CN220722119U - Deep groove ball holder pile up neatly receiving device - Google Patents

Abstract

The application discloses deep groove ball holder pile up neatly receiving device, the column string material subassembly comprises many guide bars that encircle the material chassis center that connects, through making adjustment mechanism action, make the first movable tank that many guide bars can set up along the material chassis that connects and the first movable tank that the toper guide head set up and the second movable tank move near or keep away from the center that connects the material chassis, thereby change the diameter of column string material subassembly, with the deep groove ball holder material receiving operation that is used for different specification diameter dimensions, after the column string material subassembly string of a string material unit is full, drive arrangement drive connects the material tray rotation, make other string material units continue to connect the material, thereby realize automatic material pile up neatly effect, the production operation cost of holder processing enterprise has been reduced.

Description

Deep groove ball holder pile up neatly receiving device

Technical Field

The application belongs to deep groove ball holder material receiving field, especially relates to a deep groove ball holder pile up neatly material receiving device.

Background

The deep groove ball bearing is widely applied to automobiles, airplanes, machine tools and daily household appliances, wherein an important bearing part for isolating and guiding steel balls to rotate at high speed in inner and outer ring channels is a deep groove ball retainer, the deep groove ball retainer is an important component part in the manufacturing process of the deep groove ball bearing and is mainly manufactured through a stamping process, and due to the fact that the production capacity of a factory is relatively large, meanwhile, the retainer is irregular in shape, difficult to classify, put and collect, and the labor capacity of workers is relatively large.

The Chinese patent with the publication number of CN205887883U discloses a punching press carousel material-mixing machine, including unable adjustment base, rotate the tray that sets up at unable adjustment base, evenly set up the string material pole that N perpendicular tray was used for the cover charging ring on the tray, through the drive arrangement that sets up and equipartition positioner, the suit that the charging ring can be neat is on string material pole, thereby the difficult problem of classifying and accomodating of holder has been solved, but this kind of material-mixing machine only corresponds the deep groove ball holder of single specification, need change the interval of arranging of taking off the tray string material pole and the size of string material pole to the deep groove ball holder of different specification sizes, no different from increasing manufacturing cost to the enterprise production, therefore it is clear that prior art remains to improve and improve further.

Disclosure of Invention

The utility model provides a deep groove ball retainer stacking and receiving material which at least solves or alleviates one or more technical problems in the prior art, or at least provides a beneficial choice.

In order to achieve the above purpose, the present utility model provides the following technical solutions:

the deep groove ball retainer stacking and receiving device comprises a receiving tray and a driving device for driving the receiving tray to rotate, wherein a plurality of material-stringing units used for sleeving a material-stringing ring are annularly and uniformly distributed on the tray surface of the receiving tray, and the deep groove ball retainer stacking and receiving device is characterized in that the material-stringing units comprise a columnar material-stringing component, a material-stringing chassis and a conical material-guiding head;

the columnar material-mixing assembly is composed of a plurality of guide rods which are arranged around the center of a material-receiving chassis, the material-receiving chassis is provided with a first moving groove along the radial direction, the conical material-guiding head is provided with a second moving groove along the radial direction, one end of each guide rod is arranged in the first moving groove, the other end of each guide rod is arranged in the second moving groove so as to realize radial movement, each guide rod is connected with an adjusting mechanism, and the adjusting mechanism acts to enable the guide rods to be close to or far away from the center of the material-receiving chassis so as to adjust the diameter of the columnar material-mixing assembly.

According to the stacking and receiving device for the deep groove ball retainer, the columnar material-mixing assembly for sleeving the deep groove ball retainer is composed of the guide rods surrounding the center of the material-receiving chassis, the guide rods can move along the first moving groove arranged on the material-receiving chassis and the first moving groove and the second moving groove arranged on the conical material-guiding head to be close to or far away from the center of the material-receiving chassis through the action of the adjusting mechanism, so that the diameter of the columnar material-mixing assembly is changed, the columnar material-mixing assembly is used for receiving operations of the deep groove ball retainers with different specifications and diameters, and after the columnar material-mixing assembly of one material-mixing unit is fully mixed, the driving device drives the material-receiving tray to rotate, so that other material-mixing units continue to receive materials, the automatic material-receiving and stacking effects are achieved, and the production operation cost of retainer processing enterprises is reduced.

Preferably, the guide rod comprises a vertical section and an inclined section, the end part of the inclined section is arranged in the second moving groove, the diameter size of the columnar string component formed by the inclined section gradually increases towards the vertical section, and the diameter size of the columnar string component formed by the vertical section is matched with the inner diameter of the deep groove ball retainer to be tested.

Through constitute guide bar design by vertical section and slope section, the column string material subassembly part that comprises the slope section forms the taper, is convenient for form the cooperation with the toper guide head, guides the holder jointly, makes its whereabouts to vertical section pile up neatly.

Preferably, the adjusting mechanism comprises a vertical rod arranged in the center of the receiving chassis and an adjusting disc which is arranged on the upper side of the receiving chassis and is coaxially arranged with the receiving chassis; the adjusting plate is provided with an arc waist hole, one semicircular surface of one end of the arc waist hole is close to the center of the material receiving chassis, the semicircular surface of the other end of the arc waist hole is close to the edge of the material receiving chassis, one end of the guide rod penetrates through the arc waist hole and is connected with the moving block, the moving block is arranged in the first moving groove, and the adjusting plate is rotated to enable a plurality of guide rods to be synchronously close to or far away from the material receiving chassis.

Through designing adjustment mechanism into the adjustment disk, make the guide bar pass the arc waist hole that the adjustment disk was seted up, and the movable block is connected to one end, and the movable block can first movable groove remove, and the semicircle face of the one end of arc waist hole is close to the center of receiving the material chassis, and the semicircle face of the other end is close to the edge on chassis, rotates the adjustment disk during the use, makes the diameter that is close to or keeps away from receiving the material chassis center that many guide bars can be synchronous to adjust column string material subassembly, the adjustment is convenient, simple operation.

Preferably, the vertical rod is rotationally connected with the material receiving chassis and the conical material guide head, the adjusting disc is fixedly connected with the vertical rod, a threaded hole and a hollow area are formed in the center of the conical material guide head, the threaded hole is communicated with the hollow area, the vertical rod is rotationally arranged in the hollow area, a fixing hole is formed in the end portion of the vertical rod, and a bolt penetrates through the threaded hole to be connected with the fixing hole to fix the vertical rod.

Preferably, the vertical rod is fixedly connected with the material receiving chassis and the conical material guide head, the adjusting disc is rotationally connected with the vertical rod, a hollow positioning column is arranged between the adjusting disc and the material receiving chassis, the hollow positioning column is provided with internal threads, a hollow connecting column with external threads is arranged at the center of the adjusting disc, and the adjusting disc is rotated to enable the hollow connecting column to be matched and connected with the hollow positioning column so as to fix the adjusting disc.

Preferably, a movable space exists between the other end of the guide rod and the second moving groove, so that the end of the guide rod can move in the second moving groove.

The guide rod has the activity space with the toper stub bar, the guide rod along the radial in-process of moving of second movable groove, with the second movable groove contactless, the second movable groove only is as the dodge groove that the guide rod removed, the movable block is connected to the bottom of guide rod and is moved in first movable groove, reduce the removal resistance, prevent that there is frictional force different conditions at the both ends of movable rod from existence, if toper stub bar is plastics, coefficient of friction is little, and the material receiving chassis is cast iron, both ends can't synchronous movement, lead to the guide rod to buckle deformation easily, at the end of the super toper stub bar external diameter of guide rod tip, change bigger external diameter toper stub bar can.

Preferably, the end of the guide rod is conical, the depth of the second moving groove is smaller than the height of the conical end, and the width of the second moving groove is larger than or equal to the diameter of the conical end.

Preferably, the receiving tray is provided with a plurality of positioning holes, the receiving chassis is provided with a plurality of connecting holes, and the positioning holes are connected with the connecting holes through bolts.

The detachable connection mode of the material receiving chassis and the material receiving tray is convenient to detach and replace, the layout and the interval of the material mixing units are convenient to adjust, and the material receiving chassis and the material receiving tray are suitable for retainers with different specifications.

Preferably, the automatic feeding device further comprises a machine base, wherein the receiving tray and the driving device are arranged on the machine base, and lifting support legs are arranged on the machine base to adjust the height of the material stringing unit.

The material-mixing unit is arranged on the stand with the lifting supporting legs, so that the height of the material-mixing unit can be adjusted to adapt to production machines with different heights.

Preferably, the driving device comprises a servo motor and a reduction gearbox, wherein an output shaft of the servo motor is connected with the reduction gearbox, an output shaft of the reduction gearbox is connected with the receiving disc, an electric wire of the servo motor is connected with a controller, and the controller controls the rotation angle of the servo motor.

The structure has the following beneficial effects:

1. according to the stacking and receiving device for the deep groove ball retainer, the columnar material-mixing assembly is designed to be composed of the guide rods encircling the center of the material-mixing chassis, the diameter of the columnar material-mixing assembly can be adjusted through the adjusting mechanism so as to be used for the material-mixing operation of the deep groove ball retainer with different specifications and diameters, and when the columnar material-mixing assembly of one material-mixing unit is full, the driving device drives the material-mixing disc to rotate, so that the rest material-mixing units continue to be mixed, the automatic material-mixing and stacking effects are achieved, and the production and operation cost of retainer processing enterprises is reduced.

According to the deep groove ball retainer stacking and receiving device, the adjusting mechanism is designed to be the adjusting disc, the guide rods penetrate through the arc-shaped waist holes formed in the adjusting disc, one end of each guide rod is connected with the moving block, the moving block can move in the first moving groove, the semicircular surface of one end of each arc-shaped waist hole is close to the center of the receiving chassis, the semicircular surface of the other end of each arc-shaped waist hole is close to the edge of the receiving chassis, and the adjusting disc is rotated when the deep groove ball retainer stacking and receiving device is used, so that the guide rods can synchronously get close to or far from the center of the receiving chassis, and the diameter of the columnar material mixing assembly is adjusted, and the deep groove ball retainer stacking and receiving device is convenient to adjust and operate.

Drawings

The accompanying drawings, which are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate embodiments of the utility model and together with the description serve to explain the present application and do not constitute a limitation on the utility model. In the drawings:

FIG. 1 is a schematic perspective view of an exemplary embodiment of a palletizing receiving device according to the present application;

FIG. 2 is a schematic perspective view of an exemplary embodiment of a stringing unit according to the present application;

FIG. 3 is a schematic cross-sectional view of an exemplary embodiment of the adjustment structure of the present application;

FIG. 4 is an enlarged schematic view of an exemplary embodiment of the portion A of FIG. 3 of the present application;

FIG. 5 is a schematic perspective view of an exemplary embodiment of a receiving tray of the present application;

description of the reference numerals:

1-a material stringing unit; 10-a columnar material mixing component; 100-guides; 1000-vertical section; 1001-inclined section; 101-moving a block; 11-a material receiving chassis; 110-a first movement slot; 111-connecting holes; 12-a conical material guide head; 120-a second movement slot; 121-a threaded hole; 122-hollow region;

2-an adjusting mechanism; 20-erecting a pole; 200-fixing holes; 21-an adjusting disc; 210-arc waist holes; 211-a central connection column; 22-hollow positioning columns;

3-receiving trays; 30-positioning holes;

4-a driving device; 40-servo motor; 41-reduction gearbox; 42-a controller;

5-a stand; 50-lifting support legs;

Detailed Description

Hereinafter, only certain exemplary embodiments are briefly described. As will be recognized by those of skill in the pertinent art, the described embodiments may be modified in various different ways without departing from the spirit and scope of the present utility model. Accordingly, the drawings and description are to be regarded as illustrative in nature and not as restrictive.

The present utility model will be described below with reference to the drawings.

The scheme adopted is as follows:

as shown in fig. 1-5, the utility model provides a deep groove ball retainer stacking and receiving device, which comprises a receiving tray 3 and a driving device 4 for driving the receiving tray 3 to rotate, wherein a plurality of material-mixing units 1 for sleeving a material-mixing ring are annularly and uniformly distributed on the tray surface of the receiving tray 3, and the deep groove ball retainer stacking and receiving device is characterized in that the material-mixing units 1 comprise a columnar material-mixing assembly 10, a material-mixing chassis 11 and a conical material-guiding head 12;

the columnar material mixing assembly 10 is composed of a plurality of guide rods which are arranged around the center of the material receiving chassis 11, the material receiving chassis 11 is provided with a first moving groove 110 along the radial direction, the conical material guiding head 12 is provided with a second moving groove 120 along the radial direction, one end of each guide rod is arranged in the first moving groove 110, the other end of each guide rod is arranged in the second moving groove 120 so as to realize radial movement, each guide rod is connected with the adjusting mechanism 2, and the adjusting mechanism 2 acts to enable the guide rods to be close to or far away from the center of the material receiving chassis 11 so as to adjust the diameter of the columnar material mixing assembly 10.

According to the stacking and receiving device for the deep groove ball retainer, the columnar string material assembly 10 for sleeving the deep groove ball retainer is composed of a plurality of guide rods which encircle the center of the receiving chassis 11, the guide rods can move along the first moving groove 110 arranged on the receiving chassis 11 and the first moving groove 110 and the second moving groove 120 arranged on the conical guide head 12 to be close to or far away from the center of the receiving chassis 11 through the action of the adjusting mechanism 2, so that the diameter of the columnar string material assembly 10 is changed for the deep groove ball retainer material receiving operation with different specification and diameter sizes, and after the columnar string material assembly 10 of one string material unit 1 is fully strung, the driving device 4 drives the receiving tray 3 to rotate, so that the other string material units 1 continue to receive materials, the automatic material receiving and stacking effects are achieved, and the production operation cost of a retainer processing enterprise is reduced.

The specific structure of the guide rod is as shown in fig. 2, the guide rod comprises a vertical section 1000 and an inclined section 1001, the end part of the inclined section 1001 is arranged in the second moving groove 120, the diameter size of the columnar string component 10 formed by the inclined section 1001 gradually increases towards the vertical section 1000, and the diameter size of the columnar string component 10 formed by the vertical section 1000 is matched with the inner diameter of the deep groove ball retainer to be tested. The guide rod is composed of the vertical section 1000 and the inclined section 1001, and the columnar material mixing assembly 10 composed of the inclined section 1001 is in a cone shape, so that the columnar material mixing assembly is convenient to be matched with the conical material guiding head 12, and the retainer is guided together to fall to the vertical section 1000 for stacking.

In order to enable the plurality of guide rods to synchronously approach or connect the center of the material turntable, it is common practice to individually adjust the movement of each guide rod, and this requires that each guide rod moves by the same distance, and the adjustment is complex, so in this embodiment, as shown in fig. 1 and 2, the adjusting mechanism 2 includes a vertical rod 20 disposed at the center of the material receiving chassis 11, and an adjusting disc 21 disposed above the material receiving chassis 11 and coaxially with the material receiving chassis 11; the adjusting plate 21 is provided with an arc waist hole 210, one semicircular surface of one end of the arc waist hole 210 is close to the center of the material receiving chassis 11, the semicircular surface of the other end of the arc waist hole 210 is close to the edge of the material receiving chassis 11, one end of the guide rod penetrates through the arc waist hole 210 and is connected with the moving block 101, the moving block 101 is arranged in the first moving groove 110, the adjusting plate 21 is rotated to enable a plurality of guide rods to be synchronously close to or far away from the material receiving chassis 11, specifically, as shown in fig. 2, when the adjusting plate 21 is rotated clockwise, three guide rods simultaneously move towards the center direction of the adjusting plate 21 so as to reduce the diameter of the columnar material mixing assembly 10, and when the adjusting plate 21 is rotated anticlockwise, three guide rods simultaneously move away from the center line direction of the adjusting plate 21 so as to increase the diameter of the columnar material mixing assembly 10, and the structure design is reasonable.

The adjusting disc 21 needs to be fixed at a certain adjusting position after rotating, so as to prevent the diameter of the columnar material mixing assembly 10 from changing, and specifically, one of the following embodiments can be adopted:

example 1:

referring to fig. 3, a vertical rod 20 is rotatably connected with a receiving chassis 11 and a conical material guide head 12, an adjusting disc 21 is fixedly connected with the vertical rod 20, a threaded hole 121 and a hollow area 122 are formed in the center of the conical material guide head 12, the threaded hole 121 is communicated with the hollow area 122, the vertical rod 20 is rotatably arranged in the hollow area 122, a fixing hole 200 is formed in the end portion of the vertical rod 20, and a bolt penetrates through the threaded hole 121 to be connected with the fixing hole 200 to fix the vertical rod 20.

Example 2:

referring to fig. 4, a vertical rod 20 is fixedly connected with a receiving chassis 11 and a conical guide head 12, an adjusting plate 21 is rotatably connected with the vertical rod 20, a hollow positioning column 22 is arranged between the adjusting plate 21 and the receiving chassis 11, the hollow positioning column 22 is provided with internal threads, a hollow connecting column with external threads is arranged at the center of the adjusting plate 21, and the adjusting plate 21 is rotated to enable the hollow connecting column to be matched and connected with the hollow positioning column 22 so as to fix the adjusting plate 21.

Meanwhile, as shown in fig. 2, a movable space exists between the other end of the guide rod and the second moving groove 120, so that the end of the guide rod can move in the second moving groove 120, the guide rod and the conical guide head 12 have a movable space, preferably, the end of the guide rod is conical, the depth of the second moving groove 120 is smaller than the height of the conical end, and the width of the second moving groove 120 is larger than or equal to the diameter of the conical end.

Specifically, in the radial movement process of the guide rod along the second moving groove 120, the guide rod is in non-contact with the second moving groove 120, the second moving groove 120 serves as a avoidance groove for the guide rod to move, the bottom end of the guide rod is connected with the moving block 101 to move in the first moving groove 110, moving resistance is reduced, friction force difference conditions at two ends of the guide rod are prevented, if the conical guide head 12 is plastic, friction coefficient is small, the receiving chassis 11 is cast iron, two ends cannot move synchronously, bending deformation of the guide rod is easily caused, and when the end part of the guide rod exceeds the outer diameter of the bottom of the conical guide head 12, the conical guide head with larger outer diameter is replaced.

As a preferred embodiment of the present application, as shown in fig. 5, the tray 3 is provided with a plurality of positioning holes 30, the tray 11 is provided with a plurality of connecting holes 111, and the positioning holes 30 and the connecting holes 111 are connected by bolts. The detachable connection mode of the material receiving chassis 11 and the material receiving tray 3 is convenient to detach and replace, the layout and the interval of the material mixing unit 1 are convenient to adjust, and the retainer with different specifications is adapted.

As a preferred embodiment of the present application, the device further comprises a stand 5, the receiving tray 3 and the driving device 4 are arranged on the stand 5, and the stand 5 is provided with lifting legs 50 for adjusting the height of the string unit 1.

The material mixing unit 1 is arranged on the stand 5 with the lifting supporting leg 50, so that the height of the material mixing unit 1 can be adjusted to adapt to production machines with different heights.

As a preferred embodiment of the present application, the driving device 4 includes a servo motor 40 and a reduction gearbox 41, an output shaft of the servo motor 40 is connected with the reduction gearbox 41, an output shaft of the reduction gearbox 41 is connected with the tray 3, an electric wire of the servo motor 40 is connected with a controller 42, and the controller 42 gives a certain pulse signal to the servo motor to control the rotation angle of the servo motor 40.

The utility model can be realized by adopting or referring to the prior art at the places which are not described in the utility model.

In the description of the present utility model, it should be understood that the terms "center," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "axial," "radial," "circumferential," and the like indicate orientations or positional relationships based on the orientation or positional relationships shown in the drawings, merely to facilitate describing the present utility model and simplify the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and therefore should not be construed as limiting the present utility model. In the present utility model, unless expressly stated or limited otherwise, a first feature "up" or "down" a second feature may be the first and second features in direct contact, or the first and second features in indirect contact via an intervening medium.

In the present utility model, unless explicitly specified and limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally formed; can be directly connected or indirectly connected through an intermediate medium, and can be communicated with the inside of two elements or the interaction relationship of the two elements. However, it is noted that a direct connection indicates that two bodies connected together do not form a connection relationship by an excessive structure, but are connected to form a whole by a connection structure. The specific meaning of the above terms in the present utility model can be understood by those of ordinary skill in the art according to the specific circumstances.

The description as it relates to "first", "second", etc. in the present utility model is for descriptive purposes only and is not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature.

The foregoing is merely illustrative of the present utility model, and the present utility model is not limited thereto, and any person skilled in the art will readily recognize that various modifications and substitutions are possible within the scope of the present utility model. Therefore, the protection scope of the utility model is subject to the protection scope of the claims.

Claims (10)

1. The deep groove ball retainer stacking and receiving device comprises a receiving tray and a driving device for driving the receiving tray to rotate, wherein a plurality of material-stringing units used for sleeving a material-stringing ring are annularly and uniformly distributed on the tray surface of the receiving tray, and the deep groove ball retainer stacking and receiving device is characterized in that the material-stringing units comprise a columnar material-stringing component, a material-stringing chassis and a conical material-guiding head;

the columnar material-mixing assembly is composed of a plurality of guide rods which are arranged around the center of a material-receiving chassis, the material-receiving chassis is provided with a first moving groove along the radial direction, the conical material-guiding head is provided with a second moving groove along the radial direction, one end of each guide rod is arranged in the first moving groove, the other end of each guide rod is arranged in the second moving groove so as to realize radial movement, each guide rod is connected with an adjusting mechanism, and the adjusting mechanism acts to enable the guide rods to be close to or far away from the center of the material-receiving chassis so as to adjust the diameter of the columnar material-mixing assembly.

2. The deep groove ball retainer stacking and receiving device according to claim 1, wherein the guide rod comprises a vertical section and an inclined section, the end part of the inclined section is arranged in the second moving groove, the diameter size of the columnar string component formed by the inclined section gradually increases towards the vertical section, and the diameter size of the columnar string component formed by the vertical section is matched with the inner diameter of the deep groove ball retainer to be tested.

3. The deep groove ball retainer stacking and receiving device according to claim 1, wherein the adjusting mechanism comprises a vertical rod arranged in the center of the receiving chassis and an adjusting disc which is arranged on the upper side of the receiving chassis and is coaxial with the receiving chassis; the adjusting plate is provided with an arc waist hole, one semicircular surface of one end of the arc waist hole is close to the center of the material receiving chassis, the semicircular surface of the other end of the arc waist hole is close to the edge of the material receiving chassis, one end of the guide rod penetrates through the arc waist hole and is connected with the moving block, the moving block is arranged in the first moving groove, and the adjusting plate is rotated to enable a plurality of guide rods to be synchronously close to or far away from the material receiving chassis.

4. A deep groove ball retainer stacking and receiving device according to claim 3, wherein the vertical rod is rotationally connected with the receiving chassis and the conical guide head, the adjusting disc is fixedly connected with the vertical rod, the center of the conical guide head is provided with a threaded hole and a hollow area, the threaded hole is communicated with the hollow area, the vertical rod is rotationally arranged in the hollow area, the end part of the vertical rod is provided with a fixing hole, and a bolt penetrates through the threaded hole to be connected with the fixing hole to fix the vertical rod.

5. A deep groove ball retainer stacking and receiving device according to claim 3, wherein the vertical rod is fixedly connected with the receiving chassis and the conical guide head, the adjusting disc is rotationally connected with the vertical rod, a hollow positioning column is arranged between the adjusting disc and the receiving chassis, the hollow positioning column is provided with internal threads, a hollow connecting column with external threads is arranged in the center of the adjusting disc, and the adjusting disc is rotated to enable the hollow connecting column to be in matched connection with the hollow positioning column so as to fix the adjusting disc.

6. A deep groove ball retainer palletizing receiving device according to claim 3, wherein a movable space exists between the other end of the guide rod and the second moving groove, so that the end of the guide rod can move in the second moving groove.

7. The deep groove ball retainer stacking and receiving device according to claim 6, wherein the end part of the guide rod is conical, the depth of the second moving groove is smaller than the height of the conical end part, and the width of the second moving groove is larger than or equal to the diameter of the conical end part.

8. The deep groove ball retainer stacking and receiving device according to claim 1, wherein the receiving tray is provided with a plurality of positioning holes, the receiving chassis is provided with a plurality of connecting holes, and the positioning holes and the connecting holes are connected through bolts.

9. The deep groove ball retainer stacking and receiving device according to claim 1, further comprising a base, wherein the receiving tray and the driving device are arranged on the base, and the base is provided with lifting support legs for adjusting the height of the string material unit.

10. The deep groove ball retainer stacking and receiving device according to claim 1, wherein the driving device comprises a servo motor and a reduction gearbox, an output shaft of the servo motor is connected with the reduction gearbox, an output shaft of the reduction gearbox is connected with the receiving disc, a wire of the servo motor is connected with a controller, and the controller controls the rotation angle of the servo motor.