CN114018807B - Automatic detection device for viscosity of stabilizer bar bushing - Google Patents

Abstract

The invention relates to the technical field related to detection equipment, in particular to an automatic detection device for the adhesive force of a stabilizer bar bush, which comprises a base, a pull-out assembly, a fixing assembly and a detection assembly, wherein the base is in a horizontal state, the pull-out assembly is fixedly arranged on the base, the pull-out assembly is provided with a horizontally moving output end, the fixing assembly is fixedly arranged on the base, the fixing assembly is positioned at the side of the pull-out assembly, two clamp assemblies are respectively used for clamping the two bushes, the detection assembly is used for detecting the adhesive force of the bushes, the two clamp assemblies are respectively clamped by the two clamp assemblies, one of the bushes is driven to move through the pull-out assembly, one of the bushes is pulled out from the stabilizer bar, the adhesive force detection of the bushes is completed, the two clamp assemblies are respectively abutted against the two pressure sensors, after one of the pressure sensors fails, the two clamp assemblies can continue to be tested, maintenance personnel can maintain the equipment when the equipment is idle, and detection delay caused by waiting for maintenance is avoided.

Description

Automatic detection device for viscosity of stabilizer bar bushing

Technical Field

The invention relates to the technical field related to detection equipment, in particular to an automatic detection device for the viscosity of a stabilizer bar bushing.

Background

When the vehicle body only moves vertically and the suspensions at two sides deform equally, the suspensions at two sides move up and down simultaneously, the transverse stabilizer bar rotates freely in the sleeve, and the transverse stabilizer bar does not work. When the vehicle turns, due to the fact that the forces born by the outer side suspensions are large, the two side suspensions are not deformed uniformly, the vehicle body is inclined transversely to the road surface, one side of the vehicle frame is close to the spring support, the tail end of the side of the stabilizer bar is upwards moved relative to the vehicle frame, the other side of the vehicle frame is far away from the spring support, the tail end of the corresponding stabilizer bar is downwards moved relative to the vehicle frame, and however, when the vehicle body and the vehicle frame are inclined, the middle part of the transverse stabilizer bar does not move relatively to the vehicle frame. Thus, when the vehicle body is tilted, the longitudinal portions of both sides of the stabilizer bar are deflected in different directions, and the stabilizer bar is twisted. The torsional internal moment generated by the elastic stabilizer bar prevents the deformation of the suspension spring, thereby reducing the lateral inclination and lateral angular vibration of the vehicle body and improving the running stability of the vehicle.

In the original bonding operation of the lining of the automobile stabilizer bar, whether bonding is qualified or not is detected manually, bonding force cannot be accurately judged, defective products are produced to flow outwards, abnormal sound or falling of the lining is caused during loading, even the lining is not found during loading, the driving stability of a vehicle is directly affected, and the comfort of framing and the driving safety are affected.

Disclosure of Invention

Based on this, it is necessary to provide an automatic detection device for the adhesion force of the stabilizer bushing against the prior art.

In order to solve the problems in the prior art, the invention adopts the following technical scheme: an automatic detection device for the adhesion force of a stabilizer bar bushing, comprising:

a base in a horizontal state;

the pulling-out assembly is fixedly arranged on the base and is provided with a horizontally moving output end;

the fixing component is fixedly arranged on the base, is positioned beside the pulling component and is positioned in the moving direction of the output end of the pulling component;

the two clamp assemblies are oppositely arranged, are respectively used for clamping the two bushings and are respectively and fixedly arranged at the output end of the pull-out assembly and the fixing assembly;

and the detection assembly is used for detecting the adhesive force of the bushing.

Further, the pull-out assembly includes:

the number of the first fixing seats is two, the two first fixing seats are fixedly arranged on the base, and the two first fixing seats are arranged at intervals along the linear direction;

the two first guide rods are in a horizontal state, are arranged at intervals along the direction perpendicular to the length direction, and are fixedly connected with the two first fixing seats respectively at two ends;

the axis of the threaded rod is parallel to the axis of the first guide rod, the threaded rod is positioned below the first guide rod, and two ends of the threaded rod are respectively connected with the two first fixing seats in a shaft way;

the motor is fixedly arranged on the base, and an output shaft of the motor is fixedly connected with one end of the threaded rod, which is far away from the fixing assembly;

and the sliding block mechanism is sleeved on the two first guide rods in a sliding way, and is screwed with the threaded rod.

Further, the slider mechanism includes:

the first sliding blocks are arranged on the two first guide rods in a sliding manner;

the second sliding block is sleeved on the two first guide rods in a sliding manner, a first rectangular groove is formed in the upper end of the first sliding block, and the second sliding block is positioned in the first rectangular groove;

the rotary joint block is fixedly connected with the first sliding block and is in rotary joint with the threaded rod.

Further, the fixing assembly includes:

the first connecting piece is fixedly arranged on the base, and a second rectangular groove is formed at the upper end of the first connecting piece;

the number of the guide bolts is two, the length direction of the two guide bolts is consistent with the length direction of the first guide rod, the two guide bolts are arranged at intervals along the direction perpendicular to the length direction of the first guide rod, and the two guide bolts are fixedly arranged on the first connecting piece;

and the third sliding block is sleeved on the two guide bolts in a sliding way and is positioned in the second rectangular groove.

Further, the clamp assembly includes:

the number of the second fixing seats is two, the two second fixing seats are fixedly arranged on the second sliding block, and the two second fixing seats are arranged at intervals along the direction perpendicular to the first guide rod;

the two guide rods are in a horizontal state, the length directions of the two guide rods are perpendicular to the length direction of the first guide rod, the two guide rods are arranged at intervals in the vertical direction, and two ends of each guide rod are fixedly connected with the two second fixing seats;

the number of the sliding arms is two, the two sliding arms are symmetrically distributed, and the two sliding arms are both in sliding connection with the two second guide rods;

the number of the clamping blocks is two, the two clamping blocks are symmetrically distributed, the two clamping blocks are oppositely arranged, and the two clamping blocks are respectively and fixedly arranged at the upper ends of the two sliding arms;

the cylinder is in a vertical inverted state, the cylinder is fixedly arranged on the second sliding block, the cylinder is positioned below the second guide rod and is positioned in the middle of the two sliding arms, and the output end of the cylinder is hinged with the lower ends of the two sliding arms.

Further, the output end of the cylinder is hinged with the lower ends of the two sliding arms through a second connecting piece and two connecting rods, the middle part of the second connecting piece is fixedly connected with the output end of the cylinder, the length direction of the second connecting piece is parallel to the length direction of the second guide rod, the lower ends of the two connecting rods are respectively hinged with the two ends of the second connecting piece, and the upper end of each connecting rod is respectively hinged with the lower end of the corresponding sliding arm to the second guide rod.

Further, the detection assembly includes:

the two pressure sensors are fixedly arranged on the first sliding block and the first connecting piece respectively, the end part of one sensor is abutted against the side wall of the second sliding block, which is close to the first connecting piece, and the end part of the other sensor is abutted against the side wall of the third sliding block, which is close to the second sliding block;

and the force value display is fixedly arranged on the base and is connected with the two pressure sensors.

Further, the clamping blocks are fixedly connected with the sliding arms through third connecting pieces, and reinforcing ribs are formed on the third connecting pieces.

Compared with the prior art, the invention has the following beneficial effects: firstly, two groups of clamp devices are used for clamping two bushings respectively, one of the clamps is driven to move by the pulling-out assembly, one of the bushings is pulled out of the stabilizer bar, the adhesive force detection of the bushing is completed, the automatic detection is completed, and the detection working intensity is reduced;

and secondly, the two clamp assemblies are respectively abutted against the two pressure sensors, and after one of the pressure sensors fails, the test can still be continued, and maintenance personnel maintain the equipment when the equipment is idle, so that detection delay caused by waiting for maintenance is avoided.

Drawings

FIG. 1 is a schematic perspective view of an embodiment;

FIG. 2 is an enlarged schematic view of FIG. 1A of an embodiment;

FIG. 3 is a schematic perspective view of a pull-out assembly of an embodiment;

FIG. 4 is a schematic perspective view of a slider mechanism of an embodiment;

FIG. 5 is a schematic perspective view of a securing assembly of an embodiment;

FIG. 6 is a schematic perspective view of a clamp assembly of an embodiment;

FIG. 7 is an enlarged schematic view at B in FIG. 1 of an embodiment;

fig. 8 is a schematic perspective view of a third connector according to an embodiment.

The reference numerals in the figures are: 1-a base; 2-pulling out the assembly; 3-fixing the assembly; 4-a clamp assembly; 5-a detection assembly; 6-a first fixing seat; 7-a first guide bar; 8-a threaded rod; 9-a motor; 10-a slider mechanism; 11-a first slider; 12-a second slider; 13-a first rectangular slot; 14-screwing the block; 15-a first connector; 16-a second rectangular slot; 17-a guide pin; 18-a third slider; 19-a second fixing seat; 20-a second guide bar; 21-a slide arm; 22-clamping blocks; 23-cylinder; 24-a second connector; 25-connecting rods; 26-a pressure sensor; 27-force value display; 28-a stabilizer bar; 29-a bushing; 30-a third connector; 31-reinforcing ribs.

Detailed Description

The invention will be further described in detail with reference to the drawings and the detailed description below, in order to further understand the features and technical means of the invention and the specific objects and functions achieved.

Referring to fig. 1 to 8, an automatic detection device for the adhesion force of a stabilizer bar bushing includes:

a base 1 in a horizontal state;

the pulling-out assembly 2 is fixedly arranged on the base 1, and the pulling-out assembly 2 is provided with a horizontally moving output end;

the fixing component 3 is fixedly arranged on the base 1, the fixing component 3 is positioned beside the pulling-out component 2, and the fixing component 3 is positioned in the moving direction of the output end of the pulling-out component 2;

the number of the clamp assemblies 4 is two, the two clamp assemblies 4 are oppositely arranged, the two clamp assemblies 4 are respectively used for clamping the two bushings 29, and the two clamp assemblies 4 are respectively fixedly arranged on the output end of the pulling-out assembly 2 and the fixing assembly 3;

and a detection assembly 5 for detecting the adhesion of the bush 29.

When two bushings 29 are adhered to the stabilizer bar 28 and the adhesion test of the bushings 29 is needed, the two groups of clamp assemblies 4 are clamped by the bushings 29 respectively, the pull-out assembly 2 drives one clamp assembly 4 to move away from the other group of clamp assemblies 4, the detection assembly 5 detects the pulling force of the pull-out assembly 2, when one of the bushings 29 is pulled out from the stabilizer bar 28, the control terminal detects that the numerical value of the detection assembly 5 protrudes to be reduced, the control terminal is in the prior art, the control terminal is not shown in the figure, and the control terminal controls the pull-out assembly 2 to restore to the original position.

The extraction assembly 2 comprises:

the number of the first fixing seats 6 is two, the two first fixing seats 6 are fixedly arranged on the base 1, and the two first fixing seats 6 are arranged at intervals along the linear direction;

the number of the first guide rods 7 is two, the two first guide rods 7 are in a horizontal state, the two first guide rods 7 are arranged at intervals along the direction perpendicular to the length direction, and two ends of each first guide rod 7 are fixedly connected with the two first fixing seats 6 respectively;

the axis of the threaded rod 8 is parallel to the axis of the first guide rod 7, the threaded rod 8 is positioned below the first guide rod 7, and two ends of the threaded rod 8 are respectively connected with the two first fixing seats 6 in a shaft way;

the motor 9 is fixedly arranged on the base 1, and an output shaft of the motor 9 is fixedly connected with one end of the threaded rod 8 far away from the fixed assembly 3;

the sliding block mechanism 10 is sleeved on the two first guide rods 7 in a sliding manner, and the sliding block mechanism 10 is screwed with the threaded rod 8.

When the assembly 2 needs to be pulled out for starting, the motor 9 is started to drive the threaded rod 8 to rotate, the threaded rod 8 drives the sliding block mechanism 10 to slide on the two first guide rods 7 in a direction away from the fixed assembly 3, and accordingly the clamp assembly 4 is driven to move in a direction away from the other group of clamp assemblies 4 until one of the bushings 29 is pulled up by the stabilizing rod 28.

The slider mechanism 10 includes:

a first slider 11 slidably provided on the two first guide bars 7;

the second slide blocks 12 are sleeved on the two first guide rods 7 in a sliding manner, a first rectangular groove 13 is formed at the upper end of each first slide block 11, and the second slide blocks 12 are positioned in the first rectangular grooves 13;

the screwing block 14 is fixedly connected with the first sliding block 11, and the screwing block 14 is screwed with the threaded rod 8.

When the pull-out assembly 2 is started, the threaded rod 8 drives the screwing block 14 to move in a direction away from the fixed assembly 3, the screwing block 14 drives the first sliding blocks 11 to move in a direction away from the fixed assembly 3 on the two first guide rods 7, and accordingly the second sliding blocks 12 are driven to move in a direction away from the fixed assembly 3 on the two first guide rods 7, and the second sliding blocks 12 drive the clamp assemblies 4 to move in a direction away from the other group of clamp assemblies 4.

The fixing assembly 3 includes:

a first connecting member 15 fixedly provided on the base 1 and having a second rectangular groove 16 formed at an upper end thereof;

the number of the guide bolts 17 is two, the length direction of the two guide bolts 17 is consistent with the length direction of the first guide rod 7, the two guide bolts 17 are arranged at intervals along the direction perpendicular to the length direction of the first guide rod 7, and the two guide bolts 17 are fixedly arranged on the first connecting piece 15;

and a third sliding block 18 which is sleeved on the two guide bolts 17 in a sliding way, and the third sliding block 18 is positioned in the second rectangular groove 16.

When one of the bushings 29 is pulled out to move in a direction away from the fixed component 3, the other bushing 29 is driven to move by the stabilizer bar 28, and the third sliding block 18 is driven to move towards the two guide bolts 17 by the clamp component 4, so that the third sliding block is abutted against the detection component 5.

The clamp assembly 4 includes:

the number of the second fixing seats 19 is two, the two second fixing seats 19 are fixedly arranged on the second sliding block 12, and the two second fixing seats 19 are arranged at intervals along the direction perpendicular to the first guide rod 7;

the number of the second guide rods 20 is two, the two second guide rods 20 are in a horizontal state, the length direction of the two second guide rods 20 is perpendicular to the length direction of the first guide rod 7, the two second guide rods 20 are arranged at intervals along the vertical direction, and two ends of each second guide rod 20 are fixedly connected with two second fixing seats 19;

the number of the sliding arms 21 is two, the two sliding arms 21 are symmetrically distributed, and the two sliding arms 21 are in sliding connection with the two second guide rods 20;

the number of the clamping blocks 22 is two, the two clamping blocks 22 are symmetrically distributed, the two clamping blocks 22 are oppositely arranged, and the two clamping blocks 22 are fixedly arranged at the upper ends of the two sliding arms 21 respectively;

the air cylinder 23 is in a vertical inverted state, the air cylinder 23 is fixedly arranged on the second sliding block 12, the air cylinder 23 is positioned below the second guide rod 20, the air cylinder 23 is positioned right in the middle of the two sliding arms 21, and the output end of the air cylinder 23 is hinged with the lower ends of the two sliding arms 21.

The output end of the air cylinder 23 is hinged with the lower ends of the two sliding arms 21 through a second connecting piece 24 and two connecting rods 25, the middle part of the second connecting piece 24 is fixedly connected with the output end of the air cylinder 23, the length direction of the second connecting piece 24 is parallel to the length direction of the second guide rod 20, the lower ends of the two connecting rods 25 are respectively hinged with the two ends of the second connecting piece 24, and the upper end of each connecting rod 25 is respectively hinged with the lower end of the corresponding sliding arm 21 to the second guide rod.

When the bushing 29 needs to be clamped, the output end of the air cylinder 23 moves vertically downwards to drive the second connecting piece 24 to move vertically downwards, the second connecting piece 24 drives the lower ends of the two connecting rods 25 to move vertically downwards, and the upper ends of the two connecting rods 25 are close to each other, so that the two sliding arms 21 are driven to be close to each other on the two second guide rods 20, and the two clamping blocks 22 are driven to clamp the bushing 29.

The detection assembly 5 comprises:

the number of the pressure sensors 26 is two, the two pressure sensors 26 are respectively fixedly arranged on the first sliding block 11 and the first connecting piece 15, the end part of one sensor is in contact with the side wall of the second sliding block 12 close to the first connecting piece 15, and the end part of the other sensor is in contact with the side wall of the third sliding block 18 close to the second sliding block 12;

a force value display 27, which is fixedly arranged on the base 1, is connected to the two pressure sensors 26.

When the pull-out assembly 2 is started, the first sliding block 11 is driven to move in a direction away from the fixed assembly 3, the first sliding block 11 drives the pressure sensor 26 to move in a direction away from the fixed assembly 3, the end part of the sensor is abutted against the first sliding block 11, and the second sliding block 12 is indirectly driven to move, so that the tensile force is detected.

The other group of fixture device drives the third sliding block 18 to move towards the direction close to the pulling-out assembly 2, so that the third sliding block 18 is tightly abutted against the other pressure sensor 26, the tension value is detected, the number of the two pressure sensors 26 can ensure that the data are correct, one pressure sensor 26 is prevented from being failed, the detected value is displayed through the force value display 27, and the tension is the adhesive force of the bushing 29.

The clamping block 22 is fixedly connected with the sliding arm 21 through a third connecting piece 30, and reinforcing ribs 31 are formed on the third connecting piece.

During the extraction of the bushing 29, the clamping blocks 22 need to withstand a great force and therefore require reinforcing ribs 31 for reinforcement.

The foregoing examples merely illustrate one or more embodiments of the invention, which are described in greater detail and are not to be construed as limiting the scope of the invention. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the invention, which are all within the scope of the invention. Accordingly, the scope of protection of the present invention is to be determined by the appended claims.

Claims (5)

1. The utility model provides a stabilizer bar bush's adhesion automated inspection device which characterized in that includes:

a base (1) in a horizontal state;

the pulling-out assembly (2) is fixedly arranged on the base (1), and the pulling-out assembly (2) is provided with a horizontally moving output end;

the fixing component (3) is fixedly arranged on the base (1), the fixing component (3) is positioned beside the pulling-out component (2), and the fixing component (3) is positioned in the moving direction of the output end of the pulling-out component (2);

the two clamp assemblies (4) are arranged oppositely, the two clamp assemblies (4) are respectively used for clamping the two bushings (29), and the two clamp assemblies (4) are respectively and fixedly arranged at the output end of the pull-out assembly (2) and the fixing assembly (3);

a detection assembly (5) for detecting the adhesion of the bush (29);

the extraction assembly (2) comprises:

the number of the first fixing seats (6) is two, the two first fixing seats (6) are fixedly arranged on the base (1), and the two first fixing seats (6) are arranged at intervals along the linear direction;

the number of the first guide rods (7) is two, the two first guide rods (7) are in a horizontal state, the two first guide rods (7) are arranged at intervals along the direction perpendicular to the length direction, and two ends of each first guide rod (7) are fixedly connected with the two first fixing seats (6) respectively;

the axis of the threaded rod (8) is parallel to the axis of the first guide rod (7), the threaded rod (8) is positioned below the first guide rod (7), and two ends of the threaded rod (8) are respectively in shaft connection with the two first fixing seats (6);

the motor (9) is fixedly arranged on the base (1), and an output shaft of the motor (9) is fixedly connected with one end of the threaded rod (8) far away from the fixed component (3);

the sliding block mechanism (10) is sleeved on the two first guide rods (7) in a sliding manner, and the sliding block mechanism (10) is in screwed connection with the threaded rod (8);

the slider mechanism (10) includes:

a first slider (11) slidably provided on the two first guide bars (7);

the second sliding blocks (12) are sleeved on the two first guide rods (7) in a sliding mode, first rectangular grooves (13) are formed in the upper ends of the first sliding blocks (11), and the second sliding blocks (12) are located in the first rectangular grooves (13);

the rotary joint block (14) is fixedly connected with the first sliding block (11), and the rotary joint block (14) is in rotary joint with the threaded rod (8);

the clamp assembly (4) comprises:

the number of the second fixing seats (19) is two, the two second fixing seats (19) are fixedly arranged on the second sliding block (12), and the two second fixing seats (19) are arranged at intervals along the direction perpendicular to the first guide rod (7);

the two second guide rods (20) are horizontally arranged, the length direction of the two second guide rods (20) is perpendicular to the length direction of the first guide rod (7), the two second guide rods (20) are arranged at intervals along the vertical direction, and two ends of each second guide rod (20) are fixedly connected with two second fixing seats (19);

the number of the sliding arms (21) is two, the two sliding arms (21) are symmetrically distributed, and the two sliding arms (21) are both in sliding connection with the two second guide rods (20);

the number of the clamping blocks (22) is two, the two clamping blocks (22) are symmetrically distributed, the two clamping blocks (22) are oppositely arranged, and the two clamping blocks (22) are fixedly arranged at the upper ends of the two sliding arms (21) respectively;

the air cylinder (23) is in a vertical inverted state, the air cylinder (23) is fixedly arranged on the second sliding block (12), the air cylinder (23) is positioned below the second guide rod (20), the air cylinder (23) is positioned in the middle of the two sliding arms (21), and the output end of the air cylinder (23) is hinged with the lower ends of the two sliding arms (21).

2. An automatic detection device of the adhesion of stabilizer bar bushings according to claim 1, characterized in that said fixing assembly (3) comprises:

the first connecting piece (15) is fixedly arranged on the base (1), and a second rectangular groove (16) is formed at the upper end of the first connecting piece;

the number of the guide bolts (17) is two, the length direction of the two guide bolts (17) is consistent with the length direction of the first guide rod (7), the two guide bolts (17) are arranged at intervals along the direction perpendicular to the length direction of the first guide rod (7), and the two guide bolts (17) are fixedly arranged on the first connecting piece (15);

and the third sliding block (18) is sleeved on the two guide bolts (17) in a sliding way, and the third sliding block (18) is positioned in the second rectangular groove (16).

3. The automatic detection device for the adhesive force of the stabilizer bar bushing according to claim 1, wherein the output end of the air cylinder (23) is hinged with the lower ends of the two sliding arms (21) through a second connecting piece (24) and two connecting rods (25), the middle part of the second connecting piece (24) is fixedly connected with the output end of the air cylinder (23), the length direction of the second connecting piece (24) is parallel to the length direction of the second guide rod (20), the lower ends of the two connecting rods (25) are respectively hinged with the two ends of the second connecting piece (24), and the upper end of each connecting rod (25) is respectively hinged with the lower end of the corresponding sliding arm (21) to the second guide rod.

4. An automatic detection device of the adhesion of stabilizer bar bushings according to claim 2, characterized in that said detection assembly (5) comprises:

the two pressure sensors (26) are fixedly arranged on the first sliding block (11) and the first connecting piece (15) respectively, the end part of one sensor is in contact with the side wall of the second sliding block (12) close to the first connecting piece (15), and the end part of the other sensor is in contact with the side wall of the third sliding block (18) close to the second sliding block (12);

and a force value display (27) fixedly arranged on the base (1) and connected with the two pressure sensors (26).

5. The automatic detection device for the adhesion force of the stabilizer bar bushing according to claim 1, wherein the clamping block (22) is fixedly connected with the sliding arm (21) through a third connecting piece (30), and reinforcing ribs (31) are formed on the third connecting piece.