CN217845135U - A precision measurement device for roller production - Google Patents

Abstract

The utility model relates to a detection device especially relates to a precision detection device for roller production. The utility model provides a higher precision detection device that is used for roller production of work efficiency. The utility model provides a precision detection device for roller production, including base, support shell, display, step motor and first supporting block etc. base top left side is connected with the support shell, supports the anterior left upper portion position of shell and installs the display, and base upper portion left side is installed and is driven roller pivoted step motor, and step motor is located inside the support shell, and base top left side is connected with first supporting block. The utility model discloses a first frame of placing and the second frame of placing can carry on spacingly to the roller, then can drive the roller through step motor as drive power, can drive the contact piece and move right simultaneously, when roller extrusion contact piece up-going, then represent this roller unqualifiedly.

Description

A precision measurement device for roller production

Technical Field

The utility model relates to a detection device especially relates to a precision detection device for roller production.

Background

With the rapid development of buildings and industries, the number of conveyor belts used in actual production activities is more and more, which means that the market demand of rollers is higher and higher in the field of industrial transmission, but in the production process of the rollers, partial defective products are inevitable to appear, the defective products cannot be installed in actual engineering for use, accidents easily occur, and the rollers need to be subjected to precision detection before being delivered out of a warehouse.

At present, the roller diameter measurement method generally adopts a vernier caliper and a micrometer to carry out measurement manually, a certain error is usually generated in the manual measurement process, the manual measurement is carried out through equidistant point taking measurement, the error of the manual measurement is large, the measurement process is slow, and the working efficiency is low.

Therefore, a precision detection device for roller production with high work efficiency needs to be designed.

SUMMERY OF THE UTILITY MODEL

In order to overcome the defects that the manual measurement has large error, the measurement process is slow, and the working efficiency is low, the technical problem is as follows: the precision detection device for roller production is high in working efficiency.

A precision detection device for roller production comprises a base, a support shell, a display, a stepping motor, a first support block, a first placing frame, a sliding block, a second placing frame, a first spring, a first gear, a second support block, a second rotating shaft, a second gear, a missing gear, a first rotating shaft, a third gear, a third support block, a sliding frame, a screw rod, a distance sensor, a driving wheel, a driving belt, a contact block and a second spring, wherein the left side of the top of the base is connected with the support shell, the display is arranged at the upper part of the left side of the front part of the support shell, the stepping motor capable of driving a roller to rotate is arranged at the left side of the upper part of the base, the stepping motor is positioned in the support shell, the first support block is connected with the left side of the top of the base and is positioned at the right side of the stepping motor, the first placing frame used for limiting the roller is rotatably arranged at the upper part of the first support block, the left side of a first placing frame is connected with an output shaft of a stepping motor through a coupler, the right side in the base is slidably provided with a sliding block, the upper part of the sliding block is rotatably provided with a second placing frame, the first placing frame corresponds to the second placing frame, two first springs are connected between the lower part of the right side of the sliding block and the base, the output shaft of the stepping motor is connected with a first gear, the top of the first supporting block is connected with a second supporting block, the lower part of the second supporting block is rotatably provided with a second rotating shaft, the left end of the second rotating shaft is connected with a second gear, the second gear is meshed with the first gear, the left end of the second rotating shaft is connected with a gear lack which is positioned on the right side of the second gear, the upper part of the second supporting block is rotatably provided with a first rotating shaft, the left end of the first rotating shaft is connected with a third gear, the gear can be meshed with the third gear when rotating, the left side and the right side of the upper part of the supporting shell are symmetrically connected with third supporting blocks in a front-back mode, support shell upper portion left side slidingtype and be equipped with the carriage, the rotary type is equipped with the lead screw between two third supporting shoes of front side, the rotary type is equipped with the lead screw between two third supporting shoes of rear side, two lead screw left sides and carriage threaded connection, distance sensor is installed on carriage upper portion, first rotation axis right-hand member is connected with the drive wheel, two lead screw left ends all are connected with the drive wheel, around there being the drive belt between the three drive wheel, the slidingtype is equipped with and is used for carrying out the contact piece of precision measurement to the roller in the middle of the carriage lower part, contact piece upper portion is around having the second spring, the second spring both ends are connected with carriage and contact piece respectively.

As a further preferred scheme, the roller clamping device further comprises slide bars, clamping blocks and third springs, wherein four slide bars are arranged on the outer side of the first placing frame and the outer side of the second placing frame in an evenly spaced sliding mode, the inner sides of the four adjacent slide bars are connected with the clamping blocks used for clamping rollers, the outer sides of the eight slide bars are wound with the third springs, two ends of the four third springs on the left side are connected with the first placing frame and the slide bars respectively, and two ends of the four third springs on the right side are connected with the second placing frame and the slide bars respectively.

As a further preferable scheme, the roller support device further comprises fourth supporting blocks and a supporting cylinder, wherein the four fourth supporting blocks are connected to the middle position of the top of the base, the supporting cylinder for supporting the roller is rotatably arranged between the two fourth supporting blocks on the front side, and the supporting cylinder is also rotatably arranged between the two fourth supporting blocks on the rear side.

As a further preferable scheme, the lower part of the right side of the sliding block is connected with a pull handle.

As a further preferable scheme, the clamping device further comprises a non-slip mat, and the inner sides of the eight clamping blocks are connected with the non-slip mat.

As a further preferred option, the first spring is a compression spring.

The above-mentioned right has been adopted the utility model discloses the description of structure can know, the utility model discloses a design departure point, theory and advantage are:

1. the utility model discloses a first frame of placing and the second frame of placing can carry on spacingly to the roller, then can drive the roller through step motor as drive power, can drive the contact piece and move right simultaneously, when roller extrusion contact piece up-going, then represent this roller unqualifiedly.

2. The utility model discloses thereby better drive cylinder rotates.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a schematic view of a partial three-dimensional structure of the present invention.

Fig. 3 is a schematic perspective view of the lead screw, the sliding rack, the distance sensor, and the contact block.

Fig. 4 is a schematic perspective view of components such as the stepping motor, the first support block, and the first support frame.

Wherein: 1: base, 2: supporting shell, 3: display, 4: step motor, 5: first support block, 6: first placement frame, 7: a slide block, 8: second placement frame, 9: first spring, 10: first gear, 11: second support block, 12: second gear, 13: missing gear, 14: third gear, 15: a transmission wheel, 16: drive belt, 17: third support block, 18: screw, 19: carriage, 20: distance sensor, 21: contact block, 22: second spring, 23: slide bar, 24: clamping block, 25: third spring, 26: first rotation shaft, 27: second rotation axis, 28: pull handle, 29: non-slip mat, 30: fourth support block, 31: a support cylinder.

Detailed Description

The following further describes the technical solution with reference to specific embodiments, and it should be noted that: the words upper, lower, left, right, etc. used herein to indicate orientation are simply for the location of the illustrated structure in the corresponding figures. The serial numbers of the parts are themselves numbered herein, for example: first, second, etc. are used solely to distinguish one from another as to objects described herein, and do not have any sequential or technical meaning. The application states that: the connection and coupling, unless otherwise indicated, include both direct and indirect connections (couplings).

Example 1

As shown in fig. 1-4, a precision detection device for roller production comprises a base 1, a support shell 2, a display 3, a stepping motor 4, a first support block 5, a first placing frame 6, a slider 7, a second placing frame 8, a first spring 9, a first gear 10, a second support block 11, a second rotating shaft 27, a second gear 12, a missing gear 13, a first rotating shaft 26, a third gear 14, a third support block 17, a sliding frame 19, a lead screw 18, a distance sensor 20, a transmission wheel 15, a transmission belt 16, a contact block 21 and a second spring 22, wherein the support shell 2 is connected to the left side of the top of the base 1, the display 3 is installed at the upper portion of the front left side of the support shell 2, the stepping motor 4 is bolted to the left side of the upper portion of the base 1, the stepping motor 4 is located inside the support shell 2, the left side of the top of the base 1 is welded with the first support block 5, the first support block 5 is located on the right side of the base 1, the first support block 5 is connected to the right side of the base 1, the slider 7 is connected to the sliding type gear 7, the sliding type bearing frame 7, the slider 7 is connected to the right side of the second rotating type, the second rotating type gear 13, the rotating type second rotating shaft 12 is connected to the sliding type second rotating type bearing block 13, the sliding type of the sliding type gear 13, the sliding type bearing 12 is connected to the second rotating type bearing block 12, the sliding type rack 12, the sliding type of the sliding type rack 12, the second rotating type rack 12 is connected to the left side of the rotating shaft 12, the upper portion of the second supporting block 11 is rotatably provided with a first rotating shaft 26, the left end of the first rotating shaft 26 is connected with a third gear 14, the missing gear 13 can be meshed with the third gear 14 when rotating, the left side and the right side of the upper portion of the supporting shell 2 are symmetrically connected with the third supporting blocks 17 in a front-back manner, the left side of the upper portion of the supporting shell 2 is slidably provided with a sliding frame 19, a screw rod 18 is rotatably arranged between the two third supporting blocks 17 at the front side, the left side of each screw rod 18 is in threaded connection with the corresponding sliding frame 19, a distance sensor 20 is installed on the upper portion of the corresponding sliding frame 19, the right end of the first rotating shaft 26 is connected with a driving wheel 15, the left ends of the two screw rods 18 are connected with driving wheels 15, driving belts 16 are wound among the three driving wheels 15, a contact block 21 is arranged in the middle of the lower portion of the sliding frame 19 in a sliding manner, the stepping motor 4 can drive the roller to rotate, the contact block 21 can be driven to move rightwards to perform precision detection on the roller, the contact block 21 is wound with a second spring 22, the two ends of the second spring 22 are respectively connected with the sliding frame 19 and the contact block 21, and the first placing frame 6 and the second placing frame 8 are mainly used for limiting the roller.

When the device is needed to be used, a worker puts the device at an appointed position, then pulls the slide block 7 rightwards, the first spring 9 is compressed to drive the second placing frame 8 to move rightwards, then puts the roller between the first placing frame 6 and the second placing frame 8, then loosens the slide block 7, the first spring 9 recovers the original state to drive the slide block 7 and the second placing frame 8 to slide leftwards and reset, so that the first placing frame 6 and the second placing frame 8 can fix the roller to enable the roller to be contacted with the contact block 21, then the worker starts the stepping motor 4 and the distance sensor 20, the rotating speed of an output shaft of the stepping motor 4 is slow, an output shaft of the stepping motor 4 can drive the first placing frame 6 to rotate, further drive the roller and the second placing frame 8 to rotate, meanwhile, the first gear 10 of an output shaft rotating belt of the stepping motor 4 rotates, so as to drive the second gear 12 and the missing gear 13 to rotate, when the gear lack 13 is meshed with the third gear 14, the third gear 14 and the first rotating shaft 26 are driven to rotate, the first rotating shaft 26 can drive the screw rod 18 to rotate through the driving wheel 15 and the driving belt 16, the screw rod 18 can drive the sliding frame 19, the distance sensor 20 and the contact block 21 to move rightwards, when the gear lack 13 is separated from the third gear 14, the contact block 21 stops moving, so that the contact block 21 intermittently moves rightwards, when the surface of the roller is provided with a bulge, the bulge can extrude the contact block 21 to move upwards, the second spring 22 is compressed, the distance sensor 20 can detect the distance change between the distance sensor and the contact block 21 and transmit data to the display 3 to display, the accuracy of the roller is unqualified, when the bulge is separated from the contact block 21, the second spring 22 recovers to the original state to drive the contact block 21 to move downwards to reset, if the in-process of contact piece 21 right movement, do not up move the case, it is qualified to show this roller precision, accomplish the precision detection back, the staff closes step motor 4 and distance sensor 20, pulls slider 7 and slides right again, first spring 9 compression, then will detect the roller and take out, loosen slider 7 afterwards, first spring 9 reconversion can drive the second and place frame 8 and slide left and reset, first spring 9 is compression spring, can drive slider 7 and reset.

Example 2

As shown in fig. 2, based on embodiment 1, the roller clamping device further includes four sliding rods 23, clamping blocks 24, and third springs 25, four sliding rods 23 are uniformly arranged on the outer side of the first placing frame 6 and the outer side of the second placing frame 8 at intervals in a sliding manner, the clamping blocks 24 are fixedly connected to the inner sides of the four adjacent sliding rods 23, the third springs 25 are wound around the outer sides of the eight sliding rods 23, two ends of the four third springs 25 on the left side are respectively connected with the first placing frame 6 and the sliding rods 23, two ends of the four third springs 25 on the right side are respectively connected with the second placing frame 8 and the sliding rods 23, and the clamping blocks can be driven to move inwards to clamp the rollers under the action of the elastic force of the third springs.

When the staff put the roller first place the frame 6 and the second place between the frame 8, the roller can extrude clamp splice 24 and slide bar 23 toward the outside motion, the third spring 25 is tensile, under the spring action of third spring 25, can make clamp splice 24 press from both sides the roller tightly, thereby the drive roller that can be better rotates, when the staff takes out the roller, roller and clamp splice 24 separation, third spring 25 reconversion drives slide bar 23 and clamp splice 24 toward the inside motion and resets.

As shown in fig. 1, the roller support device further comprises fourth supporting blocks 30 and a supporting cylinder 31, the four fourth supporting blocks 30 are welded at the middle position of the top of the base 1, the supporting cylinder 31 is rotatably arranged between the two fourth supporting blocks 30 at the front side, the supporting cylinder 31 is also rotatably arranged between the two fourth supporting blocks 30 at the rear side, and a worker places a roller on the supporting roller which can support the roller.

When the staff put the roller between first frame 6 and the second frame 8 of placing, the roller is located between two support drum 31 tops, and support drum 31 can support the roller, makes things convenient for the staff to carry out the precision detection operation to the roller.

As shown in fig. 2, the utility model also comprises a pull handle 28, and the lower part of the right side of the slide block 7 is connected with the pull handle 28.

The staff can better pull the slider 7 to slide rightwards through the pull handle 28, so that the staff can fix the roller conveniently.

As shown in FIG. 2, the clamping device further comprises a non-slip mat 29, and the non-slip mat 29 is connected to the inner sides of the eight clamping blocks 24.

The non-slip mat 29 increases the friction between the clamping blocks 24 and the roller, making the roller more stable.

It should be understood that this example is for illustrative purposes only and is not intended to limit the scope of the present invention. Furthermore, it should be understood that various changes and modifications of the present invention may be made by those skilled in the art after reading the teachings of the present invention, and these equivalents also fall within the scope of the appended claims.

Claims (6)

1. A precision detection device for roller production is characterized by comprising a base (1), a support shell (2), a display (3), a stepping motor (4), a first support block (5), a first placing frame (6), a slider (7), a second placing frame (8), a first spring (9), a first gear (10), a second support block (11), a second rotating shaft (27), a second gear (12), a gear lacking wheel (13), a first rotating shaft (26), a third gear (14), a third support block (17), a sliding frame (19), a screw rod (18), a distance sensor (20), a transmission wheel (15), a transmission belt (16), a contact block (21) and a second spring (22), wherein the support shell (2) is connected to the left side of the top of the base (1), the display (3) is installed at the upper portion of the left side of the front portion of the support shell (2), the stepping motor (4) capable of driving a roller to rotate is installed at the left side of the upper portion of the base (1), the stepping motor (4) is located inside the support shell (2), the first support block (5) is connected to the left side of the top of the base (1), the first support block (5) is located at the right side of the upper portion of the first support block (6) and is used for rotatably placing the first support block (6), the left side of a first placing frame (6) is connected with an output shaft of a stepping motor (4) through a coupler, a sliding block (7) is arranged on the right side in a sliding manner in a base (1), a second placing frame (8) is arranged on the upper portion of the sliding block (7) in a rotating manner, the first placing frame (6) corresponds to the second placing frame (8), two first springs (9) are connected between the lower portion of the right side of the sliding block (7) and the base (1), a first gear (10) is connected onto the output shaft of the stepping motor (4), a second supporting block (11) is connected to the top of a first supporting block (5), a second rotating shaft (27) is arranged on the lower portion of the second supporting block (11) in a rotating manner, a second gear (12) is connected to the left end of the second rotating shaft (27), the second gear (12) is meshed with the first gear (10), a third gear (14) is connected to the left end of the second rotating shaft (27), the third gear (13) is arranged on the right side of the second gear (12), a sliding support shell (17) and a sliding support shell (17) is symmetrically arranged on the left side and right side of the third rotating housing (2), screw rod (18) are arranged between two third supporting blocks (17) of the front side in a rotating mode, screw rod (18) are arranged between two third supporting blocks (17) of the rear side in a rotating mode, the left sides of the two screw rods (18) are in threaded connection with a sliding frame (19), a distance sensor (20) is installed on the upper portion of the sliding frame (19), a driving wheel (15) is connected to the right end of a first rotating shaft (26), the left ends of the two screw rods (18) are connected with the driving wheel (15), a driving belt (16) is wound between the three driving wheels (15), a contact block (21) used for conducting precision detection on a roller is arranged in the middle of the lower portion of the sliding frame (19) in a sliding mode, a second spring (22) is wound on the upper portion of the contact block (21), and the two ends of the second spring (22) are connected with the sliding frame (19) and the contact block (21) respectively.

2. The precision detection device for roller production according to claim 1, further comprising slide bars (23), clamping blocks (24) and third springs (25), wherein four slide bars (23) are arranged on the outer side of the first placing frame (6) and the outer side of the second placing frame (8) in a sliding manner at equal intervals, the inner sides of the four adjacent slide bars (23) are connected with the clamping blocks (24) for clamping the rollers, the outer sides of the eight slide bars (23) are wound with the third springs (25), two ends of the four third springs (25) on the left side are respectively connected with the first placing frame (6) and the slide bars (23), and two ends of the four third springs (25) on the right side are respectively connected with the second placing frame (8) and the slide bars (23).

3. The precision detecting device for roller production according to claim 1, further comprising a fourth supporting block (30) and a supporting cylinder (31), wherein four fourth supporting blocks (30) are connected to the middle position of the top of the base (1), the supporting cylinder (31) for supporting the roller is rotatably disposed between the two fourth supporting blocks (30) at the front side, and the supporting cylinder (31) is rotatably disposed between the two fourth supporting blocks (30) at the rear side.

4. The precision detecting device for roller production as claimed in claim 1, characterized in that a pull handle (28) is connected to the lower part of the right side of the sliding block (7).

5. The precision detecting device for roller production as claimed in claim 2, characterized in that it further comprises anti-skid pads (29), and the anti-skid pads (29) are connected to the inner sides of the eight clamping blocks (24).

6. An accuracy testing device for the production of drums according to claim 1, characterized in that the first spring (9) is a compression spring.

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