JP6092636B2 - Actuator - Google Patents

Description

  The present invention relates to an actuator that operates smoothly as a rolling element rolls therein, and in particular, while facilitating interior work of a lubricating oil holding member in a movable part of the actuator while reducing processing costs. Further, the present invention relates to a device devised to extend the maintenance period by preventing deformation / damage of the lubricant holding member and to supply the lubricant to the rolling elements over a long period of time.

  As a conventional actuator, there is an actuator described in Patent Document 1. This actuator has the following configuration. That is, a servo motor, a ball screw rotated by the servo motor, and a ball nut screwed into the ball screw and restricted in rotation are provided inside the housing, and the ball nut is provided outside the housing. A slider as a movable part, a part of which is exposed, is fixed.

A plurality of balls as rolling elements circulate in the slider and between the slider and the inner surface of the housing. This ball realizes smooth movement of the slider. The ball rolling path is provided in a through hole penetrating the slider, a space between the side surface of the slider and the rail provided on the inner surface of the housing, and both ends of the slider in the traveling direction. It consists of a space inside the return cap. The through hole that penetrates the slider and the space between the side surface of the slider and the rail provided on the inner surface of the housing are communicated with each other by the space in the return cap.
In addition, a cylindrical lubricating oil holding member holding lubricating oil is provided in the through hole of the slider so as to smooth the rolling of the ball. The ball is rolling.

JP-A-11-280866

However, the conventional configuration has the following problems.
The lubricating oil holding member is, for example, a cylindrical sintered resin member that is molded so as to be porous by heating a material obtained by filling a mold with ultrahigh molecular weight polyethylene powder and pressing it into a mold. That is, the lubricating oil retaining member is soft and has low rigidity.
Therefore, in order to prevent deformation of the lubricating oil holding member, the gap between the outer peripheral surface of the lubricating oil holding member and the inner peripheral surface of the through hole of the slider is made as small as possible so that the lubricating oil is placed in the through hole. It is conceivable that the holding member is configured to be housed. However, in such a case, if the processing accuracy of the through hole is low, the lubricating oil holding member contacts the inner peripheral surface of the through hole when the lubricating oil holding member is installed in the through hole of the slider. In such a case, the lubricating oil holding member is deformed, which makes it difficult to work the interior of the lubricating oil holding member into the through hole. For this reason, there is a problem in that high accuracy is required for processing the through hole, and processing cost increases.
In addition, since the interior work of the lubricating oil holding member is difficult, it is difficult to automate the interior work of the lubricating oil holding member, which increases the manufacturing cost.

On the other hand, in order to facilitate the interior work of the lubricant holding member, it is conceivable to increase the inner diameter of the through hole with respect to the outer diameter of the lubricant holding member. In such a case, high accuracy is not required for processing of the through hole, which is advantageous in terms of processing cost, but in order to position and fix the lubricant holding member in the through hole, It is necessary to insert both ends of the lubricant holding member into the return cap. However, inserting both ends of the lubricating oil holding member into the return cap also reduces the rigidity of the lubricating oil holding member as in the interior work of the lubricating oil holding member into the through hole. It will be difficult.
Further, when the gap between the outer peripheral surface of the lubricant holding member and the inner peripheral surface of the through hole of the slider is large, the deformation of the lubricant holding member is affected by the weight of the steel ball that rolls in the through hole of the slider. There is a concern that the rolling of the steel ball due to the hindrance may be hindered and the lubricating oil holding member itself may be damaged.

  The present invention has been made on the basis of the above points. The object of the present invention is to facilitate the interior work of the lubricating oil retaining member in the movable part and reduce the lubricating oil while reducing the processing cost. An object of the present invention is to provide an actuator capable of extending the maintenance period by preventing deformation and damage of members and supplying lubricating oil to rolling elements over a long period of time.

In order to solve the above-described problem, an actuator according to claim 1 includes a housing, a movable part movably attached to the housing, and a first roller provided between the housing and the movable part. A moving path, a through-hole provided in the movable part and providing a second rolling path, and attached to both ends of the moving part in the advancing direction, the first rolling path and the second rolling path are communicated with each other. A return cap provided with a return path, a plurality of rolling elements mounted in the return path so as to be able to roll in the first rolling path, the second rolling path, and a through hole provided therein; Consisting of a cylindrical lubricating oil holding member having a peripheral surface as the second rolling path and a cylindrical protective member provided on the outer periphery of the cylindrical lubricating oil holding member, the lubricating oil is supplied to the rolling element comprising a lubrication mechanism for a, the outer peripheral surface of the protective member A mouth portion is provided, and the protective member is formed by bending a metal plate into a cylindrical shape, and the opening of the protective member is brought close to the metal plate when the metal plate is bent. It is a clearance gap between the edge part of this and the other edge part, It is characterized by the above-mentioned.
According to a second aspect of the present invention, there is provided the actuator according to the first aspect, wherein a gap is provided between the inner peripheral surface of the through hole and the outer peripheral surface of the lubrication mechanism. Is.
According to a third aspect of the present invention, there is provided the actuator according to the second aspect, wherein both ends of the protective member are engaged with the return cap.
The actuator according to claim 4 includes a housing, a movable part movably attached to the housing, a first rolling path provided between the housing and the movable part, A through-hole provided in the movable part and providing a second rolling path, and a return path attached to both ends of the movable part in the advancing direction to communicate the first rolling path and the second rolling path. The return cap, the first rolling path, the second rolling path, a plurality of rolling elements that are rollably mounted in the return path, and the inner peripheral surface provided in the through-hole. A lubricating mechanism configured to include a cylindrical lubricating oil holding member serving as a second rolling path and a cylindrical protective member provided on an outer periphery of the cylindrical lubricating oil holding member; And the lubricating oil retaining member in the protective member The both ends and an adjustment member made of an elastic body is furnished, the second rolling way is characterized in the inner peripheral surface der Rukoto of the lubricating oil holding member and the adjustment member.
According to a fifth aspect of the present invention, in the actuator according to the fourth aspect, the adjusting member is a coil spring .
According to a sixth aspect of the present invention, in the actuator according to the first or second aspect , a sleeve is provided at each end of the lubrication mechanism, and the return cap and the lubrication mechanism have the sleeve. it is connected through and is characterized in Rukoto.
The actuator according to claim 7, in the actuator according to any one of claims 1 to 6, in the return cap and the connecting portion is protruded, formed, the return cap and the lubrication mechanism are those characterized that you have been connected via the connection portion.

As described above, according to the actuator of the first aspect, the housing, the movable part movably attached to the housing, and the first rolling provided between the housing and the movable part. A return hole provided in the movable part and provided in the movable part for providing the second rolling path, and a return that is attached to both ends of the movable part in the traveling direction and communicates the first rolling path and the second rolling path. A return cap provided with a road, the first rolling path, the second rolling path, and a plurality of rolling elements mounted in the return path so as to be capable of rolling, and an inner circumference provided in the through hole A cylindrical lubricating oil holding member whose surface is the second rolling path and a cylindrical protective member provided on the outer periphery of the cylindrical lubricating oil holding member are supplied to the rolling elements. A lubricating mechanism, so that the lubricating oil retaining member By providing the protective member on the side, interior work to the through hole of the lubricating oil holding member is made shall easily performed.
Further, since the protective member suppresses deformation of the lubricating oil holding member when the rolling element rolls in the lubricating oil holding member, the rolling element rolls in the lubricating oil holding member. Can be made smooth, and the movement of the movable part can be made smooth. In addition, since the deformation and damage of the lubricating oil holding member are suppressed by the protective member, the replacement frequency of the lubricating oil holding member can be reduced.
Further, when there is no protective member, in order to prevent the deformation of the lubricating oil holding member by the inner peripheral surface of the through hole, between the outer peripheral surface of the lubricating oil holding member and the inner peripheral surface of the through hole. Although the gap was made as small as possible and the lubricating oil retaining member was built in the through hole, the high machining accuracy of the through hole required in such a case became unnecessary, reducing the machining cost. You can plan.
The actuator described in claim 2 is the actuator according to claim 1, wherein a gap is provided between the inner peripheral surface of the through hole and the outer peripheral surface of the lubrication mechanism. It is possible to easily perform interior work in the through hole. In addition, high accuracy is not required for the processing of the through hole, and the processing cost can be reduced.
According to a third aspect of the present invention, in the actuator according to the second aspect, since both end sides of the protective member are engaged with the return cap, the lubricating mechanism can be easily used with the return cap. Positioning and fixing can be performed.
According to the actuator according to claim 4, in the actuator according to any one of claims 1 to 3, an opening is provided on the outer peripheral surface of the protective member, and therefore, through the opening, Lubricating oil can be easily supplied to the lubricating oil holding member.
According to the actuator according to claim 5, in the actuator according to claim 4, the protection member is formed by bending a metal plate into a cylindrical shape, and the opening of the protection member is made of the metal. Since it is a gap between one end and the other end that are close to each other when the plate is bent, it is possible to easily obtain the protective member having the opening simply by bending the metal plate. Can do.
According to the actuator according to claim 6, in the actuator according to any one of claims 1 to 5, the adjustment member made of an elastic body in the protective member and at both ends of the lubricating oil holding member And the second rolling path is the inner peripheral surface of the lubricating oil holding member and the adjusting member, so that the adjusting member gives a margin to the dimensional accuracy of the protective member and the lubricating oil holding member. You can have it. Further, the adjusting member prevents the rolling element from colliding with the lubricating oil holding member at an entrance portion of the lubricating oil holding member immediately after the rolling element is turned by the return path. . Also by this, deformation and damage in the lubricating oil holding member can be suppressed.
According to the actuator according to claim 7, in the actuator according to claim 6, since the adjustment member is a coil spring, the adjustment member can be easily obtained, and the lubrication mechanism can be easily configured. .
According to an eighth aspect of the present invention, in the actuator according to the first or second aspect, a sleeve is provided at each end of the lubrication mechanism, and the return cap and the lubrication mechanism have the sleeve. Therefore, the lubricating mechanism can be easily positioned by the sleeve and the return cap. Further, the sleeve prevents the rolling element from colliding with the lubricating oil holding member at the entrance portion of the lubricating oil holding member immediately after the rolling element is turned by the return path. Also by this, deformation and damage in the lubricating oil holding member can be suppressed.
An actuator according to claim 9 is the actuator according to any one of claims 1 to 7, wherein a connection portion projects and is formed on the return cap, and the return cap and the lubrication mechanism Are coupled via the connecting portion, the positioning of the lubricating mechanism and the coupling of the lubricating mechanism and the return cap can be easily performed by the connecting portion. Further, the connection portion may reduce an impact caused by the collision of the rolling element with the lubricating oil holding member at an entrance portion of the lubricating oil holding member immediately after the rolling element is turned by the return path. I have to. Also by this, deformation and damage in the lubricating oil holding member can be suppressed.

It is a figure which shows the 1st Embodiment of this invention, and is a perspective view which shows the actuator by this Embodiment. FIG. 2 is a diagram showing the first embodiment of the present invention, and is a cross-sectional view of the actuator according to the present embodiment cut at the slightly rear side of the return cap on the front side of the ball screw and viewed from the rear side. It is II sectional drawing. It is a figure which shows the 1st Embodiment of this invention, and is the partial sectional view which cut | disconnected the actuator by this Embodiment by the axial center of a ball screw, and looked down, and is III-III sectional drawing in FIG. . It is a figure which shows the 1st Embodiment of this invention, and is a perspective view which shows the slider of the actuator by this Embodiment. It is a figure which shows the 1st Embodiment of this invention, and is a partial longitudinal cross-sectional view of the lubrication mechanism of the actuator by this Embodiment. It is a figure which shows the 1st Embodiment of this invention, and is VI-VI sectional drawing in FIG. It is a figure which shows the 1st Embodiment of this invention, and is a partial perspective view of the edge part of the lubricating mechanism of the actuator of this Embodiment, and removes a part of protection member. It is a figure which shows the 2nd Embodiment of this invention, and is sectional drawing which shows the slider vicinity of the actuator by this Embodiment. It is a figure which shows the 3rd Embodiment of this invention, and is sectional drawing which shows the slider vicinity of the actuator by this Embodiment. It is a figure which shows the 4th Embodiment of this invention, and is sectional drawing which shows the slider vicinity of the actuator by this Embodiment.

Hereinafter, a first embodiment of the present invention will be described with reference to FIGS. The actuator 1 according to the present embodiment has the following configuration.
First, as shown in FIG. 1, the actuator 1 includes a housing 3 made of, for example, aluminum. The housing 3 has a substantially U-shaped cross section as shown in FIG. As shown in FIG. 2, grooves 3a and 3a 'extending in the length direction (perpendicular to the paper surface in FIG. 2) are formed on both sides in the width direction (left and right direction in FIG. 2) inside the housing 3. .
Steel rails 4 and 4 'are installed in the grooves 3a and 3a' of the housing 3, respectively. The rail 4 extends in the length direction (perpendicular to the paper surface in FIG. 2), and an arcuate recess 4a extends and is formed in the length direction (perpendicular to the paper surface in FIG. 2). The rail 4 'has the same configuration, and a recess 4a' is formed.
As shown in FIGS. 1 and 2, an upper cover 6 is installed above the opening of the housing 3 (upper side in FIG. 2).

Further, as shown in FIG. 1, a front cover 5 is provided at the tip of the housing 3 (lower left end in FIG. 1). A bearing (not shown) is housed inside the front cover 5.
A motor unit 9 is provided at the rear end (upper right side end in FIG. 1) of the housing 3 via a bearing case 7 in which a bearing (not shown) is housed. The motor unit 9 includes a motor (not shown) and an encoder for detecting the rotation speed of the motor.

  As shown in FIGS. 2 and 3, a ball screw 11 is installed in the housing 3. The ball screw 11 is rotatably supported by a bearing (not shown) in the front cover 5 and a bearing (not shown) in the bearing case 7 and is connected to an output shaft of a motor (not shown) in the motor unit 9. They are connected via a ring and are rotated by the motor (not shown). A spiral male screw portion 11 a is formed on the outer peripheral surface of the ball screw 11.

  A ball nut 13 is screwed onto the ball screw 11. As shown in FIG. 2, a female screw portion 13 a is formed on the surface of the ball nut 13 on the ball screw 11 side, and a rolling path 13 b as a no-load circulation path is formed inside the ball nut 13. Is formed. As shown in FIG. 3, return caps 13c and 13c are provided at the front and rear ends (upper and lower ends in FIG. 3) of the ball nut 13. A return path (not shown) is formed in the return caps 13c and 13c. The return path allows a space (rolling path) between the female screw portion 13a and the male screw portion 11a of the ball screw 11 and the above-described return path. The rolling path 13b is in communication. And in the space (rolling path) between the female screw part 13a of the ball nut 13 and the male screw part 11a of the ball screw 11, the rolling path 13b of the ball nut 13, and the return path, A plurality of steel balls 14 roll and circulate.

  For example, an aluminum slider 15 as a movable portion is fixed to the ball nut 13. As shown in FIGS. 1 and 2, the slider 15 is installed inside the housing 3, and both ends in the width direction (left and right direction in FIG. 2) of the upper part (upper side in FIG. 2) are the housing 3. It protrudes to the outside.

  Further, as shown in FIGS. 2, 3, and 4, grooves 15a, 15a ′ facing the grooves 3a, 3a ′ in the housing 3 are provided on both sides of the slider 15 in the width direction (left-right direction in FIG. 2). Is formed. A steel rail 17 is installed in the groove 15a, and a steel rail 17 'is installed in the groove 15a'. The rail 17 is extended in the length direction (perpendicular to the paper surface in FIG. 2), and an arc-shaped recess 17a is extended and formed in the length direction (perpendicular to the paper surface in FIG. 2). The rail 17 'has the same configuration, and an arcuate recess 17a' is extended and formed in the length direction (perpendicular to the paper surface in FIG. 2). The rail 17 and the rail 4 of the housing 3 are installed with the concave portion 17a of the rail 17 and the concave portion 4a of the rail 4 facing each other. The rail 17 ′ and the rail 4 ′ of the housing 3 are The concave portion 17a 'of the rail 17' and the concave portion 4a 'of the rail 4' are installed facing each other.

A space between the recess 17a of the rail 17 and the recess 4a of the rail 4 serves as a first rolling path 18, and the recess 17a 'of the rail 17' and the recess 4a 'of the rail 4' The space between is the first rolling path 18 '.
As shown in FIG. 2, grooves 19 and 19 'are formed above the rails 17 and 17' of the slider 15 (upper side in FIG. 2), and the slider 15 is formed by the grooves 19 and 19 '. The seal members 21 and 21 'are attached.
Further, the slider 15 is formed with through holes 23 and 23 'extending in the length direction (perpendicular to the paper surface in FIG. 2).
Further, as shown in FIGS. 1 and 4, oil supply nipples 16 are provided on both side surfaces of the upper portion of the slider 15 (upper portion in FIG. 4) (the direction from the upper left to the lower right in FIG. 4). is set up. The oil supply nipple 16 communicates with an oil supply passage (not shown) provided in the slider 15. The oil supply passage (not shown) communicates with the through holes 23 and 23 ′ and the rolling passage 13 b of the ball nut 13.

A lubrication mechanism 25 is provided in the through hole 23 of the slider 15, and a lubrication mechanism 25 ′ is provided in the through hole 23 ′.
As shown in FIGS. 5 to 7, the lubrication mechanism 25 includes a cylindrical protective member 27, a cylindrical lubricating oil retaining member 29 internally provided in the protective member 27, and the protective member 27. The adjustment oil members 31 and 31 are provided at both front and rear ends (upper and lower ends in FIG. 5) of the lubricating oil retaining member 29.

  As shown in FIG. 6, the protective member 27 is formed into a cylindrical shape by, for example, bending a metal plate having a predetermined size. In addition, an opening 33 is provided in a part of the outer peripheral side of the protective member 27, and the cross section is formed like a substantially C-shaped spring. The opening 33 is formed by a gap between one end and the other end of both ends in the width direction of the metal plate constituting the protection member 27. In the present embodiment, an iron plate is used as the metal plate.

Further, as shown in FIG. 2, the inner diameters of the through holes 23 and 23 'of the slider 15 are set larger than the outer diameter of the protective member 27 (the outer diameter of the lubricating mechanisms 25 and 25'). Yes.
The lubricating oil holding member 29 is, for example, a cylindrical sintered resin member formed by heating a material obtained by filling a mold with ultrahigh molecular weight polyethylene powder and pressing it into a porous structure. The porous structure absorbs and retains lubricating oil and grease. Then, the lubricating oil and grease are supplied over a long period to a steel ball (denoted by reference numerals 37 and 37 '), which will be described later, passing through the inner side of the first rolling path 18, 18' via the steel ball. And a return path (denoted by reference numerals 35a and 35a '), which will be described later, is lubricated to reduce friction (sliding) resistance caused by movement of the slider 15 and to improve durability. .

  The adjusting member 31 is composed of a steel coil spring. The reason why the adjustment member 31 made of such a steel coil spring is provided is as follows. First, this is to give a margin to the dimensional accuracy between the protective member 27 and the lubricant holding member 29. For example, there is no problem if the protective member 27 and the lubricating oil retaining member 29 can be manufactured with exactly the same length, but high dimensional accuracy is required for that purpose. Therefore, the lubricating oil holding member 29 is intentionally manufactured to be shorter than the protective member 27, and the adjustment member 31 tries to absorb the variation in the shortness of the lubricating oil holding member 29 with respect to the protective member 27.

  Another reason is to prevent damage to the lubricating oil retaining member 29 due to rolling before and after a return cap (indicated by reference numerals 35 and 35 ') of a steel ball (indicated by reference numeral 37) described later. This prevents the steel ball from colliding with the entrance portion of the lubricating oil retaining member 29 after the direction of the steel ball is changed by the return path (indicated by reference numeral 35a) of the return cap, and the impact caused by the collision is prevented. This is due to relaxation. If the lubricating oil holding member 29 is installed over the entire length, the steel ball collides with the front and rear of the return cap, that is, the entrance portion of the lubricating oil holding member 29, and the lubricating oil holding member 29 is damaged and deformed. There is concern. Thus, the adjustment member 31 made of a steel coil spring is arranged at such a position to prevent the lubricant holding member 29 from being damaged.

The length of the adjustment member 31 (vertical length in FIG. 3) is preferably 1/2 or more of the diameter of the steel ball.
Further, the adjustment member 31 made of a coil spring may be a metal other than steel or a hard resin. Moreover, elastic bodies other than a coil spring may be sufficient.
A space inside the lubricating oil retaining member 29 and the adjusting members 31, 31 serves as a second rolling path 34.
Similarly to the lubrication mechanism 25, the lubrication mechanism 25 ′ includes a protective member 27 ′, a lubricant holding member 29 ′, and adjustment members 31 ′ and 31 ′. The space inside the lubricating oil retaining member 29 'and the adjusting members 31', 31 'serves as a second rolling path 34'.

  As shown in FIGS. 3 and 4, return caps 35 and 35 are provided on one end in the width direction (left side in FIG. 3) of the front and rear ends of the slider 15. Return caps 35 'and 35' are installed on the other end in the width direction (right side in FIG. 3). A return path 35a is formed in the return cap 35, and a return path 35a 'is formed in the return cap 35'. The return paths 35a and 35a allow the space between the lubrication mechanism 25 and the space between the recess 17a of the rail 17 and the recess 4a of the rail 4, that is, the first rolling path 18 and the second rolling. The road 34 is in communication. The return paths 35a 'and 35a' allow the space between the lubrication mechanism 25 'and the space between the recess 17a' of the rail 17 'and the recess 4a' of the rail 4 ', that is, the first rolling path. 18 'communicates with the second rolling path 34'.

  As shown in FIG. 3, the return cap 35 (35 ′) is formed with an engaging portion 35b (35b ′). Both end portions of the protective member 27 of the lubrication mechanism 25 are engaged with the engaging portions 35b and 35b of the return caps 35 and 35, and the engaging portions 35b 'and 35b' of the return caps 35 'and 35' are engaged with each other. The both ends of the protective member 27 'of the lubricating mechanism 25' are engaged.

  It should be noted that the lubricating mechanism 25 is in a state in which the tips of the adjustment members 31, 31 made of a coil spring protrude from the opening at both ends of the protective member 27 before the engagement. In this state, by engaging the both end portions with the engaging portions 35b and 35b, the adjusting members 31 and 31 made of the coil spring are compressed and deformed against the urging force. Thereby, the position of the lubricating oil holding member 29 is fixed. Similarly, before the engagement, the lubricating mechanism 25 'is in a state in which the tips of the adjustment members 31' and 31 'made of coil springs protrude from the openings at both ends of the protective member 27'. In this state, the adjustment members 31 ′ and 31 ′ made of the coil spring are compressed and deformed against the urging force by engaging both end portions thereof with the engaging portions 35 b ′ and 35 b ′. Become. As a result, the position of the lubricant holding member 29 'is fixed.

Further, steel balls 37 as a plurality of rolling elements are circulated in the first rolling path 18, the second rolling path 34, and the return paths 35 a and 35 a in the return caps 35 and 35. . The first rolling path 18 ', the second rolling path 34', and the return paths 35a 'and 35a' in the return caps 35 'and 35' have steel balls as a plurality of rolling elements. 37 'is circulated.
The slider 15 includes the steel ball 37 in the first rolling path 18 and the steel ball 37 ′ in the first rolling path 18 ′, that is, the recess 17 a of the rail 17 and the recess 4 a of the rail 4. The rotation around the axis of the ball screw 11 is regulated by the steel ball 37 engaged with the steel ball 37 and the steel ball 37 ′ engaged with the recess 17 a ′ of the rail 17 ′ and the recess 4 a ′ of the rail 4 ′.
The above is the configuration of the actuator 1 according to the present embodiment.

Next, the operation of the actuator 1 according to this embodiment will be described.
First, when the ball screw 11 is rotated forward or reverse by a motor (not shown) of the motor unit 9, the ball nut 13, and consequently the slider 15, the male screw portion 11 a of the ball screw 11, the steel ball 14, and the ball nut 13. Due to the interaction of the female screw portion 13a, it moves forward (moves to the lower left side in FIG. 1) or retreats (moves to the upper right side in FIG. 1).

  At this time, in the first rolling path 18 between the recess 4a of the rail 4 and the recess 17a of the rail 17, the second rolling path 34 in the slider 15, and the return paths 35a and 35a in the return caps 35 and 35. A plurality of steel balls 37 are rolled. Further, the first rolling path 18 'between the recess 4a' of the rail 4 'and the recess 17a' of the rail 17 ', the second rolling path 34' in the slider 15, and the return caps 35 ', 35'. A plurality of steel balls 37 'are rolled in the return paths 35a' and 35a '. Friction (sliding) resistance between the slider 15 and the housing 3 when the slider 15 is moved is reduced by the rolling of the plurality of steel balls 37, 37 ′.

  Further, the interaction between the steel ball 37 and the rails 4 and 17 and the interaction between the steel ball 37 ′ and the rails 4 ′ and 17 ′ restrict the rotation of the slider 15 around the axis of the ball screw 11. Has been. Therefore, as already described, the slider 15 is moved forward (moved to the lower left side in FIG. 1) or moved backward (moved to the upper right side in FIG. 1) by the rotation of the ball screw 11.

  It should be noted that the rolling path 13b in the ball nut 13 or the space (rolling path) between the female threaded portion 13a of the ball nut 13 and the male threaded portion 11a of the ball screw 11 or a return (not shown) in the return cap 13c. In the road, a plurality of steel balls 14 are rolled. The rolling of the plurality of steel balls 14 reduces the resistance between the ball nut 13 and the ball screw 11 in the movement of the slider 15.

  As shown in FIGS. 2 to 4, the steel ball 37 (37 ′) and the steel ball 14 are connected to an oil supply passage (not shown) in the slider 15 from an oil supply nipple 16 provided on the slider 15. Through this, lubricating oil and grease are supplied. A part of the lubricating oil or grease is held by the lubricating mechanism 25 (25 ′) in the slider 15. That is, the lubricating oil or grease is first filled in the space between the inner peripheral surface of the through hole 23 (23 ') and the outer peripheral surface of the protective member 27 (27'), and then the protective member 27 ( 27 ') enters the inside of the protective member 27 (27') through the gap 33 (33 ') and is absorbed and held by the lubricating oil holding member 29 (29').

  The lubricating mechanism 25 (25 ′) is provided with a lubricating oil retaining member 29 (29 ′). The lubricating oil holding member 29 (29 ′) is, for example, a cylindrical sintered resin member formed by heating a material obtained by filling an ultrahigh molecular weight polyethylene powder into a mold and pressing it into a porous shape. is there. The lubricating oil and grease are held by the lubricating oil holding member 29 (29 ').

  Further, a protective member 27 (27 ') is provided on the outer peripheral side of the lubricating oil holding member 29 (29'). The protective member 27 (27 ′) is a highly rigid member, for example, formed by bending a metal plate of a predetermined size into a cylindrical shape. On the other hand, the lubricating oil retaining member 29 (29 ′) is composed of, for example, a sintered resin member made of ultrahigh molecular weight polyethylene as described above, and has a low rigidity.

Therefore, for example, assuming that only the lubricating oil holding member 29 (29 ′) is provided in the through hole 23 (23 ′) of the slider 15, the outer peripheral surface of the lubricating oil holding member 29 (29 ′). And the inner peripheral surface of the through hole 23 (23 ′), the steel ball 37 (37 ′) rolls in the lubricating oil retaining member 29 (29 ′). As a result, the lubricating oil retaining member 29 (29 ′) is deformed by the gap due to the behavior caused by the competition between the steel balls 37 (37 ′) and the weight of the steel balls 37 (37 ′). There is a concern that it will be damaged. There is a concern that this may hinder rolling of the steel ball 37 (37 ') and, consequently, smooth movement of the slider 15.
However, in the case of the present embodiment, since the protective member 27 (27 ') is provided on the outer peripheral side of the lubricating oil holding member 29 (29'), the protective member 27 (27 ') The deformation and damage of the lubricating oil retaining member 29 (29 ′) is prevented, and the smooth rolling of the steel ball 37 (37 ′) and, consequently, the smooth movement of the slider 15 is ensured.

  The protective member 27 (27 ') is, for example, a metal plate having a predetermined size that is bent into a cylindrical shape. The protective member 27 (27') is formed of the metal plate constituting the protective member 27 (27 '). A gap between one end and the other end of both ends in the width direction is an opening 33 (33 ′). For this reason, the lubricating oil retaining member 29 (from the oil supply passage (not shown) communicating with the through hole 23 (23 ') in which the lubricating mechanism 25 (25') is installed through the opening 33 (33 '). 29 ') is supplied with lubricating oil and grease.

  Further, since the adjusting members 31, 31 (31 ', 31') are arranged at both ends of the second rolling path 34 (34 '), the steel ball 37 (37') is connected to the return path 35a ( 35a ′), the steel ball 37 (37 ′) collides with the lubricating oil holding member 29 at the entrance (both ends) of the lubricating oil holding member 29 (29 ′) immediately after the direction is changed. It can be prevented. This also prevents deformation and damage of the lubricating oil holding member 29 (29 ') and smoothes the rolling of the steel ball 37 (37'), thereby smoothly moving the ball nut 13 and the slider 15. It is supposed to be.

  Further, both end portions of the protective member 27 of the lubrication mechanism 25 (25 ′) are engaged with engaging portions 35b and 35b of the return caps 35 and 35 (35 ′ and 35 ′), and the protective member 27 is The cross-sectional shape is substantially C-shaped and is like a spring. Therefore, the inner surface of the engaging portion 35b is pressed by the protective member 27 (27 ′). As a result, the protective member 27 (27 ') and thus the lubrication mechanism 25 (25') are securely engaged with the return caps 35 and 35 (35 'and 35') and elastically held. Is done.

Further, adjustment members 31 and 31 (31 formed of coil springs) are provided in the protective member 27 (27 ′) and on both front and rear ends (upper and lower ends in FIG. 5) of the lubricant holding member 29 (29 ′). ', 31') are installed. Therefore, there is no problem even if the dimensional accuracy between the protective member 27 (27 ') and the lubricating oil retaining member 29 (29') is not so high. That is, there is no problem even if there is variation in the shortness of the lubricant holding member 29 (29 ′) with respect to the protective member 27 (27 ′).

Next, the effect of the actuator 1 according to the present embodiment will be described.
First, the protective member 27 (27 ') is provided on the outer peripheral side of the lubricating oil holding member 29 (29'), so that the lubricating oil holding member 29 (29 ') is installed in the through hole 23 (23') of the slider 15. The work can be facilitated.
That is, on the outer peripheral side of the lubricating oil holding member 29 (29 '), for example, a highly rigid protective member 27 (27') is provided which is formed by bending a metal plate of a predetermined size into a cylindrical shape. Yes. Therefore, the interior work to the through-hole 23 (23 ') of the slider 15 of the said lubrication mechanism 25 (25') and by extension, the said lubricating oil holding member 29 (29 ') can be performed easily.

Further, the protective member 27 (27 ') facilitates the operation of engaging the end portion of the lubrication mechanism 25 (25') with the engaging portion 35b of the return cap 35, 35 (35 ', 35'). be able to.
If the protective member 27 (27 ') is not provided, only the end portion of the lubricating oil retaining member 29 (29') having low rigidity is engaged with the engaging portion of the return caps 35, 35 (35 ', 35'). When engaged with 35b, the lubricating oil retaining member 29 (29 ') comes into contact with the edge of the opening of the engaging portion 35b or inside the engaging portion 35b and is inadvertently deformed. Engagement work of the end of the oil retaining member 29 (29 ') with the return caps 35, 35 (35', 35 ') is hindered.

However, in the case of the present embodiment, the end portion of the protective member 27 (27 ') having high rigidity is engaged with the engaging portion 35b of the return cap 35, 35 (35', 35 '). There is no inadvertent deformation of the protective member 27 (27 '), and the engaging operation is not hindered.
Further, since the through hole 23 (23 ') is set to have a larger diameter than the lubricating mechanism 25 (25'), this also causes the through hole 23 (23 ') of the lubricating mechanism 25 (25'). The interior work is easy.
Further, since the through hole 23 (23 ') is not required to be drilled with high precision, the cost can be reduced and the slider 15 can be easily formed by, for example, extrusion molding or pultrusion molding. can do.

  In addition, adjustment members 31, 31 (31 ', 31') are installed in the protective member 27 at both front and rear ends (upper and lower ends in FIG. 5) of the lubricant holding member 29 (29 '). ing. By providing such an adjustment member 31, tolerance can be given to the dimensional accuracy between the protection member 27 and the lubricant holding member 29. For example, there is no problem if the protective member 27 and the lubricating oil retaining member 29 can be manufactured with exactly the same length, but high dimensional accuracy is required for that purpose. Therefore, the lubricating oil holding member 29 is intentionally manufactured to be shorter than the protective member 27, and the adjustment member 31 tries to absorb the variation in the shortness of the lubricating oil holding member 29 with respect to the protective member 27. Thus, as described above, a margin can be given to the dimensional accuracy between the protective member 27 and the lubricating oil retaining member 29.

  Further, both end portions of the protective member 27 of the lubrication mechanism 25 (25 ′) are engaged with engaging portions 35b and 35b of the return caps 35 and 35 (35 ′ and 35 ′), and the protective member 27 is The cross-sectional shape is substantially C-shaped and is like a spring. Therefore, the inner surface of the engaging portion 35b is pressed by the protective member 27 (27 ′). As a result, the protective member 27 (27 '), and thus the lubricating mechanism 25 (25'), is securely engaged with the return caps 35, 35 (35 ', 35'), and is elastically held. In addition, the engagement of the end of the lubrication mechanism 25 (25 ′) with the return caps 35, 35 (35 ′, 35 ′) can be facilitated.

  As described above, since the interior work of the lubrication mechanism 25 (25 ′) into the through hole 23 (23 ′) is facilitated, the lubrication mechanism 25 (25 ′) is attached to the slider 15. Work is easy to automate. Further, the attaching operation of the lubrication mechanism 25 (25 ′) to the slider 15 can be facilitated by automation.

  Further, since the adjustment members 31, 31 (31 ', 31') are coil springs, the adjustment members 31, 31 (31 ', 31') can be easily obtained, and the lubrication mechanism 25 (25 ') Can be configured easily.

  The lubricating oil holding member 29 (29 ′) is, for example, a cylindrical sintered resin formed by heating a material obtained by filling an ultrahigh molecular weight polyethylene powder into a mold and pressing it into a porous shape. It is a thing with low rigidity comprised from the member. Further, since the through hole 23 (23 ') is set to have a larger diameter than the lubricating mechanism 25 (25'), the lubricating mechanism 25 (25 ') and the through hole 23 (23') There is a gap between them. Therefore, for example, assuming that only the lubricating oil retaining member 29 (29 ′) is provided in the through hole 23 (23 ′) of the slider 15, the steel ball 37 (37 ′) is connected to the lubricating mechanism 25. (25 '), that is, when rolling in the lubricating oil retaining member 29 (29'), the behavior caused by the competition between the steel balls 37 (37 ') and the steel balls 37 (37') There is a concern that the lubricating oil holding member 29 (29 ') may be deformed or damaged by the gap due to the weight of the oil. There is a concern that the deformation and damage of the lubricating oil retaining member 29 (29 ') may hinder the rolling of the steel ball 37 (37') and, consequently, the movement of the slider 15.

  However, in the case of the present embodiment, the protective member 27 (27 ') having high rigidity is provided on the outer peripheral side of the lubricating oil holding member 29 (29'). ) Can prevent deformation and damage of the lubricating oil retaining member 29 (29 '). As a result, the rolling of the steel ball 37 (37 ′) in the lubricating oil holding member 29 (29 ′) can be made smooth, and the ball nut 13 and the slider 15 can move. It can be smooth. Further, since the deformation and damage of the lubricating oil holding member 29 (29 ') are suppressed, the replacement frequency of the lubricating oil holding member 29 (29') can be reduced.

  Further, since the lubricating mechanism 25 (25 ′) includes the lubricating oil holding member 29 (29 ′), the lubricating oil and grease can be held in the lubricating oil holding member 29 (29 ′). Further, the lubricating oil and grease can be supplied over a long period of time to the steel ball 37 (37 ′) rolling inside by the lubricating oil holding member 29 (29 ′), and the steel ball 37 ( 37 '), and the smooth movement of the ball nut 13 and the slider 15 can be maintained over a long period of time.

  The protective member 27 (27 ') is, for example, a metal plate having a predetermined size that is bent into a cylindrical shape. The protective member 27 (27') is formed of the metal plate constituting the protective member 27 (27 '). A gap between one end and the other end of both ends in the width direction is an opening 33 (33 ′). Therefore, the lubricating oil retaining member 29 (29 ′) is passed through an opening 33 (33 ′) from an oil supply passage (not shown) communicating with the through hole 23 (23 ′) in which the lubricating mechanism 25 (25 ′) is installed. ) Can be easily supplied with lubricating oil and grease.

  Further, since the adjusting members 31, 31 (31 ', 31') are disposed at both ends of the second rolling path 34 (34 '), the steel ball 37 (37') is returned to the return path 35a (35a). ′) The steel ball 37 (37 ′) is prevented from colliding with the lubricant holding member 29 at the entrance portions (both ends) of the lubricant holding member 29 (29 ′) immediately after the direction is changed by ′). it can. This also prevents deformation and damage of the lubricating oil retaining member 29 (29 '), and smooth rolling of the steel ball 37 (37'), and consequently smooth movement of the ball nut 13 and the slider 15. It can be maintained for a long time.

Next, a second embodiment of the present invention will be described with reference to FIG.
In the actuator 39 according to the present embodiment, as shown in FIG. 8, sleeves 41 (41 ′) are respectively installed on both ends of the lubrication mechanism 25 (25 ′). The sleeve 41 (41 ′) is made of hard resin.
It may be a metal such as steel.
The lubrication mechanism 25 (25 ′) and the return caps 35 and 35 (35 ′ and 35 ′) are connected via the sleeves 41 and 41 (41 ′ and 41 ′).

  As shown in FIG. 8, the sleeve 41 (41 ′) is formed with a through hole 42a (42a ′). The through hole 42a (42a ') has a large diameter portion 42b (42b') on the side opposite to the return cap 35 (35 ') (center side in FIG. 8). Both end sides of the lubrication mechanism 25 (25 ′) are engaged.

Further, an engagement convex portion 42c (42c ') is formed on the return cap 35 (35') side (upper side or lower side in FIG. 8) of the sleeve 41 (41 '). The return cap 35 (35 ') is engaged with the engaging convex portion 42c (42c').
The configuration of the actuator 39 other than the sleeve 41 (41 ') is the same as that of the actuator 1 according to the first embodiment described above. Omitted.

  In the actuator 39 according to the present embodiment, since the sleeve 41 (41 ′) is provided, the return cap 35 is attached with the sleeve 41 (41 ′) attached to both ends of the lubricating mechanism 25 (25 ′). If it is attached to (35 '), it is possible to prevent the adjustment member 31 (31') from falling off, thereby facilitating the attaching operation of the lubricating mechanism 25 (25 ').

  Also, the sleeve 41 (41 ') also has an inlet portion (both ends) of the lubricating oil retaining member 29 (29') immediately after the steel ball 37 (37 ') is turned by the return path 35a (35a'). Part), the steel ball 37 (37 ') can be prevented from colliding with the lubricating oil retaining member 29. This also prevents deformation and damage of the lubricating oil retaining member 29 (29 '), and smooth rolling of the steel ball 37 (37'), and consequently smooth movement of the ball nut 13 and the slider 15. It can be maintained for a long time.

Next, a third embodiment of the present invention will be described with reference to FIG.
As shown in FIG. 9, in the actuator 43 according to the present embodiment, a lubrication mechanism 45 (45 ′) is built in the through hole 23 (23 ′) of the slider 15, and this lubrication mechanism 45 (45 ′). Sleeves 41 (41 ′) are respectively installed on both end sides.
The lubrication mechanism 45 (45 ′) has substantially the same configuration as the lubrication mechanism 25 (25 ′) in the first and second embodiments described above, but the adjustment members 31, 31 (31 ′) , 31 '), and the lengths of the protective member 27 (27') and the lubricating oil retaining member 29 (29 ') (the vertical length in FIG. 9) are approximately the same.

The configuration of the actuator 43 other than the lubrication mechanism 45 (45 ′) is the same as the configuration of the actuator 39 according to the second embodiment described above. Is omitted.
In addition, regarding the same structure as the lubricating mechanism 25 (25 ′) in the first embodiment of the lubricating mechanism 45 (45 ′), the same parts are denoted by the same reference numerals and the description thereof is omitted. To do.

Also in the actuator 43 according to the present embodiment, by providing the sleeve 41 (41 ′), the attaching operation of the lubricating mechanism 45 (45 ′) is facilitated as in the case of the second embodiment. be able to.
Further, the sleeve 41 (41 ') causes the inlet portion (both ends) of the lubricating oil retaining member 29 (29') immediately after the steel ball 37 (37 ') is redirected by the return path 35a (35a'). Part), the steel ball 37 (37 ') can be prevented from colliding with the lubricating oil retaining member 29. This also prevents deformation and damage of the lubricating oil retaining member 29 (29 '), and smooth rolling of the steel ball 37 (37'), and consequently smooth movement of the ball nut 13 and the slider 15. It can be maintained for a long time.
Incidentally, in this embodiment, since the adjusting member 31 (31 ′) is not used, the dimension absorbing function between the protective member 27 (27 ′) and the lubricating oil retaining member 29 (29 ′) is provided. Although it cannot be provided, the configuration can be simplified.

Next, a fourth embodiment of the present invention will be described with reference to FIG.
As shown in FIG. 10, in the actuator 47 according to the present embodiment, a lubrication mechanism 49 (49 ′) is housed in the through hole 23 (23 ′) of the slider 15. The lubrication mechanism 49 (49 ') is composed of a protective member 27 (27') and a lubricating oil retaining member 29 (29 ') built in the protective member 27 (27'). Members such as the adjustment members 31, 31 (31 ', 31') in the embodiment and the second embodiment and the sleeve 41 (41 ') in the third embodiment are not installed.

  However, a cylindrical connecting portion 51 (51 ') protrudes and is formed on the lubrication mechanism 49 (49') side (lower side or upper side in FIG. 10) of the return caps 35 and 35 (35 ', 35'). ing. The connecting portion 51 (51 ′) is press-fitted into the protective member 27 (27 ′) of the lubrication mechanism 49 (49 ′), whereby the lubrication mechanism 49 (49 ′) and the return caps 35, 35 ( 35 ', 35'). Further, the inner peripheral surface 53 (53 ') of the connecting portion 51 (51') communicates with the return path 35a (35a ') of the return caps 35, 35 (35', 35 '). The return path 35a (35a ′) and the second rolling path 34 (34 ′) are communicated with each other through the connecting portion 51.

Also in the actuator 47 according to the present embodiment, the connecting portion 51 (51 ′) facilitates the mounting operation of the lubrication mechanism 49 (49 ′) as in the case of the second embodiment. Can do.
In addition, the connecting portion 51 (51 ′) has an inlet portion (29 ′) of the lubricating oil retaining member 29 (29 ′) immediately after the direction of the steel ball 37 (37 ′) is changed by the return path 35a (35a ′). It is possible to prevent the steel balls 37 (37 ′) from colliding with the lubricant holding member 29 at both ends. This also prevents deformation and damage of the lubricating oil retaining member 29 (29 '), and smooth rolling of the steel ball 37 (37'), and consequently smooth movement of the ball nut 13 and the slider 15. It can be maintained for a long time.

  Incidentally, in this embodiment, since the adjusting member 31 (31 ′) is not used, the dimension absorbing function between the protective member 27 (27 ′) and the lubricating oil retaining member 29 (29 ′) is provided. Although not provided, the connection 51 (51 ') formed integrally with the return caps 35, 35 (35', 35 ') can simplify the configuration.

Note that the present invention is not limited to the first to fourth embodiments described above.
For example, it can be considered that the protective member 27 (27 ′) itself is formed of a porous plate. Thereby, lubricating oil and grease can be easily supplied to the lubricating oil holding member inside.
It is also conceivable that the protective member 27 (27 ') is constituted by a pipe member formed by pultrusion molding, extrusion molding, or injection molding. In this case, by providing a through hole in such a pipe member, it is possible to easily supply the lubricating oil or grease to the lubricating oil holding member inside the pipe member.

Further, for example, the size of the opening 33 in the first embodiment is not particularly limited, and it is conceivable to provide a larger opening with respect to the illustrated one.
The protective member 27 (27 ') can be made of various materials as long as the material has high rigidity. For example, the protection member 27 (27 ′) may be made of other metals or resins.

Further, the adjustment member may be made of various materials as long as it is an elastic body. For example, a rubber material or a synthetic resin material may be used.
Further, by installing a cylindrical member instead of the adjustment member on both ends of the lubricating oil retaining member 29 (29 '), the direction of the steel ball 37 (37') is changed by the return path 35a (35a '). It is also conceivable to protect the lubricating oil holding member 29 (29 ') from the collision of the steel ball 37 (37') at the entrance portions (both ends) of the lubricating oil holding member 29 (29 ') immediately after. .
In addition, various cases are conceivable for the material, manufacturing method, and the like of the protective member, the lubricant holding member, and the adjustment member.
In addition, the present invention is not limited to the illustrated configuration, and various modifications can be considered.

  The present invention relates to an actuator used for, for example, an industrial robot, and in particular, facilitates the interior work of the lubricating oil holding member in the movable part of the actuator while reducing the processing cost, and also provides the lubricating oil holding member. For example, it is suitable for an actuator used in a food manufacturing robot, for example, in which the maintenance period is extended by preventing deformation and damage and lubricating oil is supplied to the rolling elements over a long period of time.

1 Actuator 3 Housing 15 Slider (Moving part)
18 1st rolling path 18 '1st rolling path 23 Through-hole 23' Through-hole 25 Lubrication mechanism 25 'Lubrication mechanism 27 Protection member 29 Lubricating oil holding member 31 Adjustment member 33 Opening 34 Second rolling path 34' First 2 Rolling path 35 Return cap 35 'Return cap 35a Return path 37 Steel ball (rolling element)
37 'Steel ball (rolling element)
39 Actuator 41 Sleeve 41 ′ Sleeve 43 Actuator 45 Lubrication Mechanism 45 ′ Lubrication Mechanism 47 Actuator 49 Lubrication Mechanism 49 ′ Lubrication Mechanism 51 Connection Portion 51 ′ Connection Portion

Claims (7)

A housing;
A movable part movably attached to the housing;
A first rolling path provided between the housing and the movable part;
A through hole provided in the movable part and providing a second rolling path;
A return cap that is attached to both ends of the movable portion in the traveling direction and includes a return path that communicates the first rolling path and the second rolling path;
A plurality of rolling elements mounted so as to be able to roll in the first rolling path, the second rolling path, and the return path;
A cylindrical lubricating oil holding member provided in the through hole and having the inner peripheral surface thereof as the second rolling path, and a cylindrical protective member provided on the outer periphery of the cylindrical lubricating oil holding member And a lubrication mechanism for supplying lubricating oil to the rolling elements,
Equipped with,
An opening is provided on the outer peripheral surface of the protective member,
The protective member is formed by bending a metal plate into a cylindrical shape,
The actuator is characterized in that the opening of the protective member is a gap between one end and the other end that are close to each other when the metal plate is bent . The actuator according to claim 1, wherein
An actuator, wherein a gap is provided between an inner peripheral surface of the through hole and an outer peripheral surface of the lubrication mechanism. The actuator according to claim 2, wherein
An actuator characterized in that both ends of the protection member are engaged with the return cap. A housing;
A movable part movably attached to the housing;
A first rolling path provided between the housing and the movable part;
A through hole provided in the movable part and providing a second rolling path;
A return cap that is attached to both ends of the movable portion in the traveling direction and includes a return path that communicates the first rolling path and the second rolling path;
A plurality of rolling elements mounted so as to be able to roll in the first rolling path, the second rolling path, and the return path;
A cylindrical lubricating oil holding member provided in the through hole and having the inner peripheral surface thereof as the second rolling path, and a cylindrical protective member provided on the outer periphery of the cylindrical lubricating oil holding member And a lubrication mechanism for supplying lubricating oil to the rolling elements,
Comprising
An adjustment member made of an elastic body is provided inside the protective member and on both ends of the lubricating oil holding member,
The second rolling way actuator, wherein the inner peripheral surface der Rukoto of the lubricating oil holding member and the adjustment member. The actuator according to claim 4, wherein
The actuator according to claim 1, wherein the adjustment member is a coil spring . The actuator according to claim 1 or 2 ,
Sleeves are provided at both ends of the lubrication mechanism,
The return cap and the lubricating mechanism actuator characterized that you have been connected through the sleeve. The actuator according to any one of claims 1 to 6,
The return cap has a protruding and formed connection,
The return cap and the lubricating mechanism actuator characterized that you have been connected via the connection portion.

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