CN220532287U - Automatic detection system for bearing cap height - Google Patents

Abstract

The utility model relates to the technical field of bearing processing, and particularly provides an automatic detection system for bearing cover height, which comprises a workbench, wherein a detection line is arranged on the workbench, and the system is arranged on the workbench and distributed around the detection line; the system comprises a feeding system, a material moving system, a detection system and a pushing system, wherein the feeding system is positioned at the input end of the detection line, the material moving system is positioned at one side of the detection line, the detection system is positioned at the other side of the detection line, and the pushing system is positioned at the same side as the detection system and is close to the output end of the detection line; by arranging the automatic detection system integrating the functions of feeding, material moving, detecting and pushing, the whole design layout is reasonable, the structure is compact, and the continuity of the bearing transmission on a detection line can be ensured by the material moving system in the bearing processing process; the detection system is used for detecting the height of the bearing cover, and pushing out the unqualified bearing through the pushing system, so that automation of the bearing detection process is realized, and further the bearing machining efficiency is improved.

Description

Automatic detection system for bearing cap height

Technical Field

The utility model relates to the technical field of bearing machining, in particular to an automatic detection system for bearing cap height.

Background

In the case of a bearing with a dust cover, there is a case where the dust cover Gao Chuzhou has a thickness, and therefore, it is necessary to detect the bearing with the dust cover and screen out the bearing with a height greater than the thickness of the bearing. At present, the detection is mainly performed manually, whether the dust cover is higher than the thickness of the bearing is detected through the height gauge, the detection efficiency is poor, and false detection is easy to occur.

Disclosure of Invention

In view of the above-mentioned drawbacks of the prior art, an object of the present utility model is to provide an automatic detection system for bearing cap height, which is used for solving the problem of low efficiency of detecting dust cap manually through a height gauge in the prior art.

To achieve the above and other related objects, the present utility model provides an automatic detection system for bearing cap height, comprising a workbench, wherein a detection line is provided on the workbench, and the system is provided on the workbench and distributed around the detection line;

the system comprises:

the feeding system is positioned at the input end of the detection line and is used for feeding the bearing;

the material moving system is positioned at one side of the detection line and is used for bearing material moving;

the detection system is positioned at the other side of the detection line, and the bearing to be detected is moved into the detection system through the material moving system to detect the height of the bearing cover;

and the pushing system is arranged on the same side as the detection system and is close to the output end of the detection line, the detected bearing is moved to the output end of the detection line through the moving system, and the unqualified bearing is pushed out by the pushing system.

In an embodiment of the utility model, the feeding system includes:

a feeding motor;

a driving rotating wheel arranged at the output end of the feeding motor;

a driven runner applied in cooperation with the driving runner;

meanwhile, the conveying belts of the driving rotating wheel and the driven rotating wheel are sleeved, the conveying belts are connected with the input end of the detection line in a crossed mode, and the bearing to be detected conveys materials to the detection line through the conveying belts.

In one embodiment of the present utility model, the material moving system includes:

a transfer stock rail parallel to the detection line;

the material moving motor is arranged on the material moving rail;

the first pushing cylinder is arranged at the upper end of the material moving motor, and the pushing direction of the first pushing cylinder is perpendicular to the detection line; the output end of the first pushing cylinder is provided with a fork for forking the bearing on the detection line, and then the material moving motor drives the material moving.

In one embodiment of the present utility model, the detection system includes:

a support frame perpendicular to the upper end of the workbench;

the first mounting seat is arranged at the upper end of the supporting frame, and,

the second installation seat is arranged at the side end of the support frame;

a measuring instrument is arranged through the first mounting seat, a detection seat is arranged through the second mounting seat, and a reed is arranged between the detection seat and the second mounting seat; the lower end of the measuring instrument is provided with a compressible corrugated end, and the corrugated end penetrates through the first mounting seat and is connected to the detection seat;

the lower end of the detection seat is provided with a positioning block used for penetrating through the inner ring of the detected bearing to position the placement position of the detected bearing; the detection seat synchronously reflects the thickness of the detected bearing through the height change by pressing the gravity of the detection seat on the detected bearing, and further obtains the thickness data of the detected bearing through the measuring instrument and judges whether the thickness of the detected bearing is qualified or not.

In an embodiment of the utility model, the detection system further comprises a lifting mechanism for lifting the detection seat, the lifting mechanism comprising:

the lifting cylinder is arranged at the side end of the support frame, and a conical push pin is arranged at the output end of the lifting cylinder;

the cylindrical wheel is arranged on the detection seat, and the push pin is abutted against the lower end of the cylindrical wheel; the lifting cylinder pushes the push pin to move along with the taper change of the push pin to jack up the cylindrical wheel so as to realize the up-and-down movement of the detection seat.

In an embodiment of the present utility model, the pushing system includes:

the pushing direction of the second pushing cylinder is perpendicular to the detection line;

and the output end of the second pushing cylinder is provided with a pushing plate for pushing out the unqualified bearing.

In an embodiment of the utility model, a feeding direction of the feeding system is perpendicular to a direction of the detection line, and an L-shaped plate is arranged at a joint of the feeding system and the detection line for turning the feeding joint.

In an embodiment of the utility model, a stop bar is disposed on a side edge of the detection line away from the material moving system.

In an embodiment of the utility model, the output end of the first pushing cylinder is provided with a pushing plate, the pushing plate is provided with an aluminum profile, and the material fork is arranged at the upper end of the aluminum profile.

In an embodiment of the present utility model, at least two fork material openings are disposed on the material fork, and the two fork material openings are respectively located at two ends of the material fork.

As described above, the automatic detection system for the bearing cap height has the following beneficial effects:

the automatic detection system integrating the functions of feeding, material moving, detecting and pushing is arranged, so that the overall design layout is reasonable, the structure is compact, the feeding system is used for feeding the bearing in the bearing processing process, and the material moving system is used for moving the material on the detection line, so that the continuity of the bearing in the transmission on the detection line can be ensured; the detection system is used for detecting the bearing cover height with the dust cover, pushing out the unqualified bearing through the pushing system, realizing the automation of the bearing detection process, and further improving the bearing machining efficiency.

Drawings

Fig. 1 is a schematic structural view of an automatic detection system for bearing cap height according to the present disclosure.

Fig. 2 is a schematic view of a bearing cap height automatic detection system according to another view angle of the present disclosure.

Fig. 3 shows an enlarged view of the feeding system in the bearing cap height automatic detection system disclosed by the utility model.

Fig. 4 is an enlarged view of a material moving system in the automatic detection system for bearing cap height according to the present utility model.

Fig. 5 shows an enlarged view of a detection system in the bearing cap height automatic detection system disclosed by the utility model.

Fig. 6 shows an enlarged view of a pushing system in the automatic detection system for bearing cap height according to the present utility model.

Description of element reference numerals

A work table 1; a detection line 2; a stop bar 3; a feeding motor 4; a driving rotating wheel 5; a driven runner 6; a conveyor belt 7; an L-shaped plate 8; a transfer line rail 9; a material moving motor 10; a first pushing cylinder 11; a fork 12; a fork opening 121; a push plate 13; an aluminum profile 14; a support 15; a first mount 16; a second mount 17; a gauge 18; a detection seat 19; a reed 20; a corrugated end 21; a positioning block 22; a lifting cylinder 23; push pins 24; a cylindrical wheel 25; a second pushing cylinder 26; a pusher plate 27; a feeding system a; a material moving system b; a detection system c; and a pushing system d.

Detailed Description

Further advantages and effects of the present utility model will become apparent to those skilled in the art from the disclosure of the present utility model, which is described by the following specific examples.

Please refer to fig. 1 to 6. It should be understood that the structures, proportions, sizes, etc. shown in the drawings are for illustration purposes only and should not be construed as limiting the utility model to the extent that it can be practiced, since modifications, changes in the proportions, or otherwise, used in the practice of the utility model, are not intended to be critical to the essential characteristics of the utility model, but are intended to fall within the spirit and scope of the utility model. Also, the terms such as "upper," "lower," "left," "right," "middle," and "a" and the like recited in the present specification are merely for descriptive purposes and are not intended to limit the scope of the utility model, but are intended to provide relative positional changes or modifications without materially altering the technical context in which the utility model may be practiced.

Referring to fig. 1-2, the utility model provides an automatic detection system for bearing cap height, comprising a workbench 1, wherein a detection line 2 is arranged on the workbench 1, and the system is arranged on the workbench 1 and distributed around the detection line 2; the system comprises a feeding system a, a material moving system b, a detection system c and a pushing system d, wherein the feeding system a is positioned at the input end of the detection line 2 and is used for feeding a bearing; the material moving system b is positioned at one side of the detection line 2 and is used for bearing material moving; the side edge of the detection line 2, which is far away from the material moving system b, is provided with a stop bar 3 for stopping the bearing, so that the bearing is prevented from falling off in the material moving process of the material moving system b; the detection system c is positioned at the other side of the detection line 2, and the bearing to be detected is moved into the detection system c through the material moving system b to detect the height of the bearing cover; the pushing system d is on the same side as the detection system c and is close to the output end of the detection line 2, the detected bearing is moved to the output end of the detection line 2 through the moving system b, and the unqualified bearing is pushed out by the pushing system d; all modules of the system are mutually matched, so that automation of a bearing detection process can be realized, and the bearing processing efficiency is improved.

Referring to fig. 3, the feeding system a includes a feeding motor 4, a driving runner 5 installed at an output end of the feeding motor 4, a driven runner 6 matched with the driving runner 5, and a conveyor belt 7 sleeved with the driving runner 5 and the driven runner 6 at the same time, wherein the conveyor belt 7 is in cross connection with an input end of the detection line 2, and a bearing to be detected conveys the feeding to the detection line 2 through the conveyor belt 7; the feeding direction of the feeding system a is perpendicular to the direction of the detection line 2, and an L-shaped plate 8 is arranged at the joint of the feeding system a and the detection line 2 and used for turning at the joint of feeding; the feeding system a is reasonably arranged in a limited workbench 1 space relative to the feeding steering design of the detection line 2, and the whole is compact.

Referring to fig. 4, the material moving system b includes a material moving rail 9, a material moving motor 10 disposed on the material moving rail 9, a first material pushing cylinder 11 disposed at an upper end of the material moving motor 10, and a material fork 12 disposed at an output end of the first material pushing cylinder 11, where the material moving rail 9 is parallel to the detection line 2, and a pushing direction of the first material pushing cylinder 11 is perpendicular to the detection line 2; the material fork 12 is used for carrying out fork material on the bearing on the detection line 2, and then the material moving motor 10 drives the material moving; specifically, the output end of the first pushing cylinder 11 is provided with a pushing plate 13, the pushing plate 13 is provided with an aluminum section bar 14, and the fork 12 is arranged at the upper end of the aluminum section bar 14; the material moving system b moves materials on the detection line 2, so that the continuity of the transmission of the bearing on the detection line 2 can be ensured; the material fork 12 is at least provided with two fork material openings 121, the two fork material openings 121 are respectively positioned at two ends of the material fork 12, and the bearing can be snapped through the fork material openings 121, so that the bearing is sent to the corresponding processing position through the cooperation driving of the material moving motor 10 and the first pushing cylinder 11.

Referring to fig. 5, the detection system c includes a support 15 perpendicular to the upper end of the workbench 1, a first mounting seat 16 disposed at the upper end of the support 15, and a second mounting seat 17 disposed at the side end of the support 15, wherein a measuring instrument 18 is installed through the first mounting seat 16, a detection seat 19 is installed through the second mounting seat 17, a reed 20 is disposed between the detection seat 19 and the second mounting seat 17, and the reed 20 can ensure movable connection of the detection seat 19 relative to the second mounting seat 17; the lower end of the measuring instrument 18 is provided with a compressible corrugated end 21, and the corrugated end 21 passes through the first mounting seat 16 and is connected to the detecting seat 19; the lower end of the detection seat 19 is provided with a positioning block 22 for penetrating through the inner ring of the detected bearing to position the placement position of the detected bearing; the detection seat 19 synchronously reflects the thickness of the detected bearing through the height change by pressing the gravity of the detection seat on the detected bearing, and further acquires the thickness data of the detected bearing through the measuring instrument 18 and judges whether the thickness of the detected bearing is qualified or not; high detection precision, stable detection and high repeated detection precision.

Referring to fig. 6, the detecting system c further includes a lifting mechanism for lifting the detecting seat 19, where the lifting mechanism includes a lifting cylinder 23 mounted on a side end of the supporting frame 15, a conical push pin 24 mounted on an output end of the lifting cylinder 23, and a cylindrical wheel 25 mounted on the detecting seat 19, and the push pin 24 abuts against a lower end of the cylindrical wheel 25; the lifting cylinder 23 pushes the push pin 24 to move to jack up the cylindrical wheel 25 along with the taper change of the push pin 24 so as to realize the up-and-down movement of the detection seat 19; the impact force of the detection process on the bearing is small, which is beneficial to the continuity of the detection work implementation.

The pushing system d comprises a second pushing cylinder 26 and a pushing plate 27 arranged at the output end of the second pushing cylinder 26, the pushing direction of the second pushing cylinder 26 is perpendicular to the detection line 2, the bearing detected by the detection system c is further moved to the output end of the detection line 2 through the material moving system b, pushing is not needed for qualified bearings, and the pushing plate 27 is movably pushed by the second pushing cylinder 26 to push out unqualified bearings.

In summary, the automatic detection system c integrating the functions of feeding, material moving, detecting and pushing is arranged, so that the overall design layout is reasonable, the structure is compact, the feeding system a is used for feeding the bearing in the bearing processing process, and the material moving system b moves the bearing on the detection line 2, so that the continuity of the bearing transmission on the detection line 2 can be ensured; the detection system c is used for detecting the height of the bearing cover with the dust cover, pushing out the unqualified bearing through the pushing system d, realizing the automation of the bearing detection process, and further improving the bearing machining efficiency. Therefore, the utility model effectively overcomes various defects in the prior art and has high industrial utilization value.

The above embodiments are merely illustrative of the principles of the present utility model and its effectiveness, and are not intended to limit the utility model. Modifications and variations may be made to the above-described embodiments by those skilled in the art without departing from the spirit and scope of the utility model. Accordingly, it is intended that all equivalent modifications and variations of the utility model be covered by the claims, which are within the ordinary skill of the art, be within the spirit and scope of the present disclosure.

Claims (10)

1. The automatic detection system for the bearing cap height comprises a workbench, wherein a detection line is arranged on the workbench, and the system is arranged on the workbench and distributed around the detection line;

characterized in that the system comprises:

the feeding system is positioned at the input end of the detection line and is used for feeding the bearing;

the material moving system is positioned at one side of the detection line and is used for bearing material moving;

the detection system is positioned at the other side of the detection line, and the bearing to be detected is moved into the detection system through the material moving system to detect the height of the bearing cover;

and the pushing system is arranged on the same side as the detection system and is close to the output end of the detection line, the detected bearing is moved to the output end of the detection line through the moving system, and the unqualified bearing is pushed out by the pushing system.

2. The automatic bearing cap height detection system according to claim 1, wherein the loading system comprises:

a feeding motor;

a driving rotating wheel arranged at the output end of the feeding motor;

a driven runner applied in cooperation with the driving runner;

meanwhile, the conveying belts of the driving rotating wheel and the driven rotating wheel are sleeved, the conveying belts are connected with the input end of the detection line in a crossed mode, and the bearing to be detected conveys materials to the detection line through the conveying belts.

3. The automatic bearing cap height detection system according to claim 1, wherein the material moving system comprises:

a transfer stock rail parallel to the detection line;

the material moving motor is arranged on the material moving rail;

the first pushing cylinder is arranged at the upper end of the material moving motor, and the pushing direction of the first pushing cylinder is perpendicular to the detection line; the output end of the first pushing cylinder is provided with a fork for forking the bearing on the detection line, and then the material moving motor drives the material moving.

4. The automatic bearing cap height detection system according to claim 1, wherein the detection system comprises:

a support frame perpendicular to the upper end of the workbench;

the first mounting seat is arranged at the upper end of the supporting frame, and,

the second installation seat is arranged at the side end of the support frame;

a measuring instrument is arranged through the first mounting seat, a detection seat is arranged through the second mounting seat, and a reed is arranged between the detection seat and the second mounting seat; the lower end of the measuring instrument is provided with a compressible corrugated end, and the corrugated end penetrates through the first mounting seat and is connected to the detection seat;

the lower end of the detection seat is provided with a positioning block used for penetrating through the inner ring of the detected bearing to position the placement position of the detected bearing; the detection seat synchronously reflects the thickness of the detected bearing through the height change by pressing the gravity of the detection seat on the detected bearing, and further obtains the thickness data of the detected bearing through the measuring instrument and judges whether the thickness of the detected bearing is qualified or not.

5. The automatic bearing cap height detection system according to claim 4, further comprising a lifting mechanism for lifting the detection seat, the lifting mechanism comprising:

the lifting cylinder is arranged at the side end of the support frame, and a conical push pin is arranged at the output end of the lifting cylinder;

the cylindrical wheel is arranged on the detection seat, and the push pin is abutted against the lower end of the cylindrical wheel; the lifting cylinder pushes the push pin to move along with the taper change of the push pin to jack up the cylindrical wheel so as to realize the up-and-down movement of the detection seat.

6. The automatic bearing cap height detection system according to claim 1, wherein the pushing system comprises:

the pushing direction of the second pushing cylinder is perpendicular to the detection line;

and the output end of the second pushing cylinder is provided with a pushing plate for pushing out the unqualified bearing.

7. The automatic bearing cap height detection system according to claim 2, wherein: the feeding direction of the feeding system is perpendicular to the direction of the detection line, and an L-shaped plate is arranged at the joint of the feeding system and the detection line and used for turning at the joint of feeding.

8. The automatic bearing cap height detection system according to claim 3, wherein: and a stop bar is arranged on the side edge, far away from the material moving system, of the detection line.

9. The automatic bearing cap height detection system according to claim 3, wherein: the output end of the first pushing cylinder is provided with a push plate, an aluminum profile is arranged on the push plate, and a material fork is arranged at the upper end of the aluminum profile.

10. The automatic bearing cap height detection system according to claim 9, wherein: at least two fork material openings are arranged on the material fork, and the two fork material openings are respectively positioned at two ends of the material fork.