JP5425658B2 - Exercise guidance device - Google Patents

Description

  The present invention relates to a motion guide device such as a linear guide or a ball spline that guides a movable portion such as a table to move linearly or curvedly with respect to a fixed portion such as a bed.

  This type of motion guide device includes a track member attached to a fixed part such as a bed and a moving member fixed to a movable part such as a table. A moving member is assembled | attached to a track member so that linear motion or curvilinear motion is possible. In order to reduce frictional resistance, a large number of rolling elements are interposed between the race member and the moving member so as to allow rolling motion. Further, the moving member is provided with a circuit-like rolling element circulation path through which the rolling elements circulate.

  When the rolling element rolls between the race member and the moving member, if the rolling elements before and after the traveling direction are in contact with each other, considerable slip occurs between them, so that the rolling element is worn early. Invite. In order to solve this problem, there is known a rolling element holding body in which a spacer is interposed between rolling elements positioned before and after the traveling direction, and a large number of spacers are connected in series with a belt (see Patent Document 1). Since the contact between the rolling elements can be prevented by the spacer, it is widely used in this type of motion guide device that uses the rolling motion of the rolling elements.

  The circuit-shaped rolling element circulation path of the motion guide device is a load rolling element rolling path between the rolling element rolling part of the raceway member and the loaded rolling element rolling part of the moving member, and is not parallel to the loaded rolling element rolling path. It is comprised from a pair of U-shaped direction change path which connects a load return path, a load rolling-element rolling path, and a no-load return path. On the rolling element rolling path, the rolling element rolls while receiving a load. In the no-load return path and the pair of direction change paths, the rolling element is in an unloaded state and moves while being pushed by the subsequent rolling element or being pulled by the rolling element holder.

  The rolling element circulates in the rolling element circulation path together with the rolling element holder. When the rolling element holder circulates in the rolling element circulation path, the belt of the rolling element holder extends linearly in the loaded rolling element rolling path and the no-load return path, and bends in a U shape in the direction changing path. When the belt is a flexible elastic body, a stress caused by bending is generated in the belt that bends in a U shape in the direction change path. In the rolling element holder in which a spacer is interposed between the rolling elements, not only a simple bending stress but also a complicated stress acts on the belt for the following reasons. That is, the actual position of the spacer that moves in the rolling element circulation path is determined by the rolling elements that are positioned before and after the traveling direction. The actual position of the spacer is different from the virtual position of the spacer when the belt is bent under the assumption that there are no rolling elements. For this reason, not only a simple bending stress but also a complicated stress is generated on the belt of the rolling element holder. Conventional belts for rolling element holders have been designed to withstand such complex stresses.

  In order to prevent the occurrence of complicated stress in the belt, the applicant does not interpose a spacer between the rolling elements before and after the traveling direction, and uses rolling element holding portions arranged on both the left and right sides in the traveling direction. The rolling element holding body which hold | maintains a rolling element was proposed (refer patent document 2). The rolling element holder includes rolling element holders disposed on both left and right sides in the traveling direction of the rolling element, and a belt that connects the rolling element holders on both the left and right sides. According to this rolling element holder, since there is no spacer between the rolling elements before and after the traveling direction, it is possible to prevent a complicated stress from being generated on the belt.

JP-A-5-52217 JP 2008-175324 A

  However, in the conventional rolling element holding body, the rolling element located in the load rolling element rolling path pulls the belt, so the belt of the direction changing path contacts the inner peripheral side guide surface of the direction changing path, There is a problem of causing a relative slip at a speed to perform. Even if the rolling element holders of the rolling element holder are arranged on both sides in the traveling direction of the rolling element, this problem cannot be solved.

  The inventor paid attention to the force acting on the rolling element holder when the rolling element turns on the direction change path. As a result, it has been found that the force for pulling the spacer and the rolling element holding portion inwardly of the turn is overwhelmingly larger than the force protruding outward, which causes the belt to contact the inner peripheral guide surface of the direction change path.

  Therefore, the present invention reduces the difference between the force that pulls the rolling element holding body into the inside of the turn and the force that protrudes outward, thereby preventing the belt of the rolling element holding body from contacting the inner peripheral guide surface of the direction change path. It is an object of the present invention to provide a motion guide device that can relieve pressure and contact pressure.

  In order to solve the above-described problems, one aspect of the present invention is a raceway member having a rolling element rolling part extending in a longitudinal direction, a loaded rolling element rolling part facing the rolling element rolling part, and the loaded rolling element. A no-load return path extending in parallel with the rolling section, a moving member having a direction changing path connecting the loaded rolling element rolling section and the no-load return path, the rolling element rolling section and the loaded rolling element A plurality of rolling elements arranged in a rolling element circulation path composed of a loaded rolling element rolling path between the rolling sections, the no-load return path, and the direction changing path, and the plurality of rolling elements can be rotated. In the motion guide device, the rolling body holders are arranged on both the left and right sides in the traveling direction of each of the plurality of rolling bodies, and each of the rolling bodies is rotatably held. A rolling element holding unit and a linkage connecting a plurality of rolling element holding units. And the rolling element holding body extends along the loaded rolling element rolling path and the no-load return path in the loaded rolling element rolling path and the no-load return path. Motion guides in which the front and rear rolling elements in the traveling direction are separated, the connecting portion of the rolling body holder is bent along the direction changing path in the direction changing path, and the front and rear rolling elements in the traveling direction are in contact with each other. Device.

  Other aspects of the present invention include a loaded rolling element rolling path, a no-load return path extending in parallel with the loaded rolling element rolling section, and a direction changing path connecting the loaded rolling element rolling section and the unloaded return path. A rolling element coupling body that is incorporated in a rolling element circulation path and that rotatably holds a plurality of rolling elements, the rolling element holding bodies being arranged on both left and right sides of the rolling elements arranged in a row, A rolling element holding portion that rotatably holds each of the plurality of rolling elements; and a connecting portion that connects the plurality of rolling element holding portions; and when the rolling element holding body is extended linearly, the rolling element holding portion When the rolling elements in the row direction held by the body are separated from each other and the rolling element holding body is bent at a predetermined curvature, the rolling element coupling body is in contact with the rolling elements in the row direction.

  According to the present invention, it is possible to generate a force (fb in FIGS. 8 and 18) for projecting the rolling element holder to the outside of the turn by bringing the rolling elements before and after the traveling direction into contact with each other on the direction change path. For this reason, it is possible to reduce the difference between the force that pulls the rolling element holding body inside the turn and the force that protrudes outward, so that the belt of the rolling element holding body contacts the inner circumferential guide surface of the direction change path. It can prevent or relieve the pressure of contact.

The side view (including a partial cross section) which shows the exercise | movement guide apparatus (linear guide) in 1st embodiment of this invention. Front view of the linear guide (including a partial cross section) The figure which shows a retainer ((a) shows a side view in the figure, (b) shows a top view) Enlarged perspective view of retainer The figure which shows the other example of a retainer ((a) shows a side view in the figure, (b) shows a top view) Enlarged view of retainer and ball circulating in ball circulation path Enlarged view of retainer and ball circulating in direction change path Vector diagram of the force acting on the retainer ball holding part An example of a geometric diagram during ball turn Figure showing a comparative example of a retainer Sectional drawing of the linear guide in 2nd embodiment of this invention Side view of the linear guide according to the third embodiment of the present invention (including a partial cross-sectional view) Front view of a linear guide according to the third embodiment of the present invention (including a partial cross-sectional view) The figure which shows a retainer ((a) shows a top view in the figure, (b) shows a side view) Enlarged perspective view of retainer Enlarged view of retainer and ball circulating in ball circulation path Enlarged view of retainer and ball circulating in direction change path Vector diagram of the force acting on the retainer ball holding part An example of a geometric diagram during ball turn Sectional drawing of the linear guide in 4th embodiment of this invention

  FIG.1 and FIG.2 shows the linear guide as a motion guide apparatus in 1st embodiment of this invention. 1 is a side view (including a partial cross-sectional view) of the linear guide, and FIG. 2 is a front view (including a partial cross-sectional view).

  The linear guide includes a track rail 1 as a track member extending linearly, and a moving block 2 as a moving member provided on the track rail 1 through a plurality of balls 3 as rolling elements. Yes.

  The track rail 1 is elongated with a substantially square cross section. Ball rolling grooves 1 a as rolling element rolling portions extending along the longitudinal direction are formed on the left and right side surfaces and the upper surface of the track rail 1. In this embodiment, a total of four ball rolling grooves 1a are formed on the left and right side surfaces of the track rail 1 and two on the upper surface. The cross-sectional shape of the ball rolling groove 1a is formed into a circular arc groove shape made up of a single arc or a Gothic arch groove shape made up of two arcs. The ball contacts the ball rolling groove 1a at one point or two points. The track rail 1 is formed with a through hole 1b for a bolt for attaching the track rail 1 to a fixed portion such as a bed.

  The moving block 2 includes a moving block main body 4 in which a loaded ball rolling groove 2a as a loaded rolling element rolling portion facing the ball rolling groove 1a of the track rail 1 is formed, and both ends of the moving block main body 4 in the moving direction. It is comprised from the end plate 5 as a pair of cover member attached to a part. As shown in FIG. 2, the moving block body 4 includes a central portion 4 a that faces the upper surface of the track rail 1, and a side wall portion 4 b that extends downward from both the left and right sides of the central portion 4 a and faces the left and right side surfaces of the track rail 1. . Four load ball rolling grooves 2a facing the ball rolling groove 1a of the track rail 1 are formed on the lower surface of the central portion 4a of the moving block body 4 and the inner surface of the side wall portion 4b.

  As shown in FIG. 1, a load ball rolling path P <b> 1 is formed between the ball rolling groove 1 a of the track rail 1 and the load ball rolling groove 2 a of the moving block 2 as a load rolling element rolling path extending linearly. Is done. The unloaded return path P2 extends linearly in parallel with the loaded ball rolling path P1. The end of the load ball rolling path P1 and the end of the no-load return path P2 are connected by a U-shaped direction change path P3. A ball circulation path as a circuit-like rolling element circulation path is formed by the loaded ball rolling path P1, the no-load return path P2, and the direction change path P3. A total of four ball circulation paths are formed.

  As shown in FIG. 2, the no-load return path component 7 and the R piece 8 (see FIG. 1) are provided in the moving block body 4 by insert molding of the moving block body 4 or incorporation of resin-molded parts. It is formed. In the no-load return path component 7, a no-load return path P2 extending in parallel with the loaded ball rolling groove 2a is formed. The R piece 8 is formed with the inner peripheral side of the direction change path P3. The outer peripheral side of the direction change path is formed on the end plate 5. By attaching the end plate 5 to the moving block body 4, the direction change path P3 is formed.

  A seal 6 is attached to the moving block 2 to prevent foreign matters such as dust from entering the moving block 2. The moving block 2 is attached with a nipple 9 for supplying a lubricant such as grease and lubricating oil to the ball circulation path.

  In the ball circulation path, a plurality of balls 3 are arranged and accommodated as rolling elements. The plurality of balls 3 roll while moving on the load ball rolling path P1. The ball 3 rolled to one end of the loaded ball rolling path P1 passes through the U-shaped direction changing path P3 and then enters the unloaded return path P2. The ball that has passed through the unloaded return path P2 passes through the opposite direction changing path P3 and then enters the loaded ball rolling path P1 again.

  The plurality of balls 3 are rotatably held by a retainer 10 as a rolling element holding body. A guide groove 11 (see FIGS. 2 and 6) for guiding the retainer 10 is formed in the ball circulation path of the moving block 2 over its entire length.

  3 and 4 show the retainer 10. Fig.3 (a) shows the side view of the retainer 10, FIG.3 (b) shows a top view. FIG. 4 shows a perspective view of the retainer 10. The retainer 10 is disposed on both sides of the moving direction of the ball 3, and includes a ball holding portion 12 as a rolling element holding portion that rotatably holds the ball 3, and a belt-like connecting portion 14 that connects the plurality of ball holding portions 12. . The ball holding portion 12 and the connecting portion 14 are integrally formed by resin injection molding or the like.

  The ball holding unit 12 includes a left ball holding unit 12a disposed on the left side of the traveling direction of the balls 3 (the balls 3 are also arranged in a line and thus also in the column direction of the balls 3), and a right ball disposed on the right side. Holding part 12b. The left ball holding portion 12a and the right ball holding portion 12b are disposed on the rotation axis cl1 of the ball 3 that rolls on the loaded ball rolling path P1, and holds the ball 3 in a predetermined position. As shown in FIG. 4, a curved recess 15 corresponding to the outer spherical surface of the ball 3 is formed on the opposing surfaces of the disc-shaped left ball holding portion 12a and right ball holding portion 12b. This recess 15 comes into contact with the ball 3.

  The left ball holding portion 12 a and the right ball holding portion 12 b are coupled to the connecting portion 14. The connecting portion 14 is formed in a strip shape made of an elongated thin plate so as to have flexibility. As shown in the side view of FIG. 3A, the center line cl2 in the thickness direction of the connecting portion 14 is a line cl3 connecting the center of the ball 3 held by the ball holding portion 12 (the rotation axis cl1 of the ball 3). Is disposed above the plane that includes When viewed in a cross section along the ball circulation path as shown in FIG. 7, the center line cl <b> 2 in the thickness direction of the connecting portion 14 of the retainer 10 is disposed outside the line cl <b> 3 connecting the centers of the balls 3.

  As shown in FIG. 3B, a plurality of substantially circular holes 15 corresponding to the shape of the ball 3 are opened in the connecting portion 14. An arc-shaped gap 16 corresponding to the shape of the ball 3 is vacant between the front side and the rear side in the traveling direction of the ball 3 and the connecting portion 14. The ball 3 contacts only the ball holding portion 12 without contacting the connecting portion 14 in the loaded ball rolling path P1. There is nothing that removes oil and fat as in the conventional retainer 10 on the trajectory of the portion 3a that contacts the ball rolling groove 1a of the track rail 1 or the loaded ball rolling groove 2a of the moving block 2. Better.

  FIG. 5 shows another example of the retainer 10. In the retainer 10 of this example, a piece 17 is provided on the front side (or rear side) of the moving direction of the ball 3 located at the end. By providing the piece 17, the distance between the pair of balls located at both ends of the end band-like connecting portion 14 can be kept constant.

  6 and 7 show enlarged views of the retainer 10 and the ball 3 that circulate in the ball circulation path. As shown in FIG. 6, in the loaded ball rolling path P1 and the unloaded return path P2, the balls 3 are arranged in a line. The connecting portion 14 of the retainer 10 also extends linearly along the loaded ball rolling path P1 and the unloaded return path P2. The balls 3 held by the ball holding portion 12 of the retainer 10 are separated from each other with a constant pitch.

  As shown in FIG. 7, when the ball 3 turns on the direction change path, the connecting portion 14 of the retainer 10 is bent with a predetermined curvature along the direction change path. Then, at a certain point, adjacent balls 3 come into contact with each other and cannot bend any further. In this state, the guide groove 11 is designed so that the ball holding portion 12 and the connecting portion 14 of the retainer 10 do not contact the guide groove 11 of the direction change path P3. During the turn, the ball 3 comes into contact with the inner peripheral side and the outer peripheral side of the direction change path P3 first, and the ball holding portion 12 and the connecting portion 14 of the retainer 10 do not contact the guide groove 11.

FIG. 8 shows a vector of force acting on the ball holding portion 12 of the retainer 10 when the connecting portion 14 is curved in the direction change path and the balls 3 come into contact with each other. In FIG. 8, the force acting on the ball holding portion 12 is shown on the left side, and the force balance state at the center of the ball holding portion 12 is shown on the right side. Each symbol is
f _r1 : force pulled from the adjacent ball holding portion through the connecting portion f _r2 : force pulling the entire turn portion inward f _r3 : reaction force caused by bending of the connecting portion f _b : reaction force caused by contact between balls It is. From the difference in strength between the connecting portion 14 of the retainer 10 and the ball holding portion 12, it is considered that the retainer 10 is bent only by the connecting portion 14 and the vicinity of the joint portion between the connecting portion 14 and the ball holding portion 12 is not bent.

  As shown in FIG. 8, the reaction force fb due to the contact of the ball 3 can be generated by bringing the ball 3 into contact with the direction change path P3. The force that protrudes the ball holding portion 12 to the outside of the turn can be increased, and the force that protrudes the ball holding portion 12 to the outside of the turn can be brought close to the force that pulls the inside of the turn. For this reason, when the ball 3 turns on the direction change path P3, the amount of movement of the retainer 10 to the inside of the turn can be reduced, and the retainer 10 can be moved in a state close to the ideal state as designed. Therefore, it is possible to prevent the connecting portion 14 and the ball holding portion 12 of the retainer 10 from moving inside the turn and the retainer 10 from contacting the guide groove 11. In addition, since the ball holding portion 12 is arranged on the left and right of the traveling direction of the ball 3, the ball holding portion 12 does not become an obstacle to the turn of the ball 3 when turning on the direction change path P3. For this reason, the ball 3 can be smoothly moved. From the above, it is considered that the durability of the retainer 10 is remarkably improved, and the reliability of the retainer-containing guide is also considered to be improved.

  The force that pulls the ball holding portion 12 inward is slightly larger than the force that protrudes the ball holding portion 12 outward. The force that finally pulls the remaining ball holding portion 12 to the inside of the turn performs work for the direction change path (the centripetal force causes the ball 3 to move circularly on the direction change path P3).

  The ball 3 is held in the vicinity of the rotation axis cl1 of the ball 3 by ball holding portions 12 arranged on the left and right in the traveling direction. Since the tangential speed is small in the vicinity of the rotation axis cl1 of the ball 3, its frictional resistance is small even if the ball 3 is held. For this reason, it is possible to reduce the rolling resistance of the ball 3 and to improve the positioning accuracy of the linear guide.

  FIG. 9 shows an example of a geometric diagram during a ball turn. In order to bring the balls 3 into contact with each other on the direction change path P3, as shown in this figure, the radius R of the ball, the ball pitch 2b, and the PCD of the direction change path may be determined. FIG. 9 shows a state in which the connecting portion 14 of the retainer 10 is bent from a straight state and the balls 3 are in contact with each other in a state where the ball pitch is half. As shown in FIG. 9, the xy coordinates are set, the coordinates of the joint between the connecting portion 14 of the retainer 10 and the ball holding portion 12 are (a, 0), and the coordinates of the center of the ball 3 when the connecting portion 14 is straight. (B, -c). When the ball rotates from the unknown r by θ and the ball center comes to (b ′, c ′), the balls come into contact with each other. The ball radius is R. If b ′ and c ′ are indicated using these a, b, c, r, and θ, the unknown numbers r and θ can be obtained from the relationship of (1) and (2). Also, the ball center diameter PCD is obtained.

FIG. 10 shows a comparative example of the retainer when the spacer 21 is interposed between the balls 3. When the spacer 21 is interposed between the balls 3, there is nothing that restricts the bending of the connecting portion 22 that occurs during the turn. Therefore, most of the force generated during the turn is the force that pulls the spacer 21 into the inside of the turn. Contact with the guide groove of the connecting portion 22 of the spacer 21 occurs, and relative slip occurs at a corresponding speed. The left side of FIG. 10 shows the force acting on one spacer 21 during the ball turn, and the right side shows the balance of the force at the center of the spacer 21. Each symbol is
f _r1 : force pulled from the adjacent spacer through the connecting portion f _r2 : force pulling the entire turn portion inward f _r3 : reaction force caused by bending of the connecting portion f _b : reaction force received from the ball.

  As shown in FIG. 10, the force balance is considered to be overwhelmingly larger (◯> Δ) as the force pulling the spacer 21 to the inside of the turn than the force protruding outward. The force generated in excess of the force required for this turn is the force that pulls the spacer 21 into the turn.

  FIG. 11 shows a cross-sectional view of the linear guide in the second embodiment of the present invention. In this embodiment, the end of the connecting portion 14 of the retainer 10 shown in FIG. 3 is connected, and the connecting portion 14 is formed into an endless ring. Other structures are the same as those of the retainer 10 shown in FIG.

  In this embodiment, the R piece 31 as the direction change path inner peripheral side constituting part of the inner periphery side of the direction change path P3 is slidably assembled to the moving block main body 34. The R piece 31 is formed in a mushroom shape as a whole, and includes a main body portion 31a on which the inner peripheral side of the direction change path P3 is formed, and a shaft portion 31b coupled to the main body portion 31a. The shaft portion 31 b is slidably inserted into the fitting hole 34 a of the moving block main body 34. A spring 36 as an urging means is interposed between the shaft portion 31 b of the R piece 31 and the bottom surface of the fitting hole 34 a of the moving block main body 34. A DLC (Diamond-like Carbon) film may be formed on the shaft portion 31b of the R piece 31 and the inner peripheral side of the direction change path P3 so as to have a low sliding resistance. Instead of the spring 36, an elastic body such as rubber may be used.

  The endless retainer 10 is incorporated in the ball circulation path while being stretched outward by the R pieces 31 at both ends of the moving block main body 34. The outer peripheral side of the direction change path of the end plate 35 is formed deep so as to correspond to the movement trajectory of the retainer 10.

  According to the motion guide device of this embodiment, the R piece 31 is moved by the force of an elastic body such as the spring 36, and the retainer 10 is always stretched outward, so that the extension of the retainer 10 due to swelling or the like is absorbed. can do. Further, since the retainer 10 is pulled in the end plate 35, the ball 3 against the step between the metal part of the moving block main body 34 and the resin part of the end plate 35, which is a part where the ball 3 enters and exits the load region. Since the movement trajectory is more horizontal (parallel to the load ball rolling surface) and is stable, the damage caused by the collision is reduced. For this reason, performance improvement in terms of accuracy and life is expected.

  12 and 13 show a linear guide in the third embodiment of the present invention. Since the structure of the moving block 2 and the track rail 1 in which the ball 3 and the retainer 41 are incorporated is the same as that of the linear guide in the first embodiment, the same reference numerals are given and description thereof is omitted.

  14 and 15 show a retainer incorporated in the linear guide. Fig.14 (a) shows the top view of the retainer 41, FIG.14 (b) shows a side view. FIG. 15 shows a perspective view of the retainer 41. The retainer 41 of this embodiment includes a ball holding portion 42 disposed on the left and right of the ball traveling direction, and a link 44 as a connecting portion for connecting the plurality of ball holding portions 42. Each link 44 is rotatably connected to a pair of ball holding portions 42 adjacent in the traveling direction. All the ball holding portions 42 are rotatably connected by the plurality of links 44.

  As shown in FIG. 14A, the ball holding portion 42 is composed of a left ball holding portion 42a disposed on the left side in the traveling direction of the ball 3 and a right ball holding portion 42b disposed on the right side in the traveling direction. Is done. The left ball holding portion 42a and the right ball holding portion 42b are disposed on the rotation axis cl1 of the ball 3 that rolls on the loaded ball rolling path P1, and holds the ball 3 in a predetermined position. As shown in FIG. 15, a curved recess 43 corresponding to the spherical surface of the ball 3 is formed on the opposing surfaces of the disc-shaped left ball holding portion 42 a and the right ball holding portion 42 b. The dent 43 contacts the ball 3.

  The link 44 is formed in an H shape as a whole, and a left link 44a disposed on the left side in the traveling direction of the ball 3, a right link 44b disposed on the right side, an upper portion of the left link 44a, and an upper portion of the right link 44b. And an arm 44c bridged between the two. A pair of left ball holding portions 42a adjacent to each other in the traveling direction are rotatably connected to the left link 44a, and a pair of right ball holding portions 42b adjacent to each other in the traveling direction are rotatably connected to the right link 44b. An arcuate cutout 45 corresponding to the shape of the ball 3 is formed in the arm 44c. A clearance 46 (see FIG. 14B) is provided between the front and rear sides in the traveling direction of the ball 3 and the arm 44c (see FIG. 14). As shown in FIG. 14B, the link 44-1 positioned at the end has a shape in which the H-shaped link 44 is halved along the center line of the arm 44c, and the ball positioned at the end. It is fixed to the holding part 42. For the link 44, a resin having an excellent lubricating property, a resin having a high strength, or a metal is used.

  As shown in FIG. 14B, the rotation center of the link 44 with respect to one of the pair of ball holding portions 42 adjacent in the traveling direction and the rotation center of the link 44 with respect to the other of the pair of ball holding portions 42 are determined. The connected line cl2 is arranged above the line cl3 connecting the centers of the balls 3 held by the ball holding part. Thereby, when the retainer 41 is inserted into the ball circulation path, the line cl2 connecting the rotation centers of the links 44 is arranged outside the ball circulation path than the line cl3 connecting the centers of the balls 3 (see FIG. 17). ).

  16 and 17 show an enlarged view of the retainer 41 and the ball 3 that circulate in the ball circulation path, and the balls are arranged in a line in the loaded ball rolling path P1 and the unloaded return path P2. The link 44 of the retainer 41 also extends linearly along the loaded ball rolling path P1 and the unloaded return path P2. The balls 3 held by the ball holding portion 42 of the retainer 41 are separated from each other with a constant pitch.

  As shown in FIG. 17, when the ball 3 turns on the direction change path P3, the plurality of links 44 of the retainer 41 are bent. Then, at a certain point, adjacent balls 3 come into contact with each other and cannot bend any further. Since each link 44 is rotatably connected to the ball holding portion 42, bending deformation does not occur in each link 44 itself. However, when viewed as a whole of the plurality of links 44, the plurality of links 44 bend along the direction change path. In a state where the plurality of links 44 are bent along the direction changing path P3, the ball holding portion 42 and the link 44 of the retainer 41 are designed so as not to contact the guide groove 45 of the direction changing path P3.

FIG. 18 shows a vector of force acting on the ball holding portion 42 of the retainer 41 when the ball 3 comes into contact with the direction change path P3. In FIG. 18, the left side shows the force acting on the ball holding portion 42, and the right side shows the balance of forces at the center of the ball holding portion 42. Each symbol is
f _r : force that the link pulls the ball holding portion f _b : reaction force due to contact between the balls.

By contacting the balls 3 in the direction changing passage P3, it is possible to generate a reaction force f _b by contact of the balls 3. The force that pushes the ball holding portion 42 to the outside of the turn can be increased, and the force that pushes the ball holding portion 42 to the outside of the turn can be brought close to the force that pulls the ball holding portion 42 to the inside of the turn. When turning on the road, the amount of movement of the retainer 41 to the inside of the turn can be reduced.

  In addition, since the link 44 of the retainer 41 and the ball holding portion 42 are link-joined, the link 44 can freely rotate with respect to the ball holding portion 42. When the ball 3 is turned, the direction of the ball row is changed by the rotation of the fitting portion, so that no bending stress acts on the link 44 and the ball holding portion 42. Therefore, it is considered that the durability of the retainer 41 is significantly improved.

  FIG. 19 shows an example of a geometric diagram during a ball turn. In order to bring the balls into contact with each other on the direction change path P3, as shown in FIG. 19, the radius R of the ball, the ball pitch 2b, and the PCD of the direction change path may be determined. This figure shows a state in which the balls 44 are in contact with each other when the link 44 of the retainer 41 rotates from the straight state in a state where the ball pitch is half. As shown in FIG. 19, the xy coordinates are set, the joint portion between the link 44 of the retainer 41 and the ball holding portion 42 is (a, 0), and the center of the ball 3 when the link 44 is straight is (b, -c). And When the link 44 rotates by an unknown θ and the ball center comes to (b ′, c ′), the balls come into contact with each other. The ball radius is R. If b ′ and c ′ are shown using these a, b, c, and θ, an unknown θ can be obtained from the following equation. Also, the ball center diameter PCD is obtained.

  FIG. 20 shows a cross-sectional view of the linear guide in the fourth embodiment of the present invention. In this embodiment, all the ball holding portions 42 of the retainer 41 shown in FIG. 14 are connected by the link 44, and the retainer 41 is formed into an endless ring. The other structure is the same as the retainer shown in FIG.

  The R piece 47 is formed in a mushroom shape as a whole and is slidably assembled to the moving block main body 48. The shaft portion 47 a of the R piece 47 is slidably inserted into the fitting hole 48 a of the moving block main body 48. A spring 49 as an urging means is interposed between the shaft portion 47 a of the R piece 47 and the bottom surface of the fitting hole 48 a of the moving block main body 48. The endless retainer 41 is incorporated in the ball circulation path while being stretched outward by the R pieces 47 at both ends of the moving block main body 48. The outer peripheral side of the direction change path P3 of the end plate 50 is formed deep so as to correspond to the movement trajectory of the retainer 41.

  According to the motion guide device of this embodiment, the R piece 47 is moved by the force of an elastic body such as the spring 49, and the retainer 41 is always stretched outward, so that the extension of the retainer due to swelling or the like is absorbed. be able to.

  The embodiment of the present invention can be variously modified without changing the gist of the present invention. For example, not only balls but also rollers can be used as rolling elements. In the above embodiment, the linear guide in which the moving block moves linearly has been described. However, the present invention can also be applied to a curved motion guide device in which the moving block moves in a curved manner. Furthermore, the present invention can also be applied to a ball spline composed of a track shaft as a track member and an outer cylinder surrounding the track shaft as a moving member. Further, the center line of the direction change path only needs to be bent with a predetermined curvature, and may be an arc having a constant curvature, an ellipse with a continuously changing curvature, a clothoid curve, or the like. In the case of an ellipse, a clothoid curve or the like whose curvature changes continuously, the rolling elements come into contact with each other at a place where the curvature is the largest.

DESCRIPTION OF SYMBOLS 1 ... Track rail (track member), 1a ... Ball rolling groove (rolling element rolling part), 2 ... Moving block (moving member), 2a ... Loaded ball rolling groove (load rolling element rolling part), 3 ... Ball (rolling element), 4, 34, 48 ... moving block main body (moving member main body), 5, 35, 50 ... end plate (lid member), 10, 41 ... retainer (rolling element holding body), 14 ... connecting part , 12, 42 ... ball holding part (rolling body holding part), 16 ... clearance, 31, 47 ... R piece (direction change path inner peripheral part), 36, 49 ... spring (biasing means), 42b ... right side ball Holding part (right rolling element holding part), 42a ... left ball holding part (left rolling element holding part), 44c ... arm, 44 ... link (connecting part), 44b ... right link, 44a ... left link

Claims (8)

A track member having a rolling element rolling part extending in the longitudinal direction, a loaded rolling element rolling part facing the rolling element rolling part, a no-load return path extending in parallel with the loaded rolling element rolling part, and the load A moving member having a direction changing path connecting the rolling element rolling part and the no-load return path; a loaded rolling element rolling path between the rolling element rolling part and the loaded rolling element rolling part; In a motion guide apparatus comprising: a plurality of rolling elements arranged in a rolling element circulation path composed of a load return path and the direction changing path; and a rolling element holder that rotatably holds the plurality of rolling elements. ,
The rolling element holders are arranged on both right and left sides in the traveling direction of each of the plurality of rolling elements, and a rolling element holder that rotatably holds the rolling elements, and a connection that connects the plurality of rolling element holders. And
In the loaded rolling element rolling path and the no-load return path, the rolling element holder extends along the loaded rolling element rolling path and the no-load return path and is moved forward and backward in the traveling direction held by the rolling element holder. The rolling element of
In the direction change path, the connection part of the rolling element holding body bends along the direction change path, and the motion guide device is in contact with the rolling elements before and after the traveling direction. The connecting portion that connects the plurality of rolling element holding portions has a belt shape,
When viewed in a cross section along the rolling element circulation path, the center line in the thickness direction of the connecting portion of the rolling element holder is the rolling element so that the rolling element can easily come into contact with the direction changing path. The motion guide device according to claim 1, wherein the motion guide device is disposed outside a line connecting the centers of the rolling elements held by the holding portion.   The motion guide device according to claim 2, wherein a clearance is provided between a front side and a rear side in a traveling direction of a rolling element rolling on the loaded rolling element rolling path and the connecting portion. The connecting portion that connects the plurality of rolling element holding portions includes a plurality of links that rotatably connect a pair of rolling element holding portions adjacent to each other in the traveling direction of the rolling elements,
The motion guide device according to claim 1, wherein all the rolling element holding portions are connected in series by the plurality of links.   When viewed in a cross-section along the rolling element circulation path so that the rolling elements can easily come into contact with the direction changing path, the rolling element holding unit with respect to one of the pair of rolling element holding portions adjacent to each other in the traveling direction of the rolling element. The line connecting the rotation center of the link and the rotation center of the link with respect to the other of the pair of rolling element holding parts is outside the line connecting the centers of the rolling elements held by the rolling element holding part. The motion guide device according to claim 4, wherein the motion guide device is arranged. The rolling element holding part has a left rolling element holding part arranged on the left side in the moving direction of the rolling element, and a right rolling element holding part arranged on the right side in the moving direction of the rolling element,
The link includes a left link rotatably connected to the left rolling element holder, a right link rotatably connected to the right rolling element holder, and a link between the left link and the right link. An arm to be passed,
The motion guide device according to claim 4 or 5, wherein a gap is provided between a front side and a rear side in a traveling direction of a rolling element rolling on the loaded rolling element rolling path and the arm. The moving member is
A moving member main body having the loaded rolling element rolling part and the no-load return path;
A lid member attached to an end face of the moving member body in the moving direction, and forming an outer peripheral side of the direction changing path;
A direction change path inner periphery constituting part that is slidably provided on the moving member main body and constitutes an inner periphery side of the direction change path, and
Biasing means for biasing the direction change path inner circumferential component toward the lid member so that tension can be applied to the connecting portion of the rolling element holder formed in an endless shape. The motion guide apparatus according to claim 1, wherein Incorporated into a rolling element circulation path consisting of a loaded rolling element rolling path, a no-load return path extending in parallel with the loaded rolling element rolling section, and a direction changing path connecting the loaded rolling element rolling section and the unloaded return path A rolling element coupling body that rotatably holds a plurality of rolling elements,
The rolling element holders are arranged on the left and right sides of the rolling elements arranged in a row, and a rolling element holder that rotatably holds each of the plurality of rolling elements, and a connecting portion that connects the plurality of rolling element holders. And having
When the rolling element holder is stretched in a straight line, the front and rear rolling elements held in the row direction held by the rolling element holder are separated,
A rolling element coupling body in which the rolling elements before and after the row direction come into contact when the rolling element holding body is bent at a predetermined curvature.

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