JP3563875B2 - Linear roller guide - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a linear motion guide device, and more particularly to a linear roller guide device using rollers as rolling elements.
[0002]
[Prior art]
Conventional linear roller guide devices of this type generally have a configuration in which a moving block is movably supported on a track rail via a number of rollers. A guide device using a roller has advantages of higher rigidity and higher load-bearing capacity than a device using a ball. The moving block includes a block main body and side lids attached to both ends of the block main body.The block main body is provided with a roller rolling surface and a roller return passage for infinite circulation of the roller row, and the side lid has A direction change path is provided between the roller rolling surface side and the roller return path.
[0003]
Further, on both sides of the roller rolling surface of the block body, a roller end surface guide wall for guiding the roller end surface is provided, and a guide wall continuous with the roller end surface guide wall is also provided on the roller return passage and the direction change path. The end face is guided and circulated around the entire circumference.
[0004]
Conventionally, cost reduction as a resin molded product has been achieved for a roller return path, a side lid and a roller end face guide wall roller return path that do not require high rigidity.
[0005]
[Problems to be solved by the invention]
(1) Complicated manufacturing process
However, each of the above-mentioned resin molded portions is a molded product separately from the block main body, and requires a process of assembling each separately.
[0006]
(2) Poor circulation of roller rolling surface
Also, when assembled, steps occur at the connection between the roller return path and the direction change path, and at the connection between the roller rolling surface and the direction change path, which hinders smooth circulation of the rollers and causes noise and other problems. There is.
[0007]
(3) Poor circulation of roller end face
In particular, in the case of a roller, it is necessary to prevent skew of the roller (runout of the roller rotating shaft). To prevent skew, not only the load area of the roller rolling surface but also the direction change path and the roller return It is necessary to guide the roller end face over the entire circumference of the infinite circulation path to the no-load area of the path.
[0008]
FIG. 8A shows a state where the roller 100 changes its direction from the no-load area α of the passage to the load area β. When the direction of the roller 100 is changed, for example, as schematically shown in FIGS. 8B and 8C, when the roller 100 enters the load region β from the no-load region α in a skew state, one of the rollers 100 End 100a first collides with the roller rolling surface 101 in the load area, which hinders the smooth operation of the roller 100 and also causes an edge load on the end 100a of the roller 100 in the load area β. Occurs, the roller 100 and the roller rolling surface 101 are damaged, and the durability is deteriorated. Further, vibrations during rolling of the rollers and changes in rolling resistance are generated, and smooth movement is hindered.
[0009]
For this purpose, the roller end face has been conventionally guided by the roller end face guide walls on both sides of the roller rolling surface, the direction change path, and the passage wall of the roller return path. However, the discontinuous roller end face guide wall, the direction change path, and the roller return path are provided. Due to the method of connecting the passages, the rollers are caught by unevenness of the width accuracy of each passage or a step of the connecting portion, and the smooth circulation is also inhibited.
[0010]
SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems of the prior art, and an object thereof is to integrate at least one of a roller return passage, a roller end face guide wall, and a direction change portion with a block main body. An object of the present invention is to reduce the number of assembling steps and accurately position the block body at a predetermined position to ensure smooth rolling of the rollers.
[0011]
[Means for Solving the Problems]
In order to achieve the above object, according to the present invention, there is provided a track rail, and a moving block assembled to the track rail via a number of rollers.Is beforeRoller rolling surface on which the roller rollsAnd theBlock body having roller return passage corresponding to roller rolling surfaceAnd beforeInner perimeter of direction change path provided on both end faces of the block bodyAnd beforeA pair of roller end surface guide walls formed on both sides of the roller rolling surface of the block body to guide both end surfaces of the rollerAnd beforeA side cover having a direction change path outer peripheral portion that is fitted to the direction change path inner peripheral portions of both end surfaces of the block body to form a direction change path;Is beforeOf the block bodySaidA roller rolling surface corresponding to the roller rolling surface;Is beforeCorresponding block body and track railSaidLoad application area between roller rolling surfacesWhenThe turning path andSaidIn the roller return passageFormationBe doneNo load areaCirculates in an infinite circuitAndRoller return path forming member for forming the roller return pathAnd saidAt least one of a pair of roller end surface guide wallsForming rollerEnd guide wall forming memberForming the inner peripheral portion of the direction change pathDirection changing path inner circumference forming memberAnd beforeThe block body is inserted into the mold to form a molded body.StraightforwardLine roller guideIn the above, the roller return passage forming member, and the direction change path inner peripheral portion forming member have a guide wall that is continuous with the pair of roller end surface guide walls in order to guide the roller end surface, so that the load load region is formed. And a guide wall for guiding the roller end surface over the entire circumference of the infinite circulation path constituted by the load-free area.It is characterized by the following.
[0013]
According to the present invention,The roller end face guide wall, the roller return passage, or the inner peripheral portion of the direction change path can be formed at an accurate position with respect to the block body.
[0014]
The roller rolls from the start to the end of the roller rolling surface of the block body, rolls into the roller return path via the direction change path, moves through the roller return path, and then rolls through the direction change path at the other end. It is supplied to the starting end of the rolling surface.
[0016]
According to the present invention, the roller end face guide wall of the roller return passage and the direction change path in the no-load area and the roller end face guide wall formed along the roller rolling surface in the load area can be continuously formed. The end face of the roller is smoothly transferred without a step at the connecting portion over the entire circumference of the circulation path.
[0018]
Further, the gap between the guide wall and the roller end face can be formed with high precision over the entire circumference of the infinite circulation path, and the skew of the roller can be reliably prevented.
[0019]
Further, a chamfered portion is provided at at least one end of the roller, and an engagement protrusion for engaging the chamfered portion of the roller and preventing the roller from falling off is provided on a roller end surface guide wall integrally formed with the block body. Features.
[0020]
By providing the engagement protrusions on the roller end surface guide wall integrally formed with the block body in this manner, it is possible to accurately position the roller relative to the block body and prevent the rollers from falling off when the bearing block is removed from the track rail. This can be reliably prevented, and there is no danger of interference with the rollers during roller circulation.
[0021]
Two rows of rollers are provided between the upper surface of the track rail and the lower surface of the horizontal portion of the block body, and a total of four roller rows are provided between the left and right side surfaces of the track rail and the inner surface of the hanging portion of the block body.
[0022]
In this case, the contact angle between the upper surface of the track rail and the roller rolling surface of the roller interposed between the horizontal portion and the lower surface of the block body is approximately 90 degrees with respect to the horizontal, and the right and left side surfaces of the track rail and the hanging inner surface of the block body. It is preferable that the contact angle of the roller interposed between the roller and the roller rolling surface is inclined approximately 30 degrees obliquely downward with respect to the horizontal.
[0023]
In addition, a total of four rows of balls are provided between the left and right side surfaces of the track rail and the left and right hanging lower side inner surfaces of the block body, that is, two rows up and down.
[0024]
The upper roller of the two rows of upper and lower rollers is approximately 45 degrees obliquely upward from the track rail side toward the left and right hanging portion of the block body, and the lower roller is approximately 45 degrees diagonally downward with respect to the horizontal direction. The upper roller of the two upper and lower rows of rollers is inclined approximately 45 degrees obliquely downward from the track rail side toward the left and right hanging portion of the block body with respect to the horizontal direction. Is preferably inclined approximately 45 degrees diagonally upward.
[0025]
In particular, in insert molding, a block support portion corresponding to the roller rolling surface of the block body is provided on the inner periphery of the mold, and the block body is positioned in the mold by contacting the roller rolling surface with the block support portion. Is effective.
[0026]
With this configuration, two sets of roller rolling grooves on the left and right sides of the block main body come into contact with the block support portion of the mold. Therefore, the block main body is supported at four points by two sets of left and right block support parts so as to be sandwiched in the vertical and horizontal directions. There is no burring of the molding material between the block and the block support.
[0027]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, the present invention will be described based on the illustrated embodiments.
[0028]
[First Embodiment]
FIGS. 1 and 2 show a linear roller guide device according to a first embodiment of the present invention. The linear roller guide device 1 includes a track rail 2 and two rows on the upper surface side of the track rail 2. A moving block 4 is provided on the left and right side surfaces so as to be movably mounted via a total of four rows of rollers 3 one by one.
[0029]
The track rail 2 is a long member formed in a substantially rectangular cross-section, and has a tapered surface on the left and right side upper portions that gradually protrudes outward as it goes upward. The running surface 5 is provided left and right one by one. Further, the upper surface of the track rail 2 is a flat surface, and a total of two roller rolling surfaces 6 are provided at both left and right end portions.
[0030]
The moving block 4 includes a metal block main body 40 and side lids 11 attached to both end surfaces of the block main body 40.
[0031]
The block body 40 is a highly rigid block body having a U-shaped cross section, and a horizontal portion 41 facing the upper surface of the track rail 2 and a pair of right and left ends of the horizontal portion 41 hanging down from both right and left sides of the track rail 2. And the hanging parts 42, 42. On the lower surface of the horizontal portion 41, a pair of roller rolling surfaces 7, 7 corresponding to a pair of roller rolling surfaces 6, 6 formed on the upper surface of the track rail 2 are provided. Roller rolling surfaces 8, 8 corresponding to the roller rolling surfaces 5, 5 formed on the left and right side surfaces of the track rail 2 are provided one by one on the inner side surface of the rail.
[0032]
A large number of rollers 3 are interposed between the corresponding four sets of roller rolling surfaces 5, 8; 6, 7 provided on the opposing surfaces of the track rail 2 and the moving block 4, and the track rail 2 and the moving block 4 are provided. A roller row for applying a load acting therebetween is configured. A predetermined preload is applied to the roller 3. Although the roller 3 is a cylindrical roller, as shown in FIG. 3D, a barrel-shaped roller having an arc-shaped cross section in the axial direction may be used.
[0033]
Each roller 3 is in linear contact with the roller rolling surfaces 5, 8; 6, 7; however, a contact angle line L1 connecting the contact portions with the roller rolling surfaces 5, 8; The roller 3 interposed between the upper surface of the track rail 2 and the horizontal portion 41 of the block body 40 is set to approximately 90 ° with respect to a horizontal line H passing through the center of the roller 3, and the right and left side surfaces of the track rail 2 and the block body 40 The roller 3 interposed between the left and right hanging parts 42, 42 is inclined upward by a predetermined angle α toward the center of the track rail 2 with respect to a horizontal line H passing through the center of the roller 3, The upper and lower right and left corners 22, 22 of the track rail 2 are sandwiched between the two rows of rollers 3, 3 and the upper two rows of rollers 3, 3. In the illustrated example, α is set to approximately 30 °.
[0034]
The block main body 40 is provided with four roller return passages 9 for circulating and guiding the four rows of rollers 3. The roller return passage 9 linearly extends in parallel with each of the roller rolling surfaces 5 and 6 provided in the block body 40, and is provided two in the horizontal portion 41 and two in the left and right hanging portions 42. ing. The roller return passage 9 is formed by a roller return passage forming member 91 made of resin.
[0035]
The roller return passage forming member 91 is integrally joined to an inner periphery of a through hole 43 that penetrates the horizontal portion 41 and the hanging portion 42 of the block body 40 in the axial direction. The outer periphery of the roller return passage forming member 91 has a cylindrical shape conforming to the inner peripheral shape of the through hole 43, and a roller return passage 9 having a rectangular cross section through which the roller 3 is guided is formed on the inner periphery. The roller return passage 9 has a pair of non-load roller rolling surfaces 9a and 9b extending parallel to each other for guiding the cylindrical outer peripheral surface of the roller 3, and a pair of parallel non-load roller end surfaces for guiding the roller end surfaces. Walls 9c, 9c are provided. The space between the no-load roller rolling surfaces 9a and 9b is slightly larger than the roller diameter to the extent that a minute gap is formed between the roller 3 and the outer periphery of the roller 3, and the space between the no-load roller end surface guide walls 9c and 9c is The roller 3 is set to be slightly larger than the length of the roller 3 to such an extent that a minute gap is formed between the roller 3 and the end face, so that the roller 3 is smoothly transferred.
[0036]
FIG. 5 shows another configuration example of the roller return passage forming member 92 provided in the hanging portion 42 of the block body 40. That is, the roller return passage forming member 92 is integrally joined to the concave portion 44 provided at the lower end of the left and right hanging portion 42 of the block body 40. The roller return passage forming member 91 is integrally connected to the third load roller end face guide wall forming member 143 on the inner peripheral side of the hanging portion 42.
[0037]
In this case, only two through-holes 43 formed in the block body 40 are formed in the horizontal portion 41, and the manufacture is simplified.
[0038]
Further, as shown in FIGS. 1B, 1C and 2, both ends of the block body 40 are interposed between the track rail 2 and the load roller rolling surfaces 5, 8; 6, 7 of the block body 40. A side cover 11 that forms a direction change path 10 for changing the direction of the mounted roller 3 to the roller return path 9 is attached. The turning path 10 has a U-shaped pipe shape, and only the turning path outer peripheral portion 10a of the turning path 10 is formed on the side cover 11, and the turning path inner peripheral section 10b is provided at both ends of the block body 40. The direction changing path inner peripheral portion forming member 12 to be formed is integrally joined.
[0039]
The direction change path 10 is also rectangular in cross section, and is provided on both sides of the direction change path outer circumference and the inner peripheral portions 10a and 10b for guiding the cylindrical outer peripheral surface of the roller 3 and the direction change roller end face guide wall 10c for guiding the end face of the roller 3. , 10c, and the direction changing roller end surface guide wall 10c is formed on the direction changing path inner peripheral portion forming member 12 together with the direction changing path inner peripheral portion 10b. Then, the side cover 11 having the direction change path outer peripheral portion 10a is fitted to the end face of the block body 40 on which the direction change path inner peripheral portion 10b and the direction change end surface guide wall 10c are formed, thereby forming a U-shaped pipe. Is formed.
[0040]
Of course, the direction change roller end surface guide walls 10c, 10c may be provided on the side cover 11 together with the direction change path outer peripheral portion 10a, and one of them may be provided on the direction change path inner circumference forming member 12 side together with the direction change path inner peripheral portion 10b. And the other may be provided on the side lid 11 side together with the direction change path outer peripheral portion 10a. Further, the direction changing roller end surface guide wall 10c may be divided into two parts, an inner circumferential side and an outer circumferential side, and the outer circumferential side may be formed on the side cover 11 and the inner circumferential side may be formed on the direction changing path inner circumferential portion forming member 12. Good.
[0041]
As shown in FIG. 1A, the load roller end surface guide wall 13 for guiding the roller end surface of the load area along both sides of each of the four roller rolling surfaces 7, 8 is provided on the block body 40. Is provided. In order to form the load roller end surface guide wall 13, a concave corner between the first end surface guide wall forming member 141 integrally joined to the lower surface of the horizontal portion 41 and the horizontal portion 41 and the left and right hanging portions 42. The left and right second end surface guide wall forming members 142 are integrally joined to the portion, and the left and right third end surface guide wall forming members 143 are integrally joined to the left and right hanging portions 42 on the lower inner surface. ing.
[0042]
At both ends of the first end face guide wall forming member 141 and at the upper end of the second end face guide wall forming member 142, the end faces of the rollers 3 rolling on the roller rolling faces 7, 7 formed on the lower surface of the horizontal portion 41 of the block body 40. Roller end face guide walls 13, 13; Rollers for rolling the roller rolling surfaces 8, 8 formed in the hanging portion 42 of the block main body 40 at the lower ends of the left and right second end surface guide wall forming members 142 and the upper ends of the third end surface guide wall forming members 143. The load roller end surface guide walls 13, 13; 13, 13 for guiding the end surface of the load roller 3 are formed. The distance between the pair of load roller end face guide walls 13 is slightly larger than the length of the roller 3 so that a minute gap is formed between the pair of load roller end face guide walls 13 and 13.
[0043]
Further, the first sealing member 15 for sealing the gap between the horizontal portion 41 of the block body 40 and the upper surface of the track rail 2 is attached to the first end surface guide wall forming member 141, and the third end surface guide wall forming member 143 is attached to the third end surface guide wall forming member 143. The second seal member 16 that seals a gap between the hanging portion 42 of the block body 40 and the left and right side surfaces of the track rail 2 is mounted.
[0044]
In this embodiment, the load roller end face guide walls 13 for guiding both end faces of the roller 3 are all formed by first to third load roller end face guide wall forming members 141 to 143 made of resin. As shown in a), the load roller end surface guide wall 13 for guiding one end surface of the roller 3 is constituted by the block body 40 itself, and the other load roller end surface guide wall 13 is formed by a resin load roller end surface guide wall forming member 14. 3 (f), and both may be formed by the block body 40 itself.
[0045]
In the first embodiment, the roller return passage forming member 91, the roller end face guide wall forming members 141 to 143, and the turning path inner peripheral portion forming member 12 are all integrally formed with the moving block.
[0046]
Accordingly, the no-load roller rolling surfaces 9a and 9b of the roller return passage 9 and the inner and outer peripheral portions 10a and 10b of the direction changing path are integrally formed continuously, and further, the inner peripheral portion 10b of the direction changing path and the roller rolling in the load area are formed. The running surfaces 7, 8 are also integrally formed.
[0047]
Further, the roller end surface guide wall 9c of the roller return passage 9, the direction change roller end surface guide wall 10c of the direction change path 10, and the load area roller end surface guide walls 13 on both sides of the load roller rolling surfaces 7, 8 are continuously formed integrally. Therefore, the roller end surface guide wall is formed continuously over the entire circumference of the infinite circulation path.
[0048]
As described above, according to the linear roller guide device of the present invention, it is not necessary to assemble the load roller end surface guide wall forming member 14, the roller return passage forming member 91, or the turning path inner peripheral portion forming member 12, and the assembling process is omitted. be able to.
[0049]
In addition, the roller end surface guide wall 13, the roller return passage 9, or the inner peripheral portion 10b of the direction change path can be formed at an accurate position with respect to the block body 40.
[0050]
That is, the roller 3 rolls from the start end to the end of the roller rolling surfaces 7 and 8 in the load region of the block body 40, and then rolls and transfers to the roller return passage 9 via the direction change path 10 to form the roller return passage. After the roller 9 has been rolled, it is supplied to the starting ends of the roller rolling surfaces 7 and 8 through a direction change path 10 at the other end.
[0051]
By forming the direction changing path inner peripheral portion forming member 12 integrally with the block main body 40, a step at the connecting portion between the roller rolling surfaces 7, 8 and the direction changing path inner peripheral portion 10b can be eliminated. Further, if the roller return passage forming member 91 is also integrally formed with the block main body 40, the step at the connecting portion between the direction changing path inner peripheral guide portion 10b and the roller return passage 9 can be eliminated.
[0052]
The roller return passage forming member 91 and the direction changing path inner peripheral portion forming member 12 include a no-load roller end surface guiding wall 9c and a direction changing roller end surface guiding wall which guide the roller end surface continuously with the load roller end surface guiding wall 13. 10c, which are integrally formed with the block body 40, so that there is a step at the connecting portion between the load roller end surface guide wall 13, the direction changing roller end surface guide wall 10c and the no-load roller end surface guide wall 9c for guiding the roller end surface. The roller can be formed continuously over the entire circumference of the infinite circulation path without occurrence, and the roller end surface is smoothly transferred.
[0053]
Further, since the gaps between the load roller end face guide wall 13, the direction changing roller end face guide wall 10c, and the no-load roller end face guide wall 9c and the roller end face can be maintained with high precision, the gaps are made as small as possible. Thus, the skew of the roller 3 can be reliably prevented.
[0054]
Further, as shown in FIGS. 3B and 3C, at least one end of the roller 3 is provided with a chamfered portion 3a, and the moving block 4 is mounted on the guide rail 13 of the load roller end face integrally formed with the block body 40. An engagement projection 13a that engages with the chamfered portion 3a of the roller 3 when the roller 3 is removed from the roller 2 to prevent the roller 3 from falling off may be provided. The engagement protrusion 13a has a small gap between the roller 3 and the roller 3 so as not to interfere with the roller 3 when the roller 3 rolls between the roller rolling surfaces 6, 7; .
[0055]
By providing the engagement protrusion 13a on the roller end surface guide wall 13 integrally formed with the block body 40, the engagement protrusion 13a can be accurately positioned with respect to the block body 40. Since the gap between the roller 3 and the chamfered portion 3a can be accurately kept constant, there is no possibility that the engagement protrusion 13a interferes with the roller during roller circulation.
[0056]
When the roller return passage forming member 91, the direction changing path inner peripheral portion forming member 12, and the load roller end face guide wall forming member 13 are integrally formed with the block main body 40, the roller rolling surfaces 7, 8 provided on the block main body 40 are formed. The block body 40 is disposed in the mold 15 with reference to the mold, a cavity is formed between the inner wall of the mold 15 and the block body 40 corresponding to each resin molding portion to be molded, and a molding material is filled in the cavity. By insert molding.
[0057]
FIG. 4 is a schematic diagram showing a state in which the block body 40 and the mold 15 are closed and opened during insert molding. That is, the fixed die 15a is provided with a positioning block support portion 15b into which the roller rolling surfaces 7, 7; 8, 8 are fitted, and the movable die 15c is provided with a pin 15d for forming a roller return passage. Have been.
[0058]
The block supporting portions 15b have a flat shape corresponding to the roller rolling surfaces 7, 7, 8, 8, and extend linearly in parallel with each other. 4 (b) and 4 (c) show only the periphery of the roller return passage 9 on the hanging portion 42 side.
[0059]
A cavity 15 e for forming the roller return passage forming member 91 is formed in the through hole 43 of the horizontal portion 41 and the hanging portion 42 of the block body 40, and first to first holes are formed on the inner periphery of the horizontal portion 41 and the hanging portion 42. Cavities 15f to 15h for forming the three load roller end surface guide wall forming members 141 to 143 are provided, and cavities 15i for forming the direction changing path inner peripheral portion forming member 12 are provided at both front and rear ends of the block body 40, respectively. Have been.
[0060]
In the present embodiment, two sets of roller rolling surfaces 7, 7; 8, 8 on the left and right sides of the block body 40 are supported at four points by the block supporting portions 15b of the mold 15, so that No matter which direction the injection pressure of the molding material acts, it can be supported without play by the positioning block support portion 15b, and the roller return passage 9, the direction change passage inner peripheral portion 10b and the first to third loads can be provided. The roller end surface guide walls 131 to 133 can be accurately formed at predetermined positions.
[0061]
Further, since the block main body 40 is stably positioned in the mold 15, no burrs are generated on the roller rolling surfaces 7, 7, 8, 8.
[0062]
It is preferable that the block support portion 15b and the roller rolling surfaces 7 and 8 be in close contact with each other. However, even if the block supporting portion 15b slightly loosens, a slight gap is formed as long as the dimensional accuracy is within an allowable range and the resin material does not enter. There may be.
[0063]
[Modified example of roller contact angle]
The above description is based on the four rows of rollers, one in each of two rows between the upper surface of the track rail 2 and the lower surface of the horizontal portion 41 of the block body 40, and one row between the left and right side faces of the track rail 2 and the inner surface of the hanging part 42 of the block body 40. Although the case of having rows has been described as an example, the number and arrangement of roller rows are arbitrary. For example, as shown in FIGS. 6 and 7, a configuration may be employed in which a total of four roller rows, two upper and lower rows, are provided between the left and right side surfaces of the track rail 2 and the inner side surface of the left and right hanging portion 42 of the block body 40.
[0064]
In the example shown in FIG. 6, the upper roller 3 of the upper and lower two rows of rollers 3 has its contact angle line L1 directed in the horizontal direction H from the track rail 2 side toward the left and right hanging portion 42 of the block body 40. This is an example in which the roller 3 on the lower side is inclined approximately 45 degrees diagonally upward and the contact angle line L2 is inclined approximately 45 degrees diagonally downward.
[0065]
In the embodiment shown in FIG. 7, the upper roller 3 of the upper and lower two rows of rollers 3 has its contact angle line L1 directed horizontally from the track rail side to the left and right hanging parts 42, 42 of the block body 40. This is an example in which the contact angle line L2 of the lower roller 3 is inclined approximately 45 degrees diagonally downward and approximately 45 degrees diagonally upward.
[0066]
In the case of this embodiment, the direction change paths 10A and 10B of two rows of upper and lower balls formed at both ends of the block main body 40 are alternately crossed at intervals in the axial direction. In this case, the turning-path inner peripheral portion forming member 12 provided on the end face of the block main body 40 includes the turning-path inner peripheral portion 10b of the turning path 10A closer to the block main body 40 and the turning roller end face. Although the guide wall 10c is formed integrally with the block body 40, at least the load roller rolling surfaces 7, 8 and the roller return path on the end face side of the block body 40 are provided on the direction change path 10B farther from the block body 40. 9 is formed integrally with the block main body 40 at a portion connected to the end of the turning direction 9 and the direction changing roller end face guide wall 10c. The round piece 10C provided with the portion 10b is mounted. A part of the outer circumference guide portion of the inner turning path 10A is formed on the inner circumference of the round piece 10C. The side lid 11 is formed with outer peripheral portions 10a, 10a of both the upper and lower direction change paths 10A, 10B.
[0067]
【The invention's effect】
As described above, according to the present invention, there is no need to assemble the roller end surface guide wall, the roller return passage, or the inner peripheral portion of the direction change passage, and the assembling process can be omitted.
[0068]
Further, the roller end face guide wall, the roller return passage, or the inner peripheral portion of the direction change path can be formed at an accurate position with respect to the block body.
[0069]
Further, by forming the inner peripheral portion of the direction changing path integrally with the block body, it is possible to eliminate the step at the connecting portion between the roller rolling surface and the inner peripheral portion of the turning direction path. Further, if the roller return passage is also formed integrally with the block body, the step at the connection between the direction changing path inner peripheral guide portion and the roller return passage can be eliminated.
[0070]
The roller return passage and the inner peripheral portion of the direction change path have a guide wall that guides the roller end surface continuously with the roller end surface guide wall, and a roller return passage and at least one of the pair of roller end surface guide walls are provided. If all of the roller end face guide wall and the inner circumference of the direction change path are integrally formed with the block body, the roller return path, the guide wall of the inner circumference of the direction change path and the roller end face guide wall can be continuously formed. Therefore, the roller end surface is smoothly transferred without any step at the connection portion.
Further, the guide wall on the roller end face is extended over the entire circumference of the infinite circulation path.In other words, a pair of roller end surface guide walls of the block body in the load application area, and over all of the roller return path and the direction change path in the no load area,Since it can be formed continuously and integrally, the gap between the guide wall and the roller end face can be formed with high precision, and the skew of the roller can be reliably prevented.
[0072]
In addition, if an engaging protrusion that engages with the chamfered portion of the roller and prevents the roller from falling off is provided on the roller end surface guide wall that is integrally formed with the block main body, accurate positioning with respect to the block main body can be achieved. The roller can be reliably prevented from falling off when the bearing block is removed from the track rail, and there is no risk of interference with the roller during roller circulation.
[0073]
Further, in the insert molding, a block support portion having a cross section passing through the center axis of the roller corresponding to the roller rolling surface of the block body and following the shape of cutting the roller outer periphery is provided on the inner periphery of the mold, If the block main body is positioned in the mold by bringing the roller rolling surface into contact with the support portion, burrs do not occur on the roller rolling surface.
[0074]
In particular, if two sets of roller rolling surfaces on the left and right sides of the block body are supported by the block support portions of the mold, the block body is supported at four points by being sandwiched vertically and horizontally by the two sets of block support portions on the left and right sides. Even if the injection pressure of the molding material from the left and right acts, the positioning can be performed accurately without rattling.
[Brief description of the drawings]
FIG. 1 is a view showing a linear roller guide device according to a first embodiment of the present invention.
FIG. 2 is a diagram showing a first embodiment of the present invention.
FIG. 3 is a view showing various modified examples of a roller end surface guide wall and a roller holding structure of the linear roller guide device of FIG. 1;
FIG. 4 is an explanatory view showing a method of forming a moving block of the linear roller guide device of FIG. 1;
FIG. 5 is a view showing a modified example of the roller return passage forming member shown in FIG. 1;
FIG. 6 is a diagram showing another roller contact angle structure according to the first embodiment of the present invention.
FIGS. 7A and 7B show another roller contact angle structure according to the first embodiment of the present invention. FIG. 7A is a sectional view, and FIG. 7B is a sectional view of a turning path. is there.
FIG. 8 is an explanatory diagram of a state in which roller skew has occurred in a conventional linear roller guide device.
[Explanation of symbols]
1 Linear roller guide
2 Track rail
3 rollers
4 Moving block
40 block body
41 horizontal part
42 hanging part
5, 6 Roller rolling surface (track rail side)
7, 8 Roller rolling surface (moving block side)
9 Roller return path
9a, 9b No-load roller rolling surface
9c No-load roller end guide wall
91 Roller return path forming member
10 Turnaround road
10a Outer circumference of turning direction
10b Inner circumference of turning road
10c Guide wall for changing direction of roller
11 Side lid
12. Inner circumference forming member for turning direction
13 Load roller end face guide wall
14 Load roller end face guide wall forming member
15 Mold
15b Block support
16, 17 sealing member

Claims (8)

Comprising a track rail and a moving block assembled to the track rail via a number of rollers,
The movable block has a roller rolling surface of front Symbol roller is rolling, the roller and the block body having a roller return path corresponding to the rolling run surface, before SL direction changing passage inner provided on both end surfaces of the block body a peripheral portion, a pair of the roller end surface guide walls formed on both sides of the roller rolling surface of the front Symbol block body for guiding the end surfaces of the roller, is fitted in the direction changing passage inner peripheral portion of the front Symbol block body end faces A side cover having a direction change path outer peripheral portion to form a direction change path,
It said track rail has a roller rolling surface corresponding to the roller rolling run plane before Symbol block body,
The roller has a load-bearing area between the roller rolling surface of the front Symbol block body corresponding said track rail, endless circulation path consisting of the direction changing passage and the roller return load unloaded region formed in the passage Circulates ,
A roller return path forming member forming the roller return path, and the roller end surface guide wall forming member for forming at least one of the pair of the roller end surface guide wall, direction changing passage forming the direction changing passage inner periphery portion the inner peripheral portion forming member, in a straight line roller guidance apparatus integrally molded moldings by insert before Symbol block body type mold inside,
The roller return passage forming member, and the direction change path inner peripheral portion forming member have a guide wall that is continuous with the pair of roller end surface guide walls in order to guide the roller end surface. A linear roller guide device, comprising: a guide wall for guiding the roller end surface over the entire circumference of the infinite circulation path constituted by a load-free area . A chamfered portion is provided at at least one end of the roller, and an engagement protrusion for engaging the chamfered portion of the roller and preventing the roller from falling off is provided on the roller end surface guide wall forming member integrally formed with the block body. The linear roller guide device according to claim 1, wherein: 3. A roller row comprising a total of four roller rows, two rows each on the right and left sides between the upper surface of the track rail and the lower surface of the horizontal portion of the block body, and one row each between the right and left side faces of the track rail and the inner side surface of the hanging part of the block body. 4. The linear roller guide device according to 1. The contact angle between the roller rolling surface of the roller interposed between the upper surface of the track rail and the lower surface of the horizontal portion of the block body is approximately 90 degrees with respect to the horizontal, and is interposed between the left and right side surfaces of the track rail and the inner surface of the hanging portion of the block body. The linear roller guide device according to claim 3, wherein the contact angle of the roller with the roller rolling surface is inclined approximately 30 degrees obliquely downward with respect to the horizontal. The linear roller guide device according to claim 1 or 2, further comprising a total of four roller rows (two rows vertically) between the right and left side faces of the track rail and the inner side faces of the left and right hanging portions of the block body. The contact angle of the roller of the upper roller row with the roller rolling surface is approximately 45 degrees obliquely upward from the track rail side toward the left and right hanging part of the block body with respect to the horizontal direction, and the roller of the lower roller row is 6. The linear roller guide device according to claim 5, wherein a contact angle between the first roller and the roller rolling surface is inclined approximately 45 degrees obliquely downward with respect to the horizontal. The contact angle between the rollers of the upper roller row and the roller rolling surface is approximately 45 degrees obliquely downward from the track rail side toward the left and right hanging portion of the block body with respect to the horizontal direction, and the lower roller is oblique. The linear roller guide device according to claim 5, wherein the linear roller guide device is inclined approximately 45 degrees upward. At the time of insert molding, a block supporting portion having a cross section passing through the center axis of the roller corresponding to the roller rolling surface of the block body and following the shape of cutting the roller outer periphery is provided on the inner periphery of the mold, and the block supporting portion is provided. The linear roller guide device according to any one of claims 1 to 7, wherein the block main body is positioned in the mold by bringing a roller rolling surface into contact with the roller.

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