JPH0526236A - Sealing device for straight line motion mechanism - Google Patents

Abstract

PURPOSE:To prevent failure in lubrication in a sealing device of straight line motion of machine tool or the like by providing a pair of second rail members between the top surface of a guide rail and the opposite surface of a slider along the axial direction separated by the central area of the axial direction of the top surface of the guide rail, and providing a lubricant storage chamber between rolling grooves. CONSTITUTION:A lubricant supply passage 20 communicated with a space between the lower surface of a slider 7 and the top surface 4 of a guide rail 1 is provided to be communicated with an end rail (first seal member) 16 of each end plate 10 fitted to both axial end surfaces of the slider 7. A flat-shape plate 15 is provided between the lower surface 19 of the slider 7 and the top surface 4 of the guide rail 1, and bend parts 23 are formed in both side edges thereof to bond an upper inner seal 24. The tips 25 of the bend parts 23 are made to contact to the upper surface 4 of the guide rail 1 to form a first storage chamber 90 of the lubricant between the upper inner seal 24 and a second rolling groove 9, the first rolling groove 3.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION The present invention relates to a machine tool, a measuring device,
The present invention relates to a sealing device for a linear motion mechanism used in medical equipment and the like.

[0002]

2. Description of the Related Art FIG. 4 (A) shows a first conventional example of a linear movement mechanism (Actual Kaihei No. 1-82330). A first rolling groove 102 is provided on both side surfaces 101 of the guide rail 100, and a second rolling groove 104 facing the first rolling groove 102 is formed on the slider 103. The rolling element 105 is interposed between the first and second rolling grooves 102 and 104, and the slider 103 is axially movable on the guide rail 100.

Further, substantially U-shaped end seals 106 are provided at both axial ends of the slider 103. On the skirt portion 106a of the end seal 106, a seal projection 107 that is in sliding contact with the first rolling groove 102 is formed oppositely. On the other hand, the end seal 106 is the guide rail 1.
No. 110 is provided in the central region A of the upper surface 108 of No. 00, that is, at a portion corresponding to the insertion hole 109 of the fixing bolt, and the end seal 106 does not slide on the upper surface 108.

Further, on the inner surface 114 of the slider 103,
An upper seal 111 that is in sliding contact with the upper surface 108 is provided. The upper seal 111 is made of a rubber-like elastic body having a substantially rectangular cross section, and is directly baked and fixed to the inner surface 114. A nipple 118 for supplying a lubricant is provided on the end surface of the slider 103.

FIG. 4 (B) shows a second conventional example (actual opening flat 1
-82328). A plate 116 is fixed to the inner surface 114 of the slider 103 with a bolt 115, and an upper seal 117 is baked on the free end side of the plate 116. The upper seal 117 is made of a rubber-like elastic body having a substantially rectangular cross section.

In the first and second conventional examples having the above-described structure, the rolling element 105 rolls and the slider 103 moves on the guide rail 100 in the axial direction. Also,
The seal protrusion 107 prevents external chips and spatters from entering the first and second rolling grooves 102 and 104. Furthermore, the notch 110 does not slide on the upper surface 108,
It plays a role of preventing malfunction of the slider 103 due to sliding resistance and preventing wear of the end seal 106.

Therefore, chips, spatter, etc., which have entered between the guide rail 100, the upper surface 108 and the slider 103 through the notch 110, are sealed by the upper seals 111 and 117 which are in sliding contact with the upper surface 108 in the axial direction. Is
This prevents entry into the first and second rolling grooves 102, 104. In addition, the lubricant supplied from the nipple 118 to the upper surface 108 via a supply path (not shown) causes the first and second rolling grooves 102 and 104 and the rolling element 105 to move.
Lubricate the sliding surface with.

[0008]

However, the above-mentioned conventional example has the following problems. Upper seals 111 and 1 for both the first and second conventional examples
17 is the outermost side 101 of the upper surface 108 of the guide rail 100.
Since it is provided closer to the upper surface 108, the lubricant cannot be retained on the upper surface 108. Therefore, insufficient lubrication is likely to occur, the sliding surface may be seized or worn, and the slider 1
03 causes malfunction. In both the first and second conventional examples, when foreign matter enters the vicinity of the first rolling groove 102 and the second rolling groove 104 via the upper surface 108 side, the foreign matter is retained as it is, and therefore the rolling element 10
5 will be impaired and the slider 103 will malfunction. In the first conventional example, the upper seal 111 is attached to the slider 10
Since it is directly fixed to the lower surface 114 of the guide rail 1,
The elastic force of 00 on the upper surface 108 cannot be sufficiently obtained.
As a result, the sealing surface is deficient in contact surface pressure, resulting in deterioration of sealing performance. In the second conventional example, since the upper seal 117 is fixed to the free end of the plate 116, the elastic force to the upper surface 108 is easily obtained as compared with the first conventional example, but the plate 1
Since 16 is fixed to the slider 103, a satisfactory elastic force is not generated. Therefore, the sealing performance is also deteriorated. The second conventional example uses a bolt 115 to plate 116.
Since the fixed parts are fixed, the assembling work at the time of manufacturing becomes complicated and the manufacturing cost rises. In both the first and second conventional examples, the side surface 1 of the guide rail 100
The lubricant that has reached the gap between 01 and the slider 103 moves downward due to its own weight, so that the sliding surface is worn or seized due to poor lubrication, which causes malfunction of the slider 103.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a sealing device for a linear motion mechanism capable of retaining the supplied lubricant near the upper surface of the guide rail.

Another object of the present invention is to provide a sealing device having a linear motion mechanism capable of discharging foreign matter entering the vicinity of the first rolling groove and the second rolling groove to the outside.

Another object of the present invention is to provide a sealing device for a linear motion mechanism in which the elastic force of the first seal member with respect to the upper surface of the guide rail is improved.

Another object of the present invention is to provide a sealing device for a linear motion mechanism, which is easy to assemble at the time of manufacture and which can suppress an increase in cost.

Another object of the present invention is to provide a sealing device of a linear motion mechanism capable of retaining the supplied lubricant in the gap between the side surface of the guide rail and the slider.

[0014]

To achieve the above object, the present invention is directed to a guide rail having axially formed first rolling grooves on both side surfaces thereof, and a second rolling roller which opposes the first rolling grooves. A linear movement mechanism in which a slider having a groove is provided, and a large number of rolling elements are interposed between the first and second rolling grooves to hold the slider axially movably on a guide rail. A pair of first seal members for sealing between the guide rail and the slider are provided at both ends in the axial direction of, and between the upper surface of the guide rail and the surface of the slider facing the upper surface, By providing a pair of second seal members along the axial direction with a central region in the axial direction on the upper surface of the guide rail separated,
A first retaining chamber for the lubricant was formed between the second rolling grooves.

Further, the second seal member has a lip shape in which a tip on the guide rail side is inclined toward the central region.

Further, a pair of end plates is provided at both ends of the slider, a plate to which the second seal member is joined is provided between the pair of end plates, and both ends of the plate have a narrow elastic width. An insert portion was formed and the insert portion was fixed to the end plate.

Further, the slider and the guide rail are provided by providing a third seal member for axially sealing between the slider and both side surfaces of the guide rail below the first rolling groove and the slider. A second storage chamber for lubricant was formed between the two storage surfaces.

[0018]

The operation of the present invention based on the above construction is such that the first seal member seals between the upper surface and both side surfaces of the guide rail and the slider, while the upper surface of the guide rail and the first and second rolling grooves are formed. The second seal member seals the space. Then, the lubricant supplied near the upper surface of the guide rail is temporarily held in the first holding chamber and then reaches the first and second rolling groove sides.

The lubricant supplied into the first holding chamber is in a high pressure state. Then, the lubricant in the first holding chamber tries to push the first seal member to spread the tip of the guide rail on the upper surface side toward the central region side. As a result, the deteriorated lubricant is discharged to the central region side together with the foreign matter invading the vicinity of the first rolling groove and the second rolling groove.

The elastic force of the first seal member with respect to the upper surface of the guide rail is secured by the elastic force of the insertion portions at both ends of the plate.

Further, when the sealing device is manufactured, the assembling work of the first sealing member is completed only by fixing the insertion portions at both ends of the plate to the end plates.

The lubricant supplied between the side surface of the guide rail and the slider is retained in the second retaining chamber.

[0023]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Next, the present invention will be described with reference to the drawings. Figure 1
(A), (B), FIG. 2 and FIG. 3 (A) show the first embodiment. In the figure, reference numeral 1 is a guide rail having a predetermined axial length, and on both side surfaces 2 of the guide rail 1, first rolling grooves 3 having an arc-shaped cross section are formed vertically in two rows. is there. Further, in the widthwise central region B of the guide rail 1,
In order to insert a fixing bolt (not shown), a plurality of mounting holes 6 penetrating from the upper surface 4 to the lower surface 5 are provided at predetermined intervals along the axial direction. The upper surface 4 of the guide rail 1 is formed flat.

A slider 7 having a substantially U-shaped cross section is mounted on the guide rail 1. On both inner side surfaces 8 of the skirt portion 7a of the slider 7 facing the guide rail 1, two second rolling grooves 9 having an arc-shaped cross section are formed along the axial direction. Further, the end plate 1 having a cross-sectional shape substantially similar to the slider 7 is provided on both end surfaces of the slider 7 in the axial direction.
0 is attached.

The second rolling groove 9 is formed in an annular shape over the inside of the slider 7 and the end plate 10. Between the second rolling groove 9 and the first rolling groove 3, a large number of them are formed. A ball (steel ball or the like) 11 as a rolling element is interposed. With such a configuration, the slider 7 is movable on the guide rail 1 in the axial direction.

Further, on both axial end faces of the end plate 10, end seals (first seal members) 16 made of a rubber-like elastic body having a cross-sectional shape substantially similar to the end plate 10 are formed.
Is fixed. On the inner peripheral side of this end seal 16,
A lip portion 16a having a shape corresponding to the shape of the gap between the slider 7 and the guide rail 1 is provided.

Furthermore, the slider 7 is provided with a lubricant supply passage 20 communicating with the space between the lower surface 14 of the slider 7 and the upper surface 4 of the guide rail 1. This supply path 20 is connected to the end face of the end seal 16 by the grease nipple 2
It communicates with 1. Note that this supply path may be provided in the end plate 10.

The slider 7 is provided with a plate 12 for holding the balls 11, and is fixed to the lower surface of the slider 7 by bolts 13. Further, between the lower surface 19 of the slider 7 and the upper surface 4 of the guide rail 1, a planar plate 15 shown in FIG. 1B is provided along the axial direction. The plate 15 has a base portion 22 set to have a widthwise dimension equal to or larger than the opening diameter of the mounting hole 6, and a bent portion 23 formed by bending both side edges of the base portion 22 in the axial direction. Further, a pair of insertion portions 26a each having a narrow width and rich in elasticity are projected at both ends of the plate 15 in the axial direction. This insertion part 26
The a is fixed by being inserted into the insertion groove (not shown) of the end plate 10. The supply path 20 is the plate 1
The upper surface of No. 5 is located almost in the center.

Then, an upper inner seal 24 as a pair of second seal members is joined, that is, baked, to the outer surface of the bent portion 23 of the plate 15. The upper inner seal 24 is made of rubber-like elastic material (nitrile rubber, styrene rubber, butyl rubber, etc.), and the tips 25 on the upper surface 4 side of the guide rail 1 are directed toward each other, that is, toward the central region B side. It has a slanted lip shape. The tip 25 configured in this manner is used for the upper surface 4 of the guide rail 1.
With a predetermined contact surface pressure, they are axially contacted with each other to form a sealing surface. As a result, the first retaining chamber 90 for the lubricant is formed between the upper inner seal 24 and the second rolling groove 9 and the first rolling groove 3.

Next, the operation of the first embodiment will be described.
First, the slider 7 can be linearly reciprocated in the axial direction on the guide rail 1 by the rolling of the ball 11. Then, the tip 16a of the end seal 16 slides on the upper surface 4 and both side surfaces 2 of the guide rail 1 to form a first sealing surface, while the upper inner seal 24 slides on the upper surface 4 and ends seal 16 is formed. Forming a second sealing surface therebetween. Therefore, foreign matter (not shown) such as chips and spatters existing in the surroundings enters between the upper surface 4 of the guide rail 1 and the lower surface 19 of the slider 7 and both side surfaces 2 by the first sealing surface. The invasion into the inner surface 8 of the slider 7, that is, the first and second rolling grooves 3 and 9 is prevented.

Further, even if a foreign matter enters the space between the upper surface 4 and the lower surface 19 of the slider 7 from between the upper seal portion 17 and the upper surface 4, the second inner surface formed by the upper inner seal 24. Due to the presence of the sealing surface, the foreign matter is unlikely to enter the first and second rolling grooves 3 and 9 side through the upper surface 4. Therefore, good rolling of the ball 11 can be ensured, and stable linear movement of the slider 7 can always be obtained. Further, since the upper inner seal 24 is in sliding contact with the axial direction, the sliding resistance with the upper surface 4 is small and the abrasion is hard to occur.

During the above operation, the lubricant supplied from the grease nipple 21, that is, the grease is supplied in the supply path 2 as shown by the arrow.
0, passing through the upper surface of the plate 15 and temporarily holding the first holding chamber 90
Pending. Then, the grease in the first holding chamber 90 is supplied to the first and second rolling grooves 3, 9 side to lubricate the sliding surface. As described above, in the present invention, the supplied grease can be temporarily retained in the first retaining chamber 90, so that the sliding surface can be sufficiently lubricated. Therefore, seizure and wear do not occur, and the operability of the slider 7 can always be stably maintained.

Further, the grease supplied from the grease nipple 21 is supplied into the first holding chamber 90 via the supply passage 20 and becomes a high pressure state. Then, since the tip 25 of the upper inner seal 24 is inclined toward the central region B side, the tip 2
5 is expanded to the central region side B. As a result, if there is a foreign substance that has entered the vicinity of the first and second rolling grooves 3 and 9, this will be discharged to the central region B side together with the deteriorated grease. Therefore, the operability of the slider 7 can always be stably maintained.

Further, since the insertion portion 26a of the plate 15 having the upper inner seal 24 baked thereon is rich in elasticity,
A reaction force is generated when the tip end 25 is pressed against the upper surface 4 of the guide rail 1, and plays a role of improving the contact surface pressure of the upper inner seal 24 against the upper surface 4. Therefore, there is an effect that the sealing property of the upper inner seal 24 is improved.

FIG. 3B shows the second embodiment. In the second embodiment, the upper inner seal 24 is baked on the inner surface of the bent portion 23 of the plate 15. Furthermore, plate 1
A lower inner seal 26 as a third seal member is baked on the side surface of 2 along the axial direction. The lower inner seal 26 is made of the same elastic material as the upper inner seal 25, and has a lip shape in which the tip 27 is inclined downward. The tip 27 contacts the side surface 2 of the guide rail 1 below the second rolling groove 3 with a predetermined contact surface pressure to form a third sealing surface.
Others are similar to those of the first embodiment.

In this way, the upper inner seal 24,
With the lower inner seal 26, the side surface 2 of the guide rail 1
A second holding chamber 28 for grease is provided between the slider 7 and the inner surface 8 of the slider 7.
Is formed. That is, the grease supplied to the sliding surfaces between the balls 11 and the first and second rolling grooves 3 and 9 does not easily leak downward due to the presence of the lower inner seal 26 due to its own weight, and the second holding chamber for a long time. 28, the sliding surface can be lubricated efficiently without waste. Therefore, seizure and wear of the sliding surface can be prevented, and stable linear motion can be maintained.

Although balls are shown as rolling elements in the illustrated embodiment, it goes without saying that they may be rollers.

[0038]

Since the present invention is constructed as described above, the supplied lubricant is temporarily held in the first holding chamber, and then the first holding chamber is moved to the first and second rolling groove sides. To lubricate the sliding surface. Therefore, the seizure of the sliding surface,
There is an effect that the operability of the slider can always be stably maintained without wear.

Further, the foreign matter having entered the first and second rolling grooves and the vicinity thereof will be discharged to the central region side together with the deteriorated lubricant. Therefore, the operability of the slider can always be stably maintained.

Furthermore, the insertion portion of the plate plays a role of improving the contact surface pressure of the second seal member against the upper surface of the guide rail. Therefore, there is an effect that the sealing performance of the second seal member is improved.

Furthermore, the grease supplied between the side surface of the guide rail and the slider is held in the second holding chamber, and the sliding surface can be efficiently lubricated without waste. Therefore, seizure and wear of the sliding surface can be prevented, and stable linear motion can be maintained.

[Brief description of drawings]

FIG. 1A is an enlarged cross-sectional view showing a main part of a first embodiment,
FIG. 3B is a plan view showing the plate of the first embodiment.

FIG. 2 is a partially cutaway front view of the first embodiment.

FIG. 3A is a cross-sectional view taken along line XX of FIG.
FIG. 6B is a half sectional view showing the second embodiment.

FIG. 4A is a partially cutaway front view showing a first conventional example,
FIG. 7B is a partially cutaway front view showing a second conventional example.

[Explanation of symbols]

1 Guide rail 2 Side of guide rail 3 First rolling groove 4 Top surface of guide rail 7 slider 9 Second rolling groove 11 balls (rolling elements) 15 plates 16 End seal (first seal member) 24 Upper inner seal (second seal member) 26 Lower inner seal (third seal member) 26a insertion part 90 First Reservation Room 28 Second Reservation Room

Claims (4)

[Claims] 1. A guide rail having axially formed first rolling grooves formed on both side surfaces thereof, and a slider having a second rolling groove facing the first rolling groove. In a linear movement mechanism in which a slider is axially movably held on a guide rail by interposing a number of rolling elements between rolling grooves, the guide rail and the slider are provided at both ends in the axial direction of the slider. A pair of first seal members are provided to seal the space between the guide rails, and the upper surface of the guide rail and the surface of the slider facing the upper surface are separated from each other by an axial center region of the upper surface of the guide rail. A linear motion mechanism sealing device in which a first retaining chamber for a lubricant is formed between the second sealing member and the first and second rolling grooves by providing a pair of second sealing members along the direction. 2. The sealing device for a linear motion mechanism according to claim 1, wherein the second seal member has a lip shape in which a tip on the guide rail side is inclined toward the central region. 3. A pair of end plates are provided at both ends of the slider, a plate to which the second seal member is joined is provided between the pair of end plates, and both ends of the plate have a narrow elastic width. The sealing device for a linear motion mechanism according to claim 1 or 2, wherein an insertion portion is formed and the insertion portion is fixed to the end plate. 4. The slider and the guide rail are provided by providing the slider with a third seal member that axially seals between the slider and both side surfaces of the guide rail below the first rolling groove and the slider. The linear motion mechanism sealing device according to any one of claims 1 to 3, wherein a second retaining chamber for the lubricant is formed between the two side surfaces of the sealing device.