction, and the end caps 22 are arranged at both ends of the main body 21 in the linear motion direction. Rolling grooves 21a facing the rolling grooves 11 of the guide rail 1 are formed on both inner side surfaces of the main body 21. The rolling passages 12 for the balls 3 are formed by these rolling grooves 11 and 21a.
A linear return passage 21b is formed outside the rolling groove 21a of the main body 21 of the slider 2. A semicircular turning path 22a is formed in a portion of the end cap 22 that is disposed on both side surfaces of the guide rail 1 (an outer portion of the leg 2A). The rolling path 12 and the return path 21b communicate with each other through the direction change path 22a, and a circulation path 25 that circulates the ball 3 infinitely is formed on each of these paths.
[0004]
The linear guide device has four circulation paths (two to four rows), and the balls 2 roll along the circulation paths 25 so that the slider 2 slides along the guide rails 1.
In the conventional linear guide device, the return passage 21b is formed by making a hole in the metal main body 21, but this operation requires labor and cost. In order to solve this problem, Patent Literature 1 discloses that a widthwise outer portion of a leg portion (a portion where a return passage is formed) is integrally formed as a molded body made of a synthetic resin into a metal block body. Describes that a slider having a return passage made of a synthetic resin is obtained. Further, in this slider, an inner groove of the direction change path is provided in the molded body so as to be continuous with the return passage, and an end cap is fixed to end face forming members forming both ends in the linear movement direction of the molded body by bolts.
[0005]
On the other hand, Patent Literature 2 describes that the end cap is fixed to the end face forming member by a welding method without using a bolt, thereby ensuring smooth circulation of the rolling elements. In the example described in this publication, as shown in FIG. 13, a lubrication groove 52b extending from the grease nipple mounting hole 67 toward the outer groove 63a of the direction change path is formed on a surface of the end cap 60 where the end face forming member is mounted, by welding. A projection 168 forming a margin is formed. The projections 168 forming a welding margin are provided continuously so as to surround the lubrication groove 52b and the outer groove 63a.
[0006]
[Patent Document 1]
JP-A-7-317762 [Patent Document 2]
JP 10-115316 A
[Problems to be solved by the invention]
However, the slider is composed of a metal main body and a plurality of outer members made of synthetic resin disposed outside the main body, and a projection forming a welding allowance on one of the bonding surfaces forming a pair of the outer member is formed on the other side. In a linear guide device in which a concave portion for receiving the projection is formed, and the plurality of outer members are assembled by sandwiching the main body by welding, the contact surface of the main body with the outer member is processed with high precision. May be required.
[0008]
For example, in the structure shown in FIG. 6 of Japanese Patent Application No. 2002-195816 filed by the present applicant, a projection of the top cover and an end cap are integrated in order to integrate the frame, the end cap, and the top cover into which the main body is fitted. It is necessary to accurately perform positioning with the concave portion. In order to accurately perform this positioning, it is necessary to grind a concave portion on the upper surface of the main body that accommodates the cover portion of the top cover.
[0009]
The present invention has been made to solve such a problem of the related art, and includes a metal main body, and a plurality of synthetic resin outer members disposed outside the main body. When assembling a slider in which a projection forming a welding allowance is formed on one of the joining surfaces forming a pair and a concave portion for receiving the projection is formed on the other by integrally welding the plurality of outer members with the main body therebetween. It is another object of the present invention to integrate the main body without processing the contact surface with the outer member with high precision.
[0010]
[Means for Solving the Problems]
In order to solve the above-mentioned problem, 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, and the slider is provided with a guide. The guide rails are provided on both sides in the width direction of the rail, and a horizontal portion is provided on one end side in the thickness direction of the guide rail and connects the two legs. A rolling groove for the rolling element is formed by the rolling groove and the rolling groove of the guide rail, and a return path for the rolling element is formed in the two leg portions; In addition, a direction change path that connects the return path and the rolling path is formed in the portion, and a rolling element rolls in a circulation path configured by the rolling path, the return path, and the direction change path. As a result, one of the guide rail and the slider is relatively In the method for manufacturing a moving linear guide device, the slider comprises: a metal main body having the rolling grooves; and a plurality of synthetic resin outer members disposed outside the main body. A projection forming a welding margin is formed on one of the joining surfaces forming a pair, and a concave portion for receiving the projection is formed on the other side. Is larger than the dimension of the recess in the depth direction, and the projection is formed so as to be loosely fitted into the recess, and the plurality of outer members are integrated by welding with the main body interposed therebetween. A manufacturing method and a linear guide device manufactured by the method are provided.
[0011]
The present invention also includes a guide rail, a slider, and a plurality of rolling elements, and rolling grooves of the rolling elements are formed on both sides in the width direction of the guide rail, and the slider is provided on both sides in the width direction of the guide rail. A rolling part, which is disposed on one end side in the thickness direction of the guide rail and connects the two leg parts, is disposed on the inner surface of each of the leg parts so as to face the rolling groove of the guide rail. A rolling groove is provided, and a rolling path 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 in the two leg portions. A direction change path for communicating the return path with the rolling path is formed, and a rolling element rolls in a circulation path formed by the rolling path, the return path, and the direction change path, thereby providing a guide rail and a slider. Linear guides, one of which moves directly relative to the other In the method for manufacturing location, to provide a linear guide device manufactured by the manufacturing method and the method of the linear guide device comprising a ▲ 1 ▼ ~ ▲ 9 ▼ below.
{Circle around (1)} The slider is provided with a metal main body, a frame body detachably fitted to the outside of the main body, and disposed at both ends of the frame body in the linear motion direction, and fixed to the main body via the frame body. And a plate-shaped member disposed on the upper surface of the main body and having an end engaged with the frame and the end cap.
{Circle around (2)} The frame is composed of an outer leg forming the widthwise outer portion of the leg portion and a frame horizontal portion forming an end portion of the horizontal portion in the direct-moving direction. It has an inner groove and has convex portions 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. The main body has rolling grooves inside both inner legs. The main body and the frame body are integrated by fitting the protrusions into the recesses, and the main body and the frame body are integrated with each other. It has a concave portion for disposing the plate-shaped member.
(4) The end cap is composed of an end leg that forms an end portion of the leg portion in the direction of linear motion and an end cap horizontal portion that forms the end portion of the horizontal portion in the direction of linear motion. It has a groove outside the road.
{Circle around (5)} The frame, plate-like member and end cap are made of synthetic resin.
{Circle around (6)} A projection forming a welding allowance is formed at one end of the plate member in the direct-moving direction and one of the end cap horizontal portion and the frame horizontal portion, and a concave portion for receiving the projection is formed at the other. Have been.
{Circle around (7)} One of the end cap-side surface of the end cap and the end cap-side surface of the frame is provided with a projection forming a welding allowance, and the other is formed with a recess for receiving the projection.
(8) The pair of projections (projections forming the welding allowance) and the recesses into which the projections are formed are formed so that the size of the projection in the projection direction is larger than the size of the recess in the depth direction, and the projection is loosely fitted in the recess. Have been.
{Circle around (9)} The frame, the plate member, and the end cap, into which the main body is fitted, are integrated by welding.
[0012]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described.
FIG. 1 is a perspective view showing a linear guide device according to an embodiment of the present invention. The linear guide device includes a guide rail 1, a slider 2, and a plurality of balls (rolling elements) 3.
[0013]
The guide rail 1 has rolling grooves 11 extending on both sides in parallel with the longitudinal direction. The slider 2 includes leg portions 2A arranged on both sides of the guide rail 1 in the width direction, and a horizontal portion 2B connecting the leg portions 2A. The horizontal portion 2B is arranged 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 opposed to both side surfaces of the guide rail 1.
[0014]
Rolling grooves 21a facing the rolling grooves 11 of the guide rail 1 are formed on the inner side surfaces of both legs 2A of the slider 2. The rolling passages 12 for the balls 3 are formed by these rolling grooves 11 and 21a.
A return path 21b for the ball is formed in a straight line on the outer portion of the two leg portions 2A, and a direction change path 22a that connects the return path 21b and the rolling path 12 is formed. The return path 21b, the rolling path 12, and the direction change path 22a constitute a circulation path 25 for circulating the ball 3 infinitely. This linear guide device has two circulation paths (one pair of two rows), and the slider 2 slides along the guide rail 1 as the ball 3 rolls on each circulation path.
[0015]
FIG. 2 is a perspective view showing the disassembled state of the slider 2. The slider 2 of this embodiment includes a metal main body 40, a synthetic resin frame (outer member) 50, a synthetic resin end cap (outer member) 60, and a synthetic resin top cover (outer member). , A plate-like member) 8. Further, as shown in FIG. 1, a side seal 7 is attached outside the end cap 60. In FIG. 1, the top cover 8 is omitted.
[0016]
FIG. 3 is a front view of the main body 40 of the slider 2, and FIG. 4 is a cross-sectional view of the frame body 50 taken along line AA of FIG. FIG. 5 is a partially broken side view of the slider 2 in an assembled state.
As shown in FIG. 2, the main body 40 includes an inner leg 41 forming an inner portion in the width direction of the two leg portions 2A, and a main body horizontal portion 42 forming 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 concave portion 43 parallel to the rolling groove 21 a is provided outside the inner leg 41. On both end surfaces in the width direction of the main body 40, between the concave portion 43 and the main body horizontal portion 42, a tapered surface 44 having a small dimension on the concave portion 43 side is formed.
[0017]
A concave portion 46A is formed in the center portion of the upper surface of the main body horizontal portion 42 in the slider width direction. Two female screw holes 47a for attaching other members such as a table are formed in outer portions 47 on both sides of the concave portion 46A. They are formed at predetermined intervals in the movement direction. An edge portion 48 and an inclined portion 49 are formed between the concave portion 46A and the outer portions 47 in this order from the concave portion 46A toward the outer portion. The surface of the edge portion 48 is slightly higher than the concave portion 46A, and the distance between the two edge portions 48 is slightly larger than the width of the top cover 8. That is, the upper surface of the horizontal portion 2B of the main body 40 is formed such that the top cover 8 is loosely fitted in the concave portion 46A.
[0018]
The main body 4 is manufactured by cutting a material made of a metal such as SUS440C after drawing.
The top cover 8 includes a rectangular plate-shaped cover portion 81 and two to four protrusions (welding allowance) 82 provided at both ends in the length direction (linear movement direction) of the cover portion 81. The protrusion 82 has a columnar shape and is formed to extend vertically from the plate surface of the cover portion 81. As will be described later, since both ends of the top cover 8 in the translation direction engage with the end caps 60, the length (dimension in the translation direction) of the cover portion 81 is slightly longer than the length of the frame 50 in the translation direction. .
[0019]
The top cover 8 is provided to reliably prevent the main body 40 from falling off in the vertical direction with respect to the frame body 50. The top cover 8 is manufactured by injection molding a synthetic resin such as POM.
The frame body 50 includes outer legs 51 forming outer portions in the width direction of the two leg portions 2A, and a frame horizontal portion 52 forming an end portion in the direct movement direction of the horizontal portion 2B of the entire slider.
[0020]
The outer leg 51 includes a first portion 51a and a second portion 51b. The first portion 51a is arranged so as to connect the two frame horizontal portions 52, and a return passage 21b is formed therein. The second portion 51b is a semicircular arc-shaped protrusion extending from the first portion 51a in the outer surface direction of both frame body horizontal portions 52. The protrusion has an inner groove 53 of a direction change path 22a continuous with the return passage 21b. ing.
[0021]
In addition, a step 51c exists between the first portion 51a and the second portion 51b. The upper surface of the first portion 51 a (the surface on the side of the frame horizontal portion 52) is formed as a tapered surface 51 d that fits with the tapered surface 44 of the main body 4. On the inner side of the first portion 51a of the outer leg 51, a convex portion 54 parallel to the return passage 21b is formed.
The frame horizontal portion 52 is formed with a concave portion 52a that is continuous with the concave portion 46A of the main body 40. A circular concave portion 57a is formed at the center in the width direction of the horizontal frame portion 52. The concave portion 57a communicates with a through hole (grease nipple mounting hole) 67 provided in the end cap 60 described later. A projection 59 extending in the linear motion direction is formed on the outer surface (the surface on the end cap 60 side) of the horizontal frame portion 25 at a position outside the concave portion 57a in the width direction.
[0022]
The frame 5 is manufactured by injection molding a synthetic resin such as POM.
The end cap 60 is a member disposed at both ends in the direct movement direction of the frame body 50, and includes an end leg 61 forming an end portion in the direct movement direction of the two leg portions 2 </ b> A, and an end portion in the direct movement direction of the horizontal portion 2 </ b> B of the entire slider. And an end cap horizontal portion 62 forming a part. A projection 63 having a semicircular recess is formed on the frame side of the end leg 61, and an outer groove 63 a of the direction change path 22 a is formed on the projection 63. The inner end in the width direction of the outer groove 63a is a tongue 63b that scoops up the ball 3 from the rolling groove 12. A plate-like member 64 extending from the lower surface of the end cap horizontal portion 62 is formed between the projections 63 with the same projection length as the projections 63.
[0023]
A through hole 67 is formed at the center in the width direction of the end cap horizontal portion 62. The through hole 67 is a grease nipple mounting hole, and the concave portion 57a of the frame body 50 is formed so as to communicate therewith. As shown in FIG. 1, the side seal 7 also has a through hole 71 communicating therewith. ing. At both ends in the width direction of the end cap horizontal portion 62, a through hole 66b through which a tapping screw 72 (see FIG. 1) for fixing the side seal 7 is formed.
[0024]
At a position between the two through holes 67 and 66b of the end cap horizontal portion 62, a through hole 68 through which the projection 59 of the frame 50 passes is formed. The through hole 68 includes a small-diameter portion 68a having a diameter slightly larger than the diameter of the cylinder forming the protrusion 59, and a large-diameter portion 68b having a diameter larger than the small-diameter portion 68a. When the protrusion 59 enters the small diameter portion 68 a of the through hole 68, the frame body 50 is positioned with respect to the end cap 60. The length of the projection 59 is formed such that the tip of the projection 59 is slightly outside the end cap 60 in this state.
[0025]
A recess 65 is formed in the end cap horizontal portion 62 on the side of the frame 50, which is continuous with the concave portion 52 a of the frame horizontal portion 52. The depression 65 is formed with a column-shaped concave portion 65 a into which the projection 82 of the top cover 8 is loosely fitted. Therefore, at the time of assembling, the longitudinal end of the cover portion 81 of the top cover 8 is disposed in the recess 65 of the end cap 60, and the projection 82 of the top cover 8 is loosely fitted in the concave portion 65a. Further, a projection 69 for positioning with the side seal 7 is formed on the outer surface of the end leg 61 of the end cap 60.
[0026]
The end cap 60 is manufactured by injection molding a synthetic resin such as POM.
Here, the slider 2 has the longest outer dimension W1 (see FIG. 3) in the slider width direction between the lower ends of the inner legs 41 of the main body 40 (the end on the side away from the concave portion 43 and away from the main body horizontal portion 42). It is formed larger than the shortest dimension W2 (see FIG. 4) in the slider width direction between the protrusions 54 of the frame body 50.
[0027]
The dimensional relationship between the projection (welding margin) 82 of the top cover 8 and the concave portion 65a of the end cap 60 in which the projection 82 is to be inserted will be described with reference to FIG.
As shown in FIG. 6A, the protrusion 82 of the top cover 8 is a columnar protrusion having a bottom surface in a circle having a diameter R1 and a height L1. As shown in FIG. 6B, the concave portion 65a of the end cap 60 is a columnar concave portion having a bottom surface of a circle having a diameter R2 and a height of L2, where R2> R1 and L1> L2. That is, the protrusion 82 is formed such that the size in the protruding direction is larger than the size in the depth direction of the recess 65a, and the protrusion 82 is loosely fitted in the recess 65a.
[0028]
As described above, the dimensional relationship between the projection (the tip corresponds to the welding allowance) 59 of the frame body 50 and the through hole (corresponding to the recess into which the projection 59 is inserted) 68 of the end cap 60 is also determined as described above. Since the length of the protrusion 59 is outside the cap 60, the size of the protrusion 59 (the tip is a welding allowance) in the protruding direction is larger than the size of the concave portion (through hole 68) in the depth direction. The projection 59 is formed so as to be loosely fitted in the small diameter portion 68 a of the through hole 68.
[0029]
FIG. 7 is a sectional view of the frame 50 of the slider 2 in an elastically deformed state, and FIG. 8 is a partially broken side view of the state immediately before the top cover 8 is attached. The method of assembling the slider 2 will be described with reference to these drawings.
When assembling the slider 2, first, the main body 40 and the frame body 50 are integrated, but this step is performed manually or by press working. In the case of manual work, first, the inner leg (the leg side of the main body) 41 of the main body 40 is inserted into the frame 50 from the side of the horizontal frame portion 52, and, for example, the outer portion 47 of the upper surface of the main body horizontal portion 42 The thumb is applied to one of the lower surfaces of the first portions 51a of the outer legs 51 of the frame body 50, the index finger and the middle finger are applied to the other, and the force in the direction of bringing the thumb, the index finger and the middle finger closer to each other with both hands simultaneously. Add.
[0030]
As a result, the frame 50 is elastically deformed as shown in FIG. 7, and the projection 54 of the frame 50 is fitted into the recess 43 of the main body 40. The inner leg 41 of the main body 40 and the first member 51a of the outer leg 51 of the frame 50 are fitted, and the tapered surface 44 of the main body 40 and the tapered surface 51d of the frame 5 are fitted. The outer surface of the main body horizontal portion 42 of the frame 40 and the inner surface of the frame horizontal portion 52 of the frame 50 are fitted.
[0031]
In this way, the main body 40 and the frame body 50 are easily integrated, and the positioning in the width direction, the linear motion direction, and the vertical direction (thickness direction) is performed precisely.
When the main body 40 is detached from the frame 50, one end of the integrated body in the direct movement direction is held by one hand, and the other end is held by the other hand. The thumb is applied to the lower surface of the frame body 42, the index finger and the middle finger are applied to the upper surface of the frame horizontal portion 52 of the frame 50, the force pushing the main body horizontal portion 42 upward with the thumb, and the frame frame horizontal portion A force for pushing the upper surface of 52 downward is applied simultaneously. As a result, the frame body 50 is elastically deformed as shown in FIG. 7, and the fitting between the main body 40 and the frame body 50 is released.
[0032]
Next, the end caps 60 are arranged at both ends in the translation direction of the frame 50, and the projections 59 of the frame 50 are inserted into the through holes 68 of the end cap 60. As a result, the plate-shaped member 64 of the end cap 60 fits on the lower surface of the frame horizontal portion 52 of the frame 50, and the recess 52a of the frame 50 and the recess 65 of the end cap 60 become a continuous recess. Further, the concave portion 57 a of the frame 50 communicates with the through hole 67 of the end cap 60. In this state, the tips of the projections 59 of the frame 50 slightly protrude from both ends of the end cap 60 in the direction of linear movement. FIG. 8 shows this state.
[0033]
Next, by using an ultrasonic plastic welding machine, the tip of the projection 59 of the frame body 50 is heated and melted by ultrasonic waves and pressurized while melting, so that a projection is formed in the gap between the projection 59 and the large diameter portion 68b of the through hole 68. The synthetic resin forming the tip of 59 is plastically flowed. As a result, the projections 59 do not protrude from both end surfaces in the linear movement direction of the end cap 60, and the end cap 60 is fixed to the frame body 50.
[0034]
Next, the one in which the main body 40, the frame body 50, and the end cap 60 are integrated is placed on the base of the ultrasonic plastic welding machine, and the cover portion 81 of the top cover 8 is placed on the concave portion 46A of the main body 40. The projection 82 of the top cover 8 is inserted into the recess 65 a of the end cap 60, and ultrasonic welding is performed while pressing and pressing the horn of the welding machine against the upper surface of the top cover 8. As a result, both ends of the top cover 8 in the translation direction are fixed to the end cap 60 and the frame body 50. By fixing the top cover 8, the main body 40 is vertically fixed to the frame body 50.
[0035]
As a result, the frame body 50 in which the main body 40 is fitted, the end cap 60, and the top cover 8 are integrated by welding, and 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 into the return passage 21b, the direction change 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. 2 incorporates the guide rail 1.
[0036]
Next, the side seal 7 is positioned on the slider 2 by using the projection 69 of the end cap 60, and the side seal 7 is fixed to the slider 2 by the tapping screw 72 using the through hole 66 b of the end cap 60. Next, the grease nipple is inserted into the grease nipple mounting hole 67 of the end cap 60 through the through hole 71 of the side seal 7.
[0037]
As described above, according to the linear guide device of this embodiment, the dimensional relationship between the projection (welding allowance) 82 of the top cover 8 and the recess 65a of the end cap 60 into which the projection 82 is inserted is determined by the dimension of the projection 82 in the projecting direction. Is larger than the depth dimension of the concave portion 65a, and the projection 82 is formed so as to be loosely fitted in the concave portion 65a. Therefore, the surface of the concave portion 46A of the main body horizontal portion 42 (the contact surface with the outer member of the main body). , The frame body 50 in which the main body 40 is fitted, the end cap 60, and the top cover 8 can be integrated by welding.
[0038]
Therefore, according to the linear guide device of this embodiment, since the surface of the concave portion 46A of the main body horizontal portion 42 is not ground, the manufacturing cost of the slider can be reduced as compared with the case where this grinding is performed.
Further, according to the linear guide device of this embodiment, the slider 2 is provided with the main body 40 having the rolling groove 21a, the frame body 50 having the return passage 21b and the inner groove 53 of the direction changing path 22a, and the direction changing path 22a. Is divided into an end cap 60 having an outer groove 63a and a top cover 8 for surely preventing the main body 40 from being pulled out of the frame body 50 in the vertical direction. The shape of the rolling grooves can be easily corrected after the molding, as compared with a slider (a slider described in Japanese Patent Application Laid-Open No. 7-317762) in which the frame 50 is integrally molded with the main body. it can.
[0039]
Further, since the frame body 50 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 50 proceeds independently of the production of the main body 40, a production system that pursues molding efficiency can be obtained. Further, the main body 40 and the frame body 50 can be easily attached and detached by manual operation as described above.
[0040]
In addition, according to the linear guide device of this embodiment, since the slider 2 is assembled by ultrasonic welding, it is not necessary to form female threads in metal. That is, the slider of this embodiment is more advantageous in terms of productivity than the case where the end cap is fixed to the main body by screwing.
In the above-described embodiment, the projections 82 forming the welding allowance are provided on the top cover 8 and the recesses 65a for receiving the projections are provided on the end cap 60. However, as shown in FIG. The projection 82 may be provided, and the concave portion 55 a for receiving the projection 82 may be provided in the frame body 50. Further, as shown in FIG. 10, a projection 605 serving as a welding margin may be provided on the end cap 60, and a concave portion 806 for receiving the projection 605 may be provided on the top cover 8. Further, as shown in FIG. 11, a projection 505 serving as a welding allowance may be provided on the frame body 50, and a concave portion 805 for receiving the projection 505 may be provided on the top cover 8.
[0041]
In the above embodiment, the cross-sectional shape (the bottom surface of the columnar body) of the protrusion 82 and the concave portion 65a is circular. However, the shape is not limited to this, and may be any shape such as a rectangle, a triangle, a semicircle, and a trapezoid. Good.
In this embodiment, a linear guide device having two circulation paths (one pair and two rows) is described. However, the linear guide device of the present invention is not characterized by the number of circulation paths, A linear guide device having two to four rows or more is naturally included in the linear guide device of the present invention.
[0042]
【The invention's effect】
As described above, according to the manufacturing method of the linear guide device of the present invention, the linear guide device includes a metal main body, and a plurality of synthetic resin outer members disposed outside the main body. When assembling a slider having a projection that forms a welding margin on one of the joining surfaces to be formed and a concave portion for receiving the projection on the other by assembling the plurality of outer members by welding with the main body therebetween. It is not necessary to process the contact surface with the outer member with high precision. Thereby, the manufacturing cost of the linear guide device including the slider having the above structure can be reduced.
[0043]
According to the linear guide device of the fourth aspect, there is provided a linear guide device having a slider in which the return path of the rolling element is formed of a non-divided body, and the productivity of the slider is disclosed in Japanese Patent Application Laid-Open No. 7-317762. A linear guide device higher than the described slider is obtained.
[Brief description of the drawings]
FIG. 1 is a perspective view showing a linear guide device according to an embodiment of the present invention.
FIG. 2 is a perspective view showing an embodiment of a slider constituting the linear guide device of FIG. 1 and showing an exploded state of the slider.
FIG. 3 is a front view showing a main body constituting the slider of FIG. 2;
4 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. 2;
FIG. 5 is a partially cutaway side view showing an assembled state of the slider of FIG. 2;
FIG. 6 is a diagram illustrating a dimensional relationship between a projection (welding allowance) of a top cover and a concave portion of an end cap into which the projection is to be inserted.
FIG. 7 is a sectional view showing an elastic deformation state of the frame body of FIG. 4;
8 is a partially broken side view showing a state immediately before the top cover of the slider of FIG. 2 is attached.
FIG. 9 is a partially cutaway side view showing an example in which a projection forming a welding margin and a concave portion for receiving the projection are different from the slider of FIG. 2;
FIG. 10 is a partially cutaway side view showing an example in which a projection forming a welding margin and a concave portion for receiving the projection are different from the slider of FIG. 2;
FIG. 11 is a partially cutaway side view showing an example in which a projection forming a welding allowance and a concave portion for receiving the projection are different from the slider of FIG. 2;
FIG. 12 is a perspective view showing a conventional example of a linear guide device.
FIG. 13 is a front view showing an end cap of a slider described in Japanese Patent Application Laid-Open No. 10-115316.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Guide rail 11 Rolling groove 12 Ball rolling path 2 Slider 2A Slider leg 2B Slider horizontal part 21a Rolling groove 21b Ball return path 22a Redirection path 25 Circulation path 3 Ball (rolling element)
40 Main body 41 Inner leg 42 Main body horizontal portion 43 Recess 44 parallel to rolling groove Tapered surface 46A Recess 47 Outer portion 47a on both sides of recess Recessed screw hole 48 Edge 49 Sloped portion 50 Frame (outer member)
50a Outer side surface 51 of frame horizontal portion Outer leg 51a First portion 51b of outer leg 51c Second portion of outer leg 51c Stepped portion 51d Tapered surface 52 Frame horizontal portion 52a Concave portion 53 continuous with concave portion of main body Inside of turning path Side groove 54 Convex portion 55a parallel to return passage 55a Recess 57a to insert protrusion for welding allowance Recess 59 Projection 505 Projection (projection for weld allowance)
605 Projection (projection that forms the welding margin)
60 End cap (outer member)
61 End leg 62 End cap horizontal portion 63 Projection 63a Outer groove 63b of direction change path Tongue 63c Surface of projection on frame side 64 Plate-shaped material 65 Depression 65a Recess 66 for inserting projection forming welding margin Projection for positioning with frame 66b Through hole 67 Through hole (grease nipple mounting hole)
68 Through-hole 68a Small-diameter portion 68b Large-diameter portion 69 Convex portion 7 for positioning with side seal Side seal 71 Through-hole 72 Tapping screw 8 Top cover (outer member, plate member)
81 Cover portion 82 Projection (projection forming welding margin)
805 A recess for inserting a projection that forms a welding margin 806 A recess L1 for inserting a projection that forms a welding allowance
L2 Height of the cylinder that forms the recess (dimension in the depth direction of the recess in which the protrusion is placed)
R1 The diameter of the bottom surface of the cylinder forming the protrusion R2 The diameter W of the bottom surface of the cylinder forming the recess W Holding wire W1 The longest outer dimension W2 in the slider width direction between the lower ends of the inner legs W2 Shortest dimension

Claims (4)

It is composed of a guide rail, a slider and a plurality of rolling elements,
Rolling grooves of rolling elements are formed on both sides in the width direction of the guide rail,
The slider is composed of legs 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 legs,
On the inner side surfaces of the two legs, a rolling groove is provided opposite to the rolling groove of the guide rail, and the rolling groove and the rolling groove of the guide rail form a rolling passage for a rolling element, A return path for the rolling element is formed in both legs, and a direction change path that connects the return path and the rolling path is also formed in the legs.
A linear guide device in which one of the guide rail and the slider linearly moves relatively to the other by the rolling element rolling in the circulation path formed by the rolling path, the return path, and the direction change path. In the manufacturing method,
The slider includes a metal main body provided with the rolling grooves, and a plurality of synthetic resin outer members disposed outside the main body,
A projection forming a welding margin is formed on one of the bonding surfaces forming a pair of the outer member, and a concave portion for receiving the projection is formed on the other,
The pair of protrusions and the recess for receiving the protrusions are formed such that the size of the protrusion in the protrusion direction is larger than the size of the recess in the depth direction, and the protrusion is loosely fitted in the recess.
A method for manufacturing a linear guide device, wherein the plurality of outer members are integrated by welding with the main body interposed therebetween. A linear guide device manufactured by the method according to claim 1. It is composed of a guide rail, a slider and a plurality of rolling elements,
Rolling grooves of rolling elements are formed on both sides in the width direction of the guide rail,
The slider is composed of legs 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 legs,
On the inner side surfaces of the two legs, a rolling groove is provided opposite to the rolling groove of the guide rail, and the rolling groove and the rolling groove of the guide rail form a rolling passage for a rolling element, A return path for the rolling element is formed in both legs, and a direction change path that connects the return path and the rolling path is also formed in the legs.
A linear guide device in which one of the guide rail and the slider linearly moves relatively to the other by the rolling element rolling in the circulation path formed by the rolling path, the return path, and the direction change path. In the manufacturing method,
The slider includes a metal main body, a frame body detachably fitted to the outside of the main body, and end caps disposed at both ends in the direct movement direction of the frame body and fixed to the main body via the frame body. And a plate-shaped member arranged on the upper surface of the main body and having an end engaged with the frame body and the end cap,
The frame body includes an outer leg that forms an outer portion in the width direction of the leg portion, and a frame body horizontal portion that forms an end portion in a direct-moving direction of the horizontal portion. Have, with a convex part 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, has rolling grooves inside both inner legs, and corresponds to the convex portion. The main body and the frame body are integrated by having the concave portions on the outer sides of both the inner legs, and the convex portions are fitted into the concave portions. Having a concave portion for placing
The end cap includes an end leg that forms an end portion in the direct movement direction of the leg portion, and an end cap horizontal portion that forms an end portion in the direct movement direction of the horizontal portion. With side grooves,
The frame, the plate-shaped member, and the end cap are made of synthetic resin,
A projection forming a welding allowance is formed on one of the end portions in the direct movement direction of the plate-shaped member and the end cap horizontal portion or the frame horizontal portion, and a recess for receiving the projection is formed on the other side,
A projection forming a welding allowance is formed on one of the surface of the end cap on the frame body side and the surface of the frame body on the end cap side, and a recess for receiving the projection is formed on the other,
The pair of protrusions and the recess for receiving the protrusions are formed such that the size of the protrusion in the protrusion direction is larger than the size of the recess in the depth direction, and the protrusion is loosely fitted in the recess.
A method for manufacturing a linear guide device, wherein a frame body, a plate-shaped member, and an end cap in which a main body is fitted are integrated by welding. A linear guide device manufactured by the method according to claim 3.

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