KR102652379B1 - Linear transmission device and its components - Google Patents

Abstract

A linear power transmission device and assembly thereof, the linear power transmission device including a screw, nut, end cap and scraping plate. The screw includes a helical external groove installed on the outer ring surface of the screw. The nut includes a barrel portion and a spiral inner groove, the barrel portion is installed to cover the screw, the spiral inner groove is installed on the inner ring surface of the barrel portion, and the spiral inner groove and the spiral outer groove correspond to each other to form a ball groove. The end cap is fixed to the nut, the first surface and the second surface of the end cap are opposing surfaces, the perforation portion passes through the first surface and the second surface and corresponds to the barrel portion, and the buckle groove is provided on the first surface. It also has a taper section and an accommodation section. The scraping plate is assembled and installed on the end cap, the third and fourth surfaces of the scraping plate are opposing surfaces, the through hole penetrates the third and fourth surfaces and corresponds to the barrel portion, and the buckle member is the fourth surface. Installed on the surface and in the buckle groove, the buckle member has a neck section and a protruding section.

Description

Linear power transmission devices and assemblies thereof {LINEAR TRANSMISSION DEVICE AND ITS COMPONENTS}

It relates to linear power transmission devices, and in particular to ball screw devices and their assemblies.

Generally, when the end cap and scraping plate of a ball screw are a two-piece assembly, alignment and assembly are required during the manufacturing process. If the alignment and assembly method is too cumbersome, additional manpower consumption and assembly time costs are incurred, and the end cap and The cost of implementing automated assembly between scraping plates also increases. Therefore, how to design end caps and scraping plates that can be quickly aligned and assembled, as well as applied to the production process of high-speed automated assembly, is a challenge for the industry.

In consideration of this, according to one embodiment, a linear power transmission device is provided including a screw, a nut, an end cap, and a scraping plate. The screw includes a helical external groove installed on the outer ring surface of the screw. The nut includes a barrel portion and a spiral inner groove, the barrel portion is installed to cover the screw, the spiral inner groove is installed on the inner ring surface of the barrel portion, and the spiral inner groove and the spiral outer groove correspond to each other to form a ball groove. The end cap is secured to the nut, the end cap includes a first surface, a second surface, a perforation, at least one buckle groove and a circulator, the first surface and the second surface are opposing surfaces, and the second surface is facing the nut, the perforation portion passes through the first surface and the second surface and corresponds to the barrel portion, and at least one buckle groove is provided on the first surface and also has a tapered section and a receiving section, the tapered section being provided in the first surface. It corresponds to the surface, the receiving section is connected to the tapered section, the circulator extends in the axial direction from the periphery of the second surface side perforation and is installed through the barrel of the nut, the circulator has a circulation groove, and the circulator has a circulation groove. The groove is connected to the ball groove. The scraping plate is assembled and installed on the end cap and includes a third surface, a fourth surface, an aperture, at least one buckle member and a scraping blade, the fourth surface facing the first surface of the end cap, the third surface and the fourth surface are opposing surfaces, the through hole penetrates the third surface and the fourth surface and corresponds to the barrel portion, and at least one buckle member is installed on the fourth surface and corresponds to at least one buckle groove. installed, the at least one buckle member has a neck section and a protruding section, the neck section is connected to the fourth surface, the protruding section is connected to the neck section, and the scraping blade is installed on the periphery of the through hole and has a spiral outer portion. It is assembled and installed correspondingly to the groove. The neck section is accommodated in the tapered section, and the protruding section is accommodated in the receiving section.

In some embodiments, at least one buckle groove surrounds the perforation to form a ring-shaped groove, at least one buckle member surrounds the perforation and protrudes from the fourth surface to form a ring-shaped wall, and the ring-shaped wall is installed in the ring-shaped groove. do.

In some embodiments, the ring-shaped groove and the perforation communicate with each other, a scraping section is installed on the ring-shaped wall on the inner surface facing the spiral outer groove, and the scraping section is assembled and installed to correspond to the spiral outer groove.

In some embodiments, the at least one buckle groove is a plurality of buckle grooves, each buckle groove is installed roundly on the first surface about the perforation, and the at least one buckle member is a plurality of buckle members, each buckle groove The buckle member is installed roundly on the fourth surface around the through hole.

In some embodiments, the tapered section has a first end and a second end, the first end and the second end being opposite ends, the first end corresponding to the first surface, and the receiving section being connected to the second end. , the width of the taper section gradually decreases from the first stage to the second stage.

In some embodiments, the width of the neck section gradually decreases in the direction of the protruding section from the fourth surface.

In some embodiments, the protruding section is a spherical joint or a rectangular joint.

According to one embodiment, a linear power transmission assembly including an end cap and a scraping plate is provided. The end cap includes a first surface, a second surface, a perforation, at least one buckle groove, and a circulator, the first surface and the second surface being opposing surfaces, and the perforation penetrating the first surface and the second surface. and the at least one buckle groove is installed on the first surface and has a tapered section and a receiving section, the tapered section corresponds to the first surface, the receiving section is connected to the tapered section, and the circulator is disposed on the second surface side. Extending axially from the periphery of the perforated portion, the circulator has a circulation groove. The scraping plate is assembled and installed on the end cap and includes a third surface, a fourth surface, an aperture, at least one buckle member and a scraping blade, the fourth surface facing the first surface of the end cap, the third surface and The fourth surface is an opposing surface, the through hole penetrates the third surface and the fourth surface, at least one buckle member is installed on the fourth surface and is installed corresponding to at least one buckle groove, and at least one buckle member is installed on the fourth surface and corresponds to at least one buckle groove. The buckle member has a neck section and a protruding section, the neck section is connected to the fourth surface, the protruding section is connected to the neck section, and a scraping blade is installed on the periphery of the through hole. The neck section is accommodated in the tapered section, and the protruding section is accommodated in the receiving section.

In summary, the linear power transmission device and linear power transmission assembly allow users to quickly assemble the scraping plate to the end cap through the buckle members and buckle grooves arranged correspondingly to each other, thereby achieving a quick and easy assembly effect, eliminating the cumbersome assembly process. and manpower consumption can be reduced and an automated assembly process can be implemented.

1 is a perspective view of a linear power transmission device according to a first embodiment.
Figure 2 is an exploded view of a linear power transmission device according to the first embodiment.
Figure 3 is a cross-sectional view taken along line 3-3 in Figure 1.
Figure 4 is a cross-sectional view taken along line 4-4 in Figure 2.
Figure 5 is a schematic diagram of the assembly of a scraping plate and an end cap according to the second embodiment.
Figure 6 is a cross-sectional view taken along line 6-6 in Figure 5.
Figure 7 is a schematic diagram of the assembly of a scraping plate and an end cap according to the third embodiment.
Figure 8 is a cross-sectional view taken along line 8-8 in Figure 7.
Figure 9 is a three-dimensional schematic diagram of a scraping plate according to the fourth embodiment.
Figure 10 is a three-dimensional schematic diagram of a scraping plate according to the fifth embodiment.
11 is a schematic diagram of a linear power transmission assembly according to one embodiment.

Referring to FIGS. 1, 2, and 3, FIG. 1 is a perspective view of a linear power transmission device according to a first embodiment, FIG. 2 is an exploded view of a linear power transmission device according to a first embodiment, and FIG. 3 is a drawing. This is a cross-sectional view cut along line 3-3 in 1. 1 and 2, the linear power transmission device 100 includes a screw 10, a nut 30, an end cap 50, and a scraping plate 70. Here, the linear power transmission device 100 is, for example, a ball screw device. In another embodiment, the end cap and scraping plate may be a group of linear power train assemblies cooperating with linear power trains of different specifications and models, the specific structure of the linear power train assembly is described in detail below.

As shown in Figure 3, the screw 10 includes a spiral outer groove 12 provided on the outer ring surface 11 of the screw 10. In the first embodiment, the spiral outer groove 12 is installed roundly at the required pitch on the outer ring surface 11 along the axial direction of the screw 10.

As shown in Figures 2 and 3, the nut 30 includes a barrel portion 33 and a spiral internal groove 32. The barrel portion 33 is installed to cover the screw 10, and the spiral inner groove 32 is installed on the inner ring surface 31 of the barrel portion 33, and the spiral inner groove 32 and the spiral outer groove 12 correspond to each other to form the ball groove 40. In the first embodiment, the spiral inner groove 32 is recessed in the inner ring surface 31 and rounded at a required pitch along the axial direction of the nut 30. In addition, the helical inner groove 32 of the nut 30 and the helical outer groove 12 of the screw 10 correspond to each other in position to form a ball groove 40 together. The ball groove is used to accommodate and install a plurality of balls and to circulate the balls. The nut 30 and the screw 10 are in rollable contact through a plurality of balls, and also enable the nut 30 and the screw 10 to move relative to each other in the axial direction, and at the same time create frictional force during relative movement. Reduce the driving torque by reducing .

The nut 30 can be formed by processing a metal block or column-shaped blank, and the processing method may be, for example, casting or forging. In addition, in order to add or drill holes such as flange holes, oil injection holes, return holes, etc. during the manufacturing process, or to change the appearance of the nut 30, the nut 30 may be additionally processed (e.g. , grinding or turning milling), and surface heat treatment may be performed on the nut 30 to strengthen the hardness of the nut 30, but the present invention is not limited thereto.

2 and 3, the end cap 50 is secured to the nut 30, and the end cap 50 has a first surface 51, a second surface 52, and a perforation 53. , includes at least one buckle groove 54 and a circulator 55. The first surface 51 and the second surface 52 are opposing surfaces. The second surface 52 faces the nut 30 . The perforation 53 passes through the first surface 51 and the second surface 52 and corresponds to the barrel portion 33. At least one buckle groove 54 is installed in the first surface 51 and also has a tapered section 541 and a receiving section 542. In the first embodiment, the case where three buckle grooves 54 are installed is described as an example, but in other embodiments, only one buckle groove 54 may be installed, or a plurality of buckle grooves 54 may be installed depending on the required number. there is. Referring to FIG. 4, FIG. 4 is a cross-sectional view taken along line 4-4 in FIG. 2. From Figure 4, it can be seen that the tapered section 541 corresponds to the first surface 51, and the receiving section 542 is connected to the tapered section 541.

The circulator 55 extends axially from the periphery of the perforated portion 53 on the second surface 52 side and is installed penetrating the barrel portion 33 of the nut 30, and the circulator 55 has a circulation groove ( 551), and the circulation groove 551 communicates with the ball groove 40. First of all, it should be explained that in the first embodiment, two end caps 50 having the same structure are installed on opposite ends of the nut 30, and in FIGS. 1, 2, and 3, a set of end caps Only (50) will be exemplified and the structure of one end cap (50) will be described in detail. However, this embodiment is only an example, and the structures of the two end caps 50 may be different, and this is not limited here. In the first embodiment, the circulation groove 551 communicates with the ball groove 40 formed by the spiral inner groove 32 and the spiral outer groove 12, so that the nut 30 and the screw 10 are relatively When exercising, a plurality of balls are rotated through the circulation groove 551 of the circulator 55 and can continuously circulate, return, and roll within the ball groove 40.

As shown in Figures 2 and 3, the scraping plate 70 is assembled and installed on the end cap 50, and the scraping plate 70 has a third surface 71, a fourth surface 72, and a hole ( 73), including at least one buckle member 74 and a scraping blade 75. The third surface 71 and the fourth surface 72 are opposing surfaces, and the through hole 73 passes through the third surface 71 and the fourth surface 72 and corresponds to the barrel portion 33. At least one buckle member 74 is installed on the fourth surface 72 and corresponding to the at least one buckle groove 54, and at least one buckle member 74 is installed in the neck section 741 and the protruding section. (742) is provided. In the first embodiment, the case in which the number of buckle members 74 corresponding to the number of buckle grooves 54 are installed is described as an example, so in this embodiment, three buckle members 74 are provided. As shown in Figure 4, the neck section 741 is connected to the fourth surface 72, the protruding section 742 is connected to the neck section 741, and the scraping blade 75 is connected to the through hole 73. It is installed on the periphery of and is assembled and installed corresponding to the spiral external groove 12.

In the first embodiment, the scraping blade 75 is located within the aperture 73 and is sandwiched between the third surface 71 and the fourth surface 72. That is, the scraping blade 75 is formed integrally within the thickness of the scraping plate 70 (i.e., the thickness formed between the third surface 71 and the fourth surface 72), and the scraping blade 75 is a screw It extends further into the spiral outer groove 12 of (10). When the screw 10 and the nut 30 move relatively, the scraping blade 75 can scrape foreign substances such as debris, debris, or dust within the spiral outer groove 12, and provides dust-proofing and oil-sealing effects at the same time. Thus, it is possible to ensure that a plurality of balls move smoothly within the ball groove 40. In addition, in the first embodiment, the thickness of the scraping blade 75 is smaller than the thickness of the scraping plate 70, and the scraping blade 75 is a crescent-shaped sheet body, but is not limited thereto, and the scraping blade 75 is It may be a sheet body of a different shape. In the first embodiment, the end cap 50 and the scraping plate 70 may be manufactured and molded as one piece through processing methods such as injection molding, casting, or milling, for example.

In the first embodiment, when the scraping plate 70 is assembled and installed on the end cap 50, the fourth surface 72 of the scraping plate 70 faces the first surface 51 of the end cap 50. , at least one buckle member 74 is buckled in at least one buckle groove 54, the neck section 741 is received in the tapered section 541, and the protruding section 742 is accommodated in the receiving section 542. It is accepted. In a first embodiment, the end cap 50 and scraping plate 70 are made of a soft material such as plastic or soft metal. The buckle groove 54 of the end cap 50 and the buckle member 74 of the scraping plate 70 are installed to correspond to each other. When the user buckles the buckle member 74 to the buckle groove 54, the protruding section 742 comes into contact with the tapered section 541 and the tapered section 541 is elastically deformed and slightly expanded, or the protruding section 742 Since this is slightly compressed and elastically deformed, the protruding section 742 can enter the receiving section 542. After the protruding section 742 is accommodated in the receiving section 542, the tapered section 541 is restored to the shape of the neck section 741 of the corresponding buckle member 74 by elasticity, and the protruding section 742 is also elastic. The shape of the receiving section 542 of the corresponding buckle groove 54 is restored by . The buckle member 74 and the buckle groove 54 may have various embodiments, for example, in the first embodiment, the plurality of buckle members 74 and the plurality of buckle grooves 54 are arranged to correspond to each other. , In addition, the buckle member 74 and the buckle groove 54 may be installed one by one and arranged to correspond to each other, and the detailed related structures will be described later.

Specifically, the linear power transmission device 100 is quickly aligned during assembly through the buckle members 74 and buckle grooves 54 arranged to correspond to each other, and then the scraping plate 70 is assembled to the end cap 50. By doing so, a quick and easy assembly effect can be achieved, reducing the cumbersome assembly process and manpower consumption, and realizing high-speed automated assembly.

As shown in Figures 2 and 4, in the first embodiment, each buckle groove 54 is installed roundly on the first surface 51 with the perforation portion 53 as the center, and each buckle member ( 74) is installed in a round shape on the fourth surface 72 with the through hole 73 as the center. That is, each buckle groove 54 surrounds the perforation 53 and is arranged on the first surface 51, and each buckle member 74 surrounds the perforation 73 and is arranged on the fourth surface 72. Each buckle groove 54 and each buckle member 74 correspond to each other.

In the first embodiment, as shown in FIG. 4, the tapered section 541 has a first end 5411 and a second end 5412, and the first end 5411 and the second end 5412 are opposite ends. The first end 5411 corresponds to the first surface 51, the receiving section 542 is connected to the second end 5412, and the width of the tapered section 541 extends from the first end 5411 to the second end 5412. It gradually decreases to stage 5412. The width of the neck section 741 gradually decreases from the fourth surface 72 toward the protruding section 742. Specifically, when the user buckles the buckle member 74 to the buckle groove 54, the protruding section 742 extends from the first end 5411 having a large width through the tapered section 541 to the tapered section 541. ), and then the user applies force so that the protruding section 742 enters the receiving section 542 from the second stage 5412 having a small width, thereby dividing the protruding section 742 into the tapered section 541. By coming into contact with, the tapered section 541 is elastically deformed and expanded, thereby allowing the protruding section 742 to enter the receiving section 542. After the protruding section 742 enters the receiving section 542, the tapered section 541 is restored by elasticity, so that the protruding section 742 and the neck section 741 become the receiving section 542 and the tapered section 541, respectively. ) is accepted. As shown in FIG. 4, in the first embodiment, the shapes of the tapered section 541 and the neck section 741 are substantially the same. Specifically, by having a corresponding shape, the buckle member 74 is accommodated in the buckle groove 54 to prevent instability after assembly due to a gap between the buckle member 74 and the buckle groove 54. In the first embodiment, as shown in FIG. 4, the structure in which the receiving section 542 communicates with the second surface 52 allows easy processing, for example, during injection molding, casting, or milling. In other embodiments, the shapes of the receiving section 542 and the protruding section 742 are generally the same.

In the first embodiment, the protruding section 742 is, for example, a spherical joint or a rectangular joint, and although a spherical joint is illustrated in Figure 4, it is not limited thereto. Although not shown in the drawing, in another embodiment, the protruding section 742 protrudes from the neck section 741 in the direction of the through hole 73 to form a claw portion, that is, when the user places the buckle member 74 in the buckle groove ( When buckling 54), the user applies force so that the claw portion contacts the wall of the tapered section 541 and is elastically deformed. After the claw part enters the receiving section 542, the claw part is restored by elasticity and buckled to the receiving section 542. Here, the protruding direction of the claw portion is not limited to the direction toward the through hole 73, and may protrude in a direction opposite to the direction toward the through hole 73.

Referring to Figures 5 and 6, Figure 5 is a schematic diagram of the assembly of a scraping plate and an end cap according to the second embodiment, and Figure 6 is a cross-sectional view taken along line 6-6 in Figure 5. In the second embodiment, the buckle member and the buckle groove are, for example, each installed one by one and arranged to correspond to each other. In the second embodiment, the same structure as the first embodiment will not be redundantly described. In the second embodiment, the buckle groove is a ring-shaped groove 54', which surrounds the perforation 53' and forms a first surface 51'. The buckle member is a ring-shaped wall 74', the ring-shaped wall 74' has a neck section 741' and a protruding section 742', and the neck section 741' is connected to the fourth surface 72'. And the protruding section 742' is connected to the neck section 741'. Then, a ring-shaped wall 74' is formed on the fourth surface 72' surrounding the aperture 73', and the ring-shaped wall 74' is disposed within the ring-shaped groove 54'. The user achieves a quick and easy assembly effect by buckling the ring-shaped wall 74' into the ring-shaped groove 54'.

Referring again to Figure 6, in the second embodiment, the ring-shaped wall 74' further includes a plurality of notches 743'. Each notch 743' is installed roundly on the ring-shaped wall 74' around the through-hole 73', and divides the ring-shaped wall 74' to form a plurality of active areas 744'. Specifically, when the user buckles the ring-shaped wall 74' into the ring-shaped groove 54', the protruding section 742' comes into contact with the tapered section 541' and the tapered section 541' is elastically deformed, The protruding section 742' enters the receiving section 542'. After the protruding section 742' enters the receiving section 542', the tapered section 541' is restored by elasticity, and the protruding section 742' is buckled to the receiving section 542'. When dividing into a plurality of active areas 744' through a plurality of notches 743' and assembling the scraping plate 70' and the end cap 50', the user must first cut a portion of the protruding section 742'. After buckling the receiving section 542', another portion of the protruding section 742' can be buckled to the receiving section 542'. That is, the plurality of notches 743' divide the protruding section 742' into a plurality of parts each having an active area 744', and the active area 744' is formed by deforming and bending the protruding section 742'. By allowing the protruding section 742' to enter the receiving section 542', the degree of freedom is improved so that the scraping plate 70' can be more easily buckled to the end cap 50'.

Referring to Figures 7 and 8, Figure 7 is a schematic diagram of the assembly of the scraping plate 70'' and the end cap 50'' according to the third embodiment, and Figure 8 is along line 8-8 in Figure 7. This is a cut cross-sectional view. In the third embodiment, the buckle groove is a ring-shaped groove 54'', and the ring-shaped groove 54'' surrounds the perforation 53'' and forms a first surface 51''. The buckle member is a ring-shaped wall 74'', the ring-shaped wall 74'' has a neck section 741'' and a protruding section 742'', and the neck section 741'' has a fourth surface ( 72''), and the protruding section 742'' is connected to the neck section 741''.
And, a ring-shaped wall 74'' is formed on the fourth surface 72'' surrounding the through hole 73'', and the ring-shaped wall 74'' is disposed in the ring-shaped groove 54''. do.
As shown in Figure 8, the specific structure of the third embodiment is that the ring-shaped groove 54'' and the perforation portion 53'' are in communication with each other, and the ring-shaped wall 74'' has a spiral external groove 12 and A scraping section 746'' is formed on the facing inner surface 745'', and the scraping section 746'' is similar to the second embodiment except that it is assembled and installed corresponding to the spiral external groove 12. do. The scraping section 746'' protrudes from the inner surface 745'' into the helical outer groove 12 and extends into the helical outer groove 12 of the screw 10. When the scraping plate 70'' is assembled to the end cap 50'' and the screw 10 and the nut 30 move relatively, the scraping section 746'' is formed by the scraping blade 75''. It can provide the same effect as . That is, foreign substances within the spiral external groove 12 can be scraped and dust-proofing and oil-sealing effects can be provided at the same time. The structure of the third embodiment allows the user to easily assemble the scraping plate 70'' to the end cap 50'', and the ring-shaped wall 74'' of the scraping plate 70'' also has a scraping function. have

Referring to FIGS. 9 and 10, FIG. 9 is a three-dimensional schematic diagram of a scraping plate according to a fourth embodiment, and FIG. 10 is a three-dimensional schematic diagram of a scraping plate according to a fifth embodiment. Since the fourth and fifth embodiments are other embodiments of the third embodiment, identical structures will not be redundantly explained. As shown in Figure 9, in the fourth embodiment, the ring-shaped wall 74''' further includes a plurality of notches 743'''. Each notch 743''' is installed roundly on the ring-shaped wall 74''' centered on the through-hole 73''', and divides the ring-shaped wall 74''' into a plurality of activity areas. It forms (744'''). The notch structure of the third embodiment is such that each notch 743''' extends from an end away from the fourth surface 72''' to the fourth surface 72''', and has a ring-shaped wall 74''. It is similar to the second embodiment except that a plurality of activity areas 744''' are formed by dividing '). In a fifth embodiment, as shown in Figure 10, the extent of each notch 743'''' divides the ring-shaped wall 74'''' into a plurality of smaller active areas 744''''. By increasing the division, the scraping plate 70'''' can be more easily assembled to the end cap 50''.

Referring to FIG. 11, FIG. 11 is a schematic diagram of a linear power transmission assembly according to one embodiment. The scraping plate and end cap in the linear power transmission may be a group of linear power transmission assembly 200, which can cooperate with linear power transmission devices of different specifications and models. In this embodiment, the same structure as the scraping plate and end cap of the above embodiment will not be redundantly described. Linear powertrain assembly 200 includes an end cap 210 and scraping plate 230. The end cap 210 includes a first surface 211, a second surface 212, a perforation 213, at least one buckle groove 214 and a circulator 215, and the first surface 211 and the second surface 212 are opposing surfaces, the perforation 213 penetrates the first surface 211 and the second surface 212, and the at least one buckle groove 214 is formed on the first surface 211. ) and has a tapered section 2141 and a receiving section 2142, the tapered section 2141 corresponds to the first surface 211, and the receiving section 2142 is connected to the tapered section 2141. , the circulator 215 extends axially from the periphery of the perforated portion 213 on the second surface 212 side, and the circulator 215 is provided with a circulation groove 2151.

The scraping plate 230 is assembled and installed on the end cap 210, and the scraping plate 230 includes a third surface 231, a fourth surface 232, a through hole 233, and at least one buckle member 234. and a scraping blade 235, wherein the fourth surface 232 faces the first surface 211 of the end cap 210, and the third surface 231 and the fourth surface 232 are opposing surfaces. , the through hole 233 penetrates the third surface 231 and the fourth surface 232, at least one buckle member 234 is installed on the fourth surface 232, and at least one buckle groove 214 ), the at least one buckle member 234 has a neck section 2341 and a protruding section 2342, the neck section 2341 is connected to the fourth surface 232, and the protruding section ( 2342) is connected to the neck section 2341, and the scraping blade 235 is installed on the periphery of the through hole 233. The neck section 2341 is accommodated in the tapered section 2141, and the protruding section 2342 is accommodated in the receiving section 2142. Specifically, the linear power transmission assembly 200 is assembled to the nut of the linear power transmission by, for example, a buckling connection or a screw connection, and the end cap 210 and the scraping blade 235 provide a quick and easy assembly effect. can be achieved.

In summary, the linear power transmission device 100 is quickly aligned during assembly through the buckle member 74 and the buckle groove 54 disposed in correspondence with each other, and then the scraping plate 70, 70', 70'', 70 By assembling ''',70'''') to the end caps (50,50',50''), a quick and easy assembly effect can be achieved, reducing cumbersome assembly processes and manpower consumption, and also realizing an automated assembly process. there is. Additionally, the linear powertrain assembly 200 can cooperate with linear powertrains of other specifications and models to implement an automated assembly process.

100: linear power transmission device 10: screw
11: outer ring surface 12: spiral outer groove
200: Linear power transmission assembly 210: End cap
211: first surface 212: second surface
213: perforation 214: buckle groove
2141: Taper section 2142: Accommodation section
215: circulator 2151: circulation groove
230: scraping plate 231: third surface
232: fourth surface 233: through study
234: Buckle member 2341: Neck section
2342: protruding section 235: scraping blade
30: Nut 31: Inner ring surface
32: Spiral internal groove 33: Barrel portion
40: Ball groove 50, 50', 50'': End cap
51, 51', 51'': first surface 52, 52', 52'': second surface
53, 53', 53'': perforation 54: buckle groove
54', 54'': Ring-shaped groove 541, 541': Tapered section
5411: 1st stage 5412: 2nd stage
542, 542': Receiving section 55: Circulator
551: Circulation groove
70, 70', 70'', 70''', 70'''': Scraping plate
71, 71': third surface
72, 72', 72'', 72''': fourth surface
73, 73',73'', 73''': Through hole 74': Absence of buckle
74', 74'', 74''', 74'''': Ring wall
741, 741',741'': Neck section 742, 742', 742'': Protruding section
743', 743''', 743'''': Notch
744', 744''', 744'''': Active area 745'': Medial surface
746'': Scraping section 75, 75'': Scraping blade

Claims (14)

As a linear power transmission device,
Includes screws, nuts, end caps and scraping plates,
The screw includes a spiral outer groove provided on the outer ring surface of the screw;
The nut includes a barrel portion and a spiral inner groove, the barrel portion is installed to cover the screw, the spiral inner groove is installed on the inner ring surface of the barrel portion, and the spiral inner groove and the spiral outer groove correspond to each other. forming a ball groove;
The end cap is secured to the nut, the end cap includes a first surface, a second surface, a perforation, at least one buckle groove and a circulator, and the first surface and the second surface are opposite surfaces. The second surface faces the nut, the perforation portion passes through the first surface and the second surface and corresponds to the barrel portion, and the at least one buckle groove is provided on the first surface and is tapered. It has a section and a receiving section, wherein the tapered section corresponds to the first surface, the receiving section is connected to the tapered section, and the circulator extends axially from the periphery of the perforation on the second surface side. The nut is installed through the barrel portion, and the circulator has a circulation groove, and the circulation groove communicates with the ball groove;
The scraping plate is assembled and installed on the end cap, the scraping plate includes a third surface, a fourth surface, a through hole, at least one buckle member, and a scraping blade, and the third surface and the fourth surface face each other. The fourth surface faces the first surface of the end cap, the through hole penetrates the third surface and the fourth surface and corresponds to the barrel portion, and the at least one buckle member is Installed on the fourth surface and corresponding to the at least one buckle groove, the at least one buckle member has a neck section and a protruding section, the neck section is connected to the fourth surface, and the protruding section The section is connected to the neck section, and the scraping blade is installed on the periphery of the through hole and is assembled and installed corresponding to the spiral external groove;
The neck section is accommodated in the tapered section, and the protruding section is accommodated in the receiving section. 2. The method of claim 1, wherein the at least one buckle groove surrounds the perforation to form a ring-shaped groove, and the at least one buckle member is a ring-shaped wall, the ring-shaped wall surrounding the perforation and protruding from the fourth surface. and the ring-shaped wall is disposed in the ring-shaped groove. The method of claim 2, wherein the ring-shaped groove and the perforation part communicate with each other, and a scraping section is installed on the ring-shaped wall on an inner surface facing the spiral outer groove, and the scraping section is assembled and installed to correspond to the spiral outer groove. linear power transmission system. The method of claim 1, wherein the at least one buckle groove is a plurality of buckle grooves, each of the buckle grooves is installed to be rounded on the first surface around the perforation portion, and the at least one buckle member has a plurality of buckle grooves. A linear power transmission device that is a buckle member, and each buckle member is installed roundly on the fourth surface around the through hole. The method of claim 1, wherein the tapered section has a first end and a second end, the first end and the second end are opposite ends, the first end corresponds to the first surface, and the receiving section. is connected to the second stage, and the width of the tapered section gradually decreases from the first stage to the second stage. The linear power transmission device of claim 1, wherein the width of the neck section gradually decreases in the direction from the fourth surface to the protruding section. The linear power transmission device of claim 1, wherein the protruding section is a spherical joint or a rectangular joint. A linear power transmission assembly comprising:
Includes end caps and scraping plates,
The end cap includes a first surface, a second surface, a perforation, at least one buckle groove, and a circulator, wherein the first surface and the second surface are opposing surfaces, and the perforation is opposite to the first surface and the perforation. Penetrating the second surface, the at least one buckle groove is provided on the first surface and has a tapered section and a receiving section, the tapered section corresponding to the first surface, and the receiving section being adjacent to the tapered section. connected to a section, the circulator extending axially from the periphery of the perforation on the second surface side, the circulator having a circulation groove;
The scraping plate is assembled and installed on the end cap, the scraping plate includes a third surface, a fourth surface, a through hole, at least one buckle member, and a scraping blade, and the third surface and the fourth surface face each other. The fourth surface faces the first surface of the end cap, the through hole penetrates the third surface and the fourth surface, and the at least one buckle member is installed on the fourth surface. and is installed to correspond to the at least one buckle groove, wherein the at least one buckle member has a neck section and a protruding section, the neck section is connected to the fourth surface, and the protruding section is connected to the neck section. connected, and the scraping blade is installed on the periphery of the through hole;
A linear power transmission device assembly wherein the neck section is accommodated in the tapered section, and the protruding section is accommodated in the receiving section. 9. The method of claim 8, wherein the at least one buckle groove surrounds the perforation and forms a ring-shaped groove, the at least one buckle member is a ring-shaped wall, and the ring-shaped wall surrounds the perforation and protrudes from the fourth surface. and the ring-shaped wall is disposed in the ring-shaped groove. The linear power transmission device assembly of claim 9, wherein the ring-shaped groove and the perforation communicate with each other, and a scraping section is installed on an inner surface of the ring-shaped wall. The method of claim 8, wherein the at least one buckle groove is a plurality of buckle grooves, each of the buckle grooves is installed to be rounded on the first surface around the perforation portion, and the at least one buckle member has a plurality of buckle grooves. A linear power transmission device assembly that is a buckle member, and each buckle member is installed roundly on the fourth surface around the through hole. The method of claim 8, wherein the tapered section has a first end and a second end, the first end and the second end are opposite ends, the first end corresponds to the first surface, and the receiving section. is connected to the second stage, and the width of the tapered section gradually decreases from the first stage to the second stage. The linear power transmission assembly of claim 8, wherein the width of the neck section gradually decreases in the direction from the fourth surface to the protruding section. The linear power transmission assembly of claim 8, wherein the protruding section is a spherical joint or a rectangular joint.