JP2013167352A - Rectilinear guide device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a rectilinear guide device capable of preventing an underseal from coming off, allowing a part for preventing the coming off to be easily processed, and restraining manufacturing cost.SOLUTION: An underseal 50 of this rectilinear guide device includes elastically deformable protrusions 52 respectively in both end parts of itself, on faces directed in a self-thickness direction. An end cap 5 includes a coming-off preventive stepped part 62 engaged with the protrusions 52 of the underseal 50 in a direction opposed to a guide rail, and allowing moving in a longitudinal direction of the underseal 50, in an inside of an underseal groove 60. The stepped part 62 is formed of a border between a narrow width part 64 and a wide width part 66, by bringing a guide rail side into the narrow width part 64 narrowing a groove width of the underseal groove 60, and by bringing a side opposed to the guide rail into the wide width part 66 making the groove width wider than that of the narrow width part 64.

Description

  The present invention relates to a linear motion guide device including a guide rail and a slider slidably provided on the guide rail via a plurality of rolling elements, and is particularly mounted on this type of linear motion guide device. In particular, the present invention relates to a mounting structure for an under seal that seals between a side surface of a guide rail and an inner side surface of a slider.

  In this type of linear motion guide device, a slider is slidably mounted on a guide rail via a plurality of rolling elements, and one of the guide rail and the slider moves relative to the other by rolling the plurality of rolling elements. And move relatively straight. In this type of linear motion guide device, an under seal is attached to seal between the side surface of the guide rail and the inner side surface of the slider.

  As a conventional underseal mounting method, for example, there is one disclosed in Patent Document 1. In the linear motion guide device described in the same document, the slider has a slider body and two end caps disposed at both ends of the slider body, and both end portions in the longitudinal direction of the under seal correspond to the corresponding end caps. Are inserted into under seal grooves that are formed through the insertion side in the longitudinal direction. A cylindrical protrusion is provided at the end of the under seal, and the protrusion is inserted into the under seal groove of the end cap, and the under seal is caused by the frictional force generated between the protrusion of the under seal end and the under seal groove. Secure the seal.

  As another example, for example, Patent Document 2 discloses a method for preventing underseal detachment. According to the configuration, a recess is further provided in the under seal groove of the end cap, and the recess and the protrusion at the end of the under seal are engaged, thereby preventing the under seal from falling off.

No. 6-19857 JP 2007-303620 A

However, in the technique described in Patent Document 1, a cylindrical protrusion is provided at the end of the under seal. However, since the contact area between the protrusion and the end cap is small, the frictional force is small and the under seal is easily dropped. There is a problem.
On the other hand, since the technique described in Patent Document 2 has a structure in which a recess is further provided in the under seal groove of the end cap, it is difficult to process the recess. Further, in view of the size of the end cap portion, if the recess is further provided in the under seal groove, only a small depth of the recess can be secured. For this reason, it is difficult to make a sufficient amount of engagement with the protrusions at the end of the under seal, and there is a problem that the force for restraining the under seal is small. In addition, when the end cap is manufactured by molding, the structure is further provided with a recess in the under seal groove, so that the molded product is difficult to come off from the mold, and there is a concern that the end cap may be cracked or otherwise defective. .

  Accordingly, the present invention has been made paying attention to such a problem, and prevents the under seal from falling off, and can easily process the part to prevent the dropping and reduce the manufacturing cost. The object is to provide a guidance device.

  In order to solve the above-described problems, a linear motion guide device according to a first aspect of the present invention is provided such that the guide rail and the guide rail are slidably extended via a plurality of rolling elements. In a linear motion guide device comprising a slider, and an under seal that seals between a side surface of the guide rail and an inner side surface of the slider, the slider is disposed at both ends of the slider body and the slider body. The under seal groove has two end caps, and both end portions in the longitudinal direction of the under seal are provided in the corresponding end caps so as to penetrate the longitudinal insertion side and the guide rail side. The under-seal is a protrusion that can be elastically deformed to the both end portions of itself and to the surface facing the thickness direction. The end cap engages in the under seal groove in a direction opposite to the guide rail with respect to the protrusion of the under seal, and is allowed to move in the longitudinal direction. The step portion for preventing slipping is a narrow portion in which the width of the under seal groove is narrowed on the guide rail side, and the opposite side to the guide rail is a groove than the narrow portion. It is characterized in that it is formed by a boundary between the narrow part and the wide part by being a wide part with a wide width.

According to the linear motion guide device according to the first aspect, a step portion for preventing slipping is provided in the under seal groove of the end cap, and the protrusion at the end of the under seal inserted into the under seal groove is for preventing slipping. Since the step portion and the guide rail engage with each other in the opposing direction, the holding ability of the under seal is further increased, and the effect of preventing the under seal from dropping off is obtained.
According to the linear motion guide device according to the first aspect, the step portion for preventing the under seal from coming off is a groove width portion in which the guide rail side narrows the groove width of the under seal groove, and the guide rail is Since the opposite side is a wide part with a wider groove width than the narrow part, it is formed at the boundary between the narrow part and the wide part, making it easy to process the stepped part that prevents falling off Cost can be reduced.

Here, in the linear motion guide device according to the first aspect, it is preferable that the narrow portion has an inclined surface formed so that the narrow portion widens toward the guide rail. With such a configuration, it is possible to prevent the under seal from falling off, while making it easier to install the under seal.
Further, in the linear motion guide device according to the first aspect, a step portion formed by a boundary between the narrow width portion and the wide width portion extends the narrow width portion to the side opposite to the guide rail side. It is preferable that the dovetail is formed by the formed inclined surface. With such a configuration, it is possible to more reliably prevent the under seal from dropping while facilitating the mounting of the under seal.

  Furthermore, in order to solve the above-described problem, a linear motion guide device according to a second aspect of the present invention includes a guide rail and a guide rail, and the guide rail is slidably extended via a plurality of rolling elements. In the linear motion guide device, the slider includes a slider main body and both ends of the slider main body. The linear guide device includes an under seal that seals between a side surface of the guide rail and an inner side surface of the slider. Two end caps, and the under seal is provided with both ends in the longitudinal direction thereof provided in the corresponding end caps, and the under seal is formed to penetrate through the longitudinal insertion side and the guide rail side. A linear motion guide device inserted and held in each of the seal grooves, wherein the end cap projects into a surface facing the thickness direction of the end cap in the under seal groove. The under seal is engaged with both ends of the end cap and in a direction opposite to the guide rail with respect to the protrusion of the end cap, and is allowed to move in the longitudinal direction and is elastically deformable to prevent the slipping out. A step portion for preventing slipping, wherein the guide rail side is a narrow portion where the width of the under seal groove is narrowed, and the opposite side to the guide rail is the narrow portion. It is characterized in that it is formed at the boundary between the narrow width part and the wide width part by making it a wide part with a wider groove width.

  According to the linear motion guide device according to the second aspect, the protrusion is provided in the under seal groove of the end cap, and the step portion for preventing the under seal from being inserted into the under seal groove is in the direction facing the guide rail. Since they are engaged, the holding ability of the under seal is further increased, and the effect of preventing the under seal from dropping off is obtained.

According to the linear motion guide device according to the second aspect, the step portion for preventing the under seal from coming off is a groove width portion in which the guide rail side narrows the groove width of the under seal groove, and the guide rail is Since the opposite side is a wide part with a wider groove width than the narrow part, it is formed at the boundary between the narrow part and the wide part, making it easy to process the stepped part that prevents falling off Cost can be reduced.
Here, in the linear motion guide device according to the second aspect, it is preferable that the narrow portion has an inclined surface formed so that the narrow portion widens toward the guide rail. With such a configuration, it is possible to prevent the under seal from falling off, while making it easier to install the under seal.

In the linear motion guide device according to one aspect of the present invention, the under seal can be removed from the under seal groove and attached to the under seal groove in a state where the slider is assembled to the guide rail. It is preferable that it is composed only of an elastic material that can be used. With such a configuration, the under seal can be attached and detached without removing the slider from the guide rail. Therefore, it is excellent in maintainability.
Moreover, in the linear motion guide device according to one aspect of the present invention, in order to increase the rigidity of the under seal, it is preferable that the under seal has a core bar provided over the entire length of the mounting portion of the under seal.

  As described above, according to the present invention, it is possible to prevent the under seal from falling off, and to easily process a portion that prevents the under seal from being dropped, thereby reducing the manufacturing cost.

BRIEF DESCRIPTION OF THE DRAWINGS It is a figure explaining one Embodiment of the linear guide apparatus (linear motion guide apparatus) which concerns on 1 aspect of this invention, The figure is a front view which shows the linear guide apparatus of the state which removed the right side half of the end cap. . It is a front view which shows the inner surface of the end cap which comprises the linear guide apparatus of FIG. It is explanatory drawing of 1st embodiment of the under seal mounting part of the linear guide apparatus of FIG. 1, Comprising: The figure (a) is the figure which looked at the one leg part of the slider of a linear guide apparatus from the lower surface side of FIG. (B) is an AA sectional view in the same figure (a) (however, the direction of the top and bottom is matched with the direction shown in FIG. 2). It is a figure (the figure corresponding to Drawing 3 (b) (it is the same in the first embodiment below)) showing the modification (the first modification of the first embodiment) of the under seal mounting part. It is a figure which shows the modification (2nd modification of 1st embodiment) of an underseal mounting part. It is a figure which shows the modification (3rd modification of 1st embodiment) of an under seal mounting part. It is a figure which shows the modification (4th modification of 1st embodiment) of an underseal mounting part. It is a figure which shows the modification (5th modification of 1st embodiment) of an underseal mounting part. It is a figure which shows the modification (6th modification of 1st embodiment) of an under seal mounting part. It is a figure which shows the modification (7th modification of 1st embodiment) of an underseal mounting part. It is explanatory drawing of 2nd embodiment of the under seal mounting part of the linear guide apparatus of FIG. 1, Comprising: The figure (a) is the figure which looked at the one leg part of the slider of a linear guide apparatus from the lower surface side of FIG. (B) is an AA sectional view in the same figure (a) (however, the direction of the top and bottom is matched with the direction shown in FIG. 2). It is a figure (the figure corresponding to Drawing 11 (b) (it is the same in the following 2nd embodiment)) which shows the modification (the 1st modification of a 2nd embodiment) of an under seal mounting part. It is a figure which shows the modification (2nd modification of 2nd embodiment) of an under seal mounting part. It is a figure which shows the modification (3rd modification of 2nd embodiment) of an under seal mounting part. It is explanatory drawing of 3rd embodiment (example in which an under seal has a metal core) of an underseal mounting part, The figure differs only in the point (The following other 3rd implementations which have a metal core) corresponding to FIG. The same applies to the modification of the embodiment). It is a modification of 3rd embodiment, The figure has shown the figure corresponding to FIG. It is a modification (a figure corresponding to Drawing 5) of a third embodiment. It is a modification (a figure corresponding to Drawing 6) of a third embodiment. It is a modification (a figure corresponding to Drawing 7) of a third embodiment. It is a modification (a figure corresponding to Drawing 8) of a third embodiment. It is a modification (a figure corresponding to Drawing 9) of a third embodiment. It is a modification (a figure corresponding to Drawing 10) of a third embodiment. It is a modification (a figure corresponding to Drawing 11) of a third embodiment. It is a modification (a figure corresponding to Drawing 12) of a third embodiment. It is a modification (a figure corresponding to Drawing 13) of a third embodiment. It is a modification (a figure corresponding to Drawing 14) of a third embodiment. It is a modification of the third embodiment (example in which the core bar has a portion not covered with the elastic material of the under seal). It is a modification of the third embodiment (example in which the core bar has a portion not covered with the elastic material of the under seal). It is a modification of the third embodiment (example in which the core bar has a portion not covered with the elastic material of the under seal). In the example shown in FIG. 27, it is a modification which does not have a metal core (an under seal is formed only with an elastic material). 1A is a view of one leg portion of the slider of the linear guide device as viewed from the lower surface side of FIG. 1, and FIG. 1B is a cross-sectional view taken along the line AA in FIG. However, the direction of the top and bottom is matched with the direction shown in FIG. In the example shown in FIG. 28, it is a modification which does not have a metal core (an under seal is formed only with an elastic material). In the example shown in FIG. 29, it is a modification which does not have a metal core (an under seal is formed only with an elastic material).

Hereinafter, a linear guide device that is a first embodiment of a linear guide device having an under seal mounting structure according to the present invention will be described with reference to the drawings as appropriate.
As shown in FIG. 1, 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 1a thereof. The slider 2 includes leg portions 2A disposed on both sides in the width direction of the guide rail 1, and a horizontal portion 2B that couples both the 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 (the direction perpendicular to both the length direction and the width direction). Side surfaces 2 a are disposed opposite to both side surfaces of the guide rail 1.

  The slider 2 has a slider body 4 and a pair of end caps 5. The pair of end caps 5 are disposed at both ends of the slider body 4 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 slider body 4. These rolling grooves 11 and 21a form rolling paths for a plurality of balls 3.

  Further, a linear return passage 22 is formed in the slider body 4 at a position outside the rolling groove 21a. The two end caps 5 are formed with a semi-circular groove 5a on the inner surface (the surface on the slider body 4 side) in a plan view (see FIG. 2). A direction changing path is formed by the semicircular arc-shaped groove 5a and an arcuate convex surface of a semicylindrical return guide (not shown). The direction changing path connects the rolling path including the rolling grooves 11 and 21a and the return path 22 to form an infinite circulation path for circulating the ball 3 infinitely by these paths. This linear guide device has four (two to four rows) infinite circulation paths, and the slider 2 slides along the guide rail 1 by rolling a plurality of balls 3 in each infinite circulation path.

  In this linear guide device, an under seal 50 for sealing between the side surface 1a of the guide rail 1 and the inner side surface 2a of the slider 2 from the lower side (the tip side of the left and right leg portions 2A) is provided on both leg portions 2A. It is attached. The under seal 50 is an example in which the slider 2 is made of only an elastic material that can be detached from the under seal groove 60 and attached to the under seal groove 60 in a state where the slider 2 is assembled to the guide rail 1. It is.

  Here, in the attachment structure of the under seal 50, as shown in FIG. 1, the under seal housing step 4a that is recessed from the outer surface 2b side is provided on the lower surface of the slider body 4 on the left and right inner surface 2a side. In addition, as shown in FIG. 2, under seal grooves 60 are respectively provided at predetermined depths in the lower portions 5 d on the left and right inner surfaces of the end cap 5. As shown in FIG. 3A, the under seal groove 60 is formed to penetrate in the longitudinal insertion side of the under seal 50 and the direction facing the guide rail 1. The under seal 50 has a mounting portion 50 s on the side opposite to the lip portion 50 r side, and both longitudinal ends of the mounting portion 50 s are respectively inserted into the under seal grooves 60 of the corresponding end caps 5. Retained.

  The under seal 50 has protrusions 52 that can be elastically deformed on both ends thereof (both ends in the longitudinal direction of the mounting portion 50 s) and on the surfaces facing the thickness direction of the under seal 50. In the example shown in FIG. 3B, the protrusion 52 is formed on the surface facing the lower surface side of the slider 2, and the shape seen from the lower surface side of the slider is a rectangular shape (see FIG. 3A). is there. The rectangular shape of the protrusion 52 is a rectangle, and the direction in which the long side extends is formed along the formation direction of the step 62 for preventing the under seal groove 60 from coming off.

  That is, the step portion 62 for preventing the under seal groove 60 from coming off is engaged with the protrusion 52 of the under seal 50 in the direction facing the guide rail 1 and is formed along the longitudinal direction of the under seal 50. Thus, the under seal 50 is formed to be allowed to move in the longitudinal direction. In particular, as shown in FIG. 3 (b), the step portion 62 for preventing the slipping is formed such that the guide rail 1 side of the under seal groove 60 is a narrow width portion 64 in which the groove width of the under seal groove 60 is narrowed. The side opposite to the rail 1 side is a wide portion 66 having a groove width wider than that of the narrow portion 64, thereby forming a boundary between the narrow portion 64 and the wide portion 66. In the example of the present embodiment, the step portion 62 for preventing removal is formed on the surface facing the slider upper surface side with respect to the under seal groove 60, and the shape of the surface of the step portion 62 that engages with the protrusion 52. The (angle) is provided at a right angle to the direction in which the under seal 50 is inserted.

Next, the operation and effect of this linear guide device will be described.
This linear guide device is provided with a step portion 62 for preventing slippage in the under seal groove 60 of the end cap 5, and the protrusion 52 at the end of the under seal 50 inserted into the under seal groove 60 is a step portion for preventing slipping. Since 62 and the guide rail 1 are engaged in the opposing direction, the holding ability of the under seal 50 is further enhanced, and the effect of preventing the under seal 50 from falling off is obtained.

  According to this linear guide device, the step portion 62 of the under seal groove 6 has the narrow width portion 64 in which the groove width of the under seal groove 60 is narrowed on the guide rail 1 side and the opposite side to the guide rail 1 side. Since it is formed at the boundary between the narrow width portion 64 and the wide width portion 66 by being the wide width portion 66 having a groove width wider than that of the narrow width portion 64, it is formed through the insertion side in the longitudinal direction of the under seal 50. Can be easily processed from the side. That is, it is easy to process the stepped portion 62 that is a part for preventing the dropout, and the manufacturing cost can be reduced.

Further, according to this linear guide device, the under seal 50 can be removed from the under seal groove 60 and attached to the under seal groove 60 in a state where the slider 2 is assembled to the guide rail 1. Therefore, the under seal 50 can be attached and detached without removing the slider 2 from the guide rail 1. Therefore, it is excellent in maintainability.
Note that the linear motion guide device according to the present invention is not limited to the linear guide device of the above-described embodiment, and it goes without saying that various modifications can be made without departing from the gist of the present invention.

  For example, in the above-described embodiment, the protrusion 52 of the under seal 50 has been described as an example in which the shape seen from the slider lower surface side is a rectangular shape. However, the shape seen from the slider lower surface side is not limited to this, for example, It may be oval. However, in order to make it difficult to remove the protrusion 52 at the end of the under seal toward the guide rail 1, the shape of the protrusion 52 of the under seal 50 viewed from the lower surface of the slider is a rectangular shape. The direction in which the long side extends is preferably formed along the direction in which the step 62 for preventing the under seal groove 60 from coming off is formed.

  Further, for example, in the above embodiment, the protrusion 52 of the under seal 50 is formed on the surface facing the lower surface side of the slider 2, and the step portion 62 that engages with the protrusion 52 is formed on the slider 2 with respect to the under seal groove 60. Although it explained by the example formed in the surface which faces the upper surface side, not only this but the direction and number of the projection 52 of the under seal 50, and the direction and number of the step part 62 engaged with the projection 52, Various modifications can be made without departing from the spirit of the present invention.

For example, as in the first modification shown in FIG. 4, the protrusion 52 of the under seal 50 is formed on the surface facing the upper surface side of the slider 2, and the stepped portion 62 that engages with the protrusion 52 is formed in the under seal groove 60. On the other hand, you may form in the surface which faces the lower surface side of the slider 2. FIG.
Further, for example, as in the second modification shown in FIG. 5, the protrusions 52 of the under seal 50 are respectively formed on the surfaces facing the upper surface side and the lower surface side of the slider 2, and stepped portions 62 that engage with these protrusions 52. May be formed on the surfaces facing the lower surface side and the upper surface side of the slider 2 with respect to the under seal groove 60, respectively.

  Moreover, if the step part 62 is formed in the under seal groove 60 at the boundary between the narrow part 64 and the wide part 66, the shapes of the narrow part 64 and the wide part 66 can be variously modified. For example, as in the third modification shown in FIG. 6, the narrow width portion 64 may be shortened in the direction facing the guide rail 1 to increase the groove width on the guide rail 1 side. Also, the position where the stepped portion 62 is formed in the direction facing the guide rail 1 is close to the guide rail 1 side (lip 50r side) or far from the guide rail 1 side (back side of the groove). May be.

  Further, for example, as in the fourth modified example shown in FIG. 7, the narrow portion 64 may be configured by an inclined surface formed so as to be widened in the direction facing the guide rail 1. With such a configuration, since the narrow portion 64 is formed so as to widen in the direction facing the guide rail 1, the under seal 50 is inserted into the under seal groove 60 from the opening on the guide rail 1 side. Since it is easy to insert and easy to insert, it is suitable for preventing the dropout while facilitating insertion.

  Further, in the above-described embodiment, the step portion 62 for preventing slipping is provided such that the shape (angle) of the surface of the step portion 52 that engages with the protrusion 52 is perpendicular to the direction in which the under seal 50 is inserted. However, the present invention is not limited to this. For example, as in the fifth modification shown in FIG. 8, the stepped portion 62 formed by the boundary between the narrow portion 64 and the wide portion 66 is connected to the guide rail 1 side. May be formed in a dovetail shape by forming an inclined surface formed so as to extend the narrow portion 64 on the opposite side. With such a configuration, since the stepped portion 62 is formed in a dovetail shape, it is preferable to make it difficult to remove the protrusion 52 at the end of the under seal on the guide rail 1 side.

  The dovetail configuration is not limited to the step 62 side. For example, as in the sixth modification shown in FIG. 9, the protrusion 52 of the under seal 50 is aligned with the dovetail step 62. You may form in the shape of "Arigata" to engage. Such a configuration is more suitable for making it difficult for the under seal end portion to come off.

  Further, the above-described embodiment and each modification can be combined with each other without departing from the spirit of the present invention. For example, as in the combination example (seventh modification example) shown in FIG. 10, the narrow-width part 64 having the inclined surface shown in the fourth modification example is adopted, and the dovetail-shaped step shown in the fifth modification example is adopted. The structure of the under seal 50 is adopted by adopting the protrusion 52 formed in the shape of the “arigata” that matches the step portion of the dovetail groove, which is used in the protrusion of the under seal 50, as shown in the sixth modification. It is good. With such a configuration, it is possible to more reliably prevent the under seal 50 from falling off, while facilitating the mounting of the under seal 50.

  In the first embodiment, the end cap 5 is provided with a step portion 62 for preventing it from coming off, and the step portion 62 engages with the protrusion 52 of the under seal 50 in the direction facing the guide rail 1. Although the structural example which accept | permits the movement of the longitudinal direction of the under seal | sticker 50 was demonstrated, this invention is not restricted to this, It is good also as a structure which provides a protrusion in the end cap 5 side and provides a step part in the under seal | sticker 50 side. Hereinafter, such a configuration example will be described as a second embodiment. The second embodiment is similar to the first embodiment described above except that a protrusion is provided on the end cap 5 side and a step is provided on the under seal 50 side. The step 62 is referred to as the reference numeral 62, and the step portion on the under seal 50 side is referred to as the reference numeral 52.

  As shown in FIG. 11 (a), the under seal groove 60 is formed so as to penetrate in the longitudinal direction of the under seal 50 and the direction facing the guide rail 1. The under seal 50 has a mounting portion 50 s on the side opposite to the lip portion 50 r side, and both longitudinal ends of the mounting portion 50 s are respectively inserted into the under seal grooves 60 of the corresponding end caps 5. Retained.

  The end cap 5 according to the second embodiment has protrusions 62 on both ends of the under seal groove 60 on the surface facing the thickness direction of the under seal groove 60, and the protrusion 62 has an under seal groove 60 on the guide rail side. The narrow width portion 64 is made narrower and the opposite side of the guide rail 1 is the wide width portion 66 wider than the narrow width portion 64, so that the boundary between the narrow width portion 64 and the wide width portion 66 is obtained. The under seal 50 is engaged with the projection 62 of the end cap 5 in the opposite direction to the guide rail 1 and is allowed to move in the longitudinal direction and is allowed to move in the longitudinal direction. The step part 52 is provided.

The under seal 50 has stepped portions 52 for preventing slipping at both ends thereof (longitudinal ends of the mounting portion 50s) and elastically deformable on the surfaces facing the thickness direction.
In the example shown in FIG. 11 (b), the step 52 for preventing slipping is formed on the surface facing the lower surface side of the slider 2, and the shape viewed from the lower surface side of the slider is rectangular (see FIG. 11 (a)). This is an example. The rectangular shape of the step 52 for preventing the omission is a rectangle, and the direction in which the long side extends is formed along the direction in which the protrusion 62 of the under seal groove 60 is formed.

  That is, the protrusion 62 of the under seal groove 60 is engaged with the step portion 52 for preventing the under seal 50 from coming off in the direction facing the guide rail 1 and is formed along the longitudinal direction of the under seal 50. Thus, the under seal 50 is formed to be allowed to move in the longitudinal direction. In particular, the protrusion 62 of the under seal groove 60 has a narrow width portion 64 in which the width of the under seal groove 60 is narrowed on the guide rail side, and a wide width in which the groove width is wider than that of the narrow width portion 64 on the side opposite to the guide rail 1. By forming the portion 66, it is formed at the boundary between the narrow portion 64 and the wide portion 66.

  In the example of this embodiment, the step portion 52 for preventing the under seal 50 from coming off is formed on a surface facing the slider lower surface side with respect to the under seal groove 60, and the step portion 52 that engages with the protrusion 62. The shape (angle) of this surface is provided perpendicular to the direction in which the under seal 50 is inserted.

Next, operations and effects of the linear guide device of the second embodiment will be described.
In this linear guide device, a protrusion 62 is provided in the under seal groove 60 of the end cap 5, and the step 52 for preventing the end of the under seal 50 inserted into the under seal groove 60 is provided with the protrusion 62 and the guide rail 1. Therefore, the holding ability of the under seal 50 is further enhanced, and the effect of preventing the under seal 50 from falling off is obtained.

  According to this linear guide device, the protrusion 62 of the under seal groove 60 has the narrow width portion 64 in which the groove width of the under seal groove 60 is narrowed on the guide rail side and the side opposite to the guide rail 1 is the above-described side. Since it is formed at the boundary between the narrow width portion 64 and the wide width portion 66 by being the wide width portion 66 having a groove width wider than that of the narrow width portion 64, it is formed through the insertion side in the longitudinal direction of the under seal 50. Can be easily processed from the side. That is, it is easy to process the stepped portion 52 serving as a portion that prevents the dropout, and the manufacturing cost can be reduced.

  The protrusion 62 of the under seal groove 60 has a narrow width portion 64 in which the width of the under seal groove 60 is narrowed on the guide rail 1 side, and the groove width is wider than the narrow width portion 64 on the side opposite to the guide rail 1 side. Since the wide portion 66 is formed at the boundary between the narrow portion 64 and the wide portion 66, it can be easily processed from the side penetrating the insertion side in the longitudinal direction of the under seal 50. That is, it is easy to process the stepped portion 52 serving as a portion that prevents the dropout, and the manufacturing cost can be reduced.

  Further, according to this linear guide device, the under seal 50 can be removed from the under seal groove 60 and attached to the under seal groove 60 in a state where the slider 2 is assembled to the guide rail 1. Therefore, the under seal 50 can be attached and detached without removing the slider 2 from the guide rail 1. Therefore, it is excellent in maintainability.

The linear motion guide device according to the present invention is not limited to the linear guide device according to the second embodiment, and various modifications can be made without departing from the gist of the present invention.
For example, in the second embodiment, the step 52 for preventing the under seal 50 from falling out has been described as an example in which the shape viewed from the slider lower surface side is a rectangular shape. The shape may be, for example, a circle or an ellipse. However, in order to make it difficult to remove the under seal 50 to the guide rail 1 side, the step portion 52 for preventing the under seal 50 from coming off is formed in a rectangular shape, and the rectangular shape of the rectangular shape is such that the extending direction of the long side is the underside. Preferably, the seal groove 60 is formed along the direction in which the step 62 for preventing the seal groove 60 from coming off is formed.

  Further, for example, in the second embodiment, the step 52 for preventing the under seal 50 from coming off is formed on the surface facing the lower surface side of the slider 2, and the under seal groove is engaged with the step 52 for preventing the under seal. Although the example in which the protrusions 62 of the 60 are formed on the surface facing the upper surface side of the slider 2 is described, the present invention is not limited to this, and the direction and number of the protrusions 62 of the under seal groove 60 and the protrusions 62 are engaged. Various modifications can be made to the direction and number of the step portions 52 for preventing the under seal 50 from coming off without departing from the spirit of the present invention.

Further, for example, as in the first modification of the second embodiment shown in FIG. 12, a step 52 for preventing the under seal 50 from coming off is formed on the surface facing the upper surface side of the slider 2, and this for preventing coming off. The protrusion 62 of the under seal groove 60 that engages with the step portion 52 may be formed on the surface facing the lower surface side of the slider 2 with respect to the under seal groove 60.
Further, for example, as in a second modification of the second embodiment shown in FIG. 13, step portions 52 for preventing the underseal 50 from coming off are formed on the surfaces facing the upper surface side and the lower surface side of the slider 2, respectively. Protrusions 62 that engage with the step portions 52 for preventing slipping out may be formed on the surfaces facing the lower surface side and the upper surface side of the slider 2 with respect to the under seal groove 60.

  Further, for example, as in the third modified example of the second embodiment shown in FIG. 14, the narrow portion 64 of the under seal groove 60 is configured by an inclined surface formed so as to be widened in the direction facing the guide rail 1. May be. With such a configuration, since the narrow portion 64 is formed so as to widen in the direction facing the guide rail 1, the under seal 50 is inserted into the under seal groove 60 from the opening on the guide rail 1 side. Since it is easy to insert and easy to insert, it is suitable for preventing the dropout while facilitating insertion.

In addition, other modifications can be further incorporated into the above-described embodiments or modifications without departing from the gist of the present invention, and the above-described embodiments and modifications are further combined with each other. It can also be.
For example, in the first or second embodiment described above, the attachment structure of the under seal 50 can be removed from the under seal groove 60 and attached to the under seal groove 60 when the slider 2 is assembled to the guide rail 1. However, the present invention is not limited to this, but the rigidity of the under seal 50 can be increased by inserting a metal core into the under seal 50 as shown in FIGS. 15 to 29 below. It is good also as composition which improves.

  FIG. 15 is a third embodiment, and differs from the example of the first embodiment only in that a cored bar 70 is put in the under seal 50. As shown in FIG. 15A, the core metal 70 is a thin plate-like member and extends over the entire length of the mounting portion 50 s of the under seal 50, and constitutes a lip portion 50 r of the under seal 50. It is provided to be embedded in the elastic material. Various materials can be applied as the material of the core metal 70. For example, it can be made of metal, and if it is more rigid than the elastic material of the under seal 50, it is made of resin. Can do.

  Further, the extending portion of the core metal 70 with respect to the under seal 50 can be variously modified. For example, in order to maintain the rigidity of the under seal 50, as shown in the figure, in the full length direction of the cored bar 70 (longitudinal direction of the guide rail), the lip is projected in the shorter direction of the cored bar 70 than the mounting portion 50s. It is preferable to provide it so that it exists toward the part 50r side. Further, the entire circumference of the cored bar 70 can be completely covered with the elastic material of the under seal 50 as in the third embodiment (see FIGS. 15 to 26). It can also have a part which is not covered with an elastic material (refer FIGS. 27-29). In the example shown in FIGS. 27 to 29, the cored bar 70 is a portion that is not covered with an elastic material at a position facing the protrusion 62 on the end cap 5 side.

  Further, in the example shown in FIGS. 27 to 29, as shown in FIGS. 30 to 32, the core metal may not be provided (the under seal is formed only of the elastic material). Furthermore, as in the modification shown in FIG. 30A, the under seal groove 60 is provided with a step 52 for preventing the under seal 50 from coming off and a protrusion 62 engaged therewith in the sliding direction of the slider 2. The under seal groove 60 may be formed along the whole.

1 Guide rail 2 Slider 3 Ball (rolling element)
4 Slider body 5 End cap 50 Under seal 52 Projection of (under seal) (or step)
60 Under seal groove 62 Stepped part (for preventing omission) (or protrusion)
64 Narrow part 66 Wide part 70 Core

Claims (7)

Linear motion comprising a guide rail, a slider slidably laid on the guide rail via a plurality of rolling elements, and an under seal that seals between the side surface of the guide rail and the inner side surface of the slider In the guidance device,
The slider has a slider body and two end caps disposed at both ends of the slider body, and the under seal has both longitudinal ends thereof provided on the corresponding end caps, and A linear motion guide device that is inserted and held in an under seal groove formed through the insertion side in the longitudinal direction and the guide rail side,
The under seal has protrusions that can be elastically deformed on both ends of the under seal and on a surface facing the thickness direction of the under seal, and the end cap is in the under seal groove with respect to the protrusion of the under seal. It has a step for preventing slipping that engages in the opposite direction to the guide rail and allows movement in the longitudinal direction.
The step portion for preventing slipping is a narrow width portion where the width of the under seal groove is narrowed on the guide rail side, and a wide width portion where the groove width is wider than the narrow width portion on the side opposite to the guide rail. Thus, the linear guide device is formed by a boundary between the narrow portion and the wide portion.   The linear motion guide device according to claim 1, wherein the narrow portion has an inclined surface formed so that the narrow portion widens toward the guide rail.   A step portion formed by a boundary between the narrow portion and the wide portion is formed into a groove shape by an inclined surface formed so as to extend the narrow portion on the side opposite to the guide rail side. The linear motion guide device according to claim 1 or 2, wherein Linear motion comprising a guide rail, a slider slidably laid on the guide rail via a plurality of rolling elements, and an under seal that seals between the side surface of the guide rail and the inner side surface of the slider In the guidance device,
The slider has a slider body and two end caps disposed at both ends of the slider body, and the under seal has both longitudinal ends thereof provided on the corresponding end caps, and A linear motion guide device that is inserted and held in an under seal groove formed through the insertion side in the longitudinal direction and the guide rail side,
The under seal has protrusions that can be elastically deformed on both ends of the under seal and on a surface facing the thickness direction of the under seal, and the end cap is in the under seal groove with respect to the protrusion of the under seal. It has a step for preventing slipping that engages in the opposite direction to the guide rail and allows movement in the longitudinal direction.
The end cap has protrusions on the surface facing the thickness direction in the under seal groove, and the under seal has the guide rail at both ends of the end cap and with respect to the protrusion of the end cap. And has an elastically deformable step portion for preventing slipping that allows the movement in the longitudinal direction and the guide rail side of the under seal groove on the guide rail side. It is formed by a boundary between the narrow part and the wide part by forming a narrow part with a narrow groove width and a wide part having a wider groove width than the narrow part on the side opposite to the guide rail. A linear motion guide device characterized by that.   The linear motion guide device according to claim 4, wherein the narrow portion has an inclined surface formed such that the narrow portion is widened toward the guide rail.   The under seal is composed of only an elastic material that can be removed from the under seal groove and attached to the under seal groove in a state where the slider is assembled to the guide rail. The linear guide apparatus as described in any one of Claims 1-5.   The linear motion guide device according to any one of claims 1 to 5, wherein the under seal includes a mandrel provided over the entire length of the mounting portion of the under seal.

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