CN117206207A - Automatic detection process for straightness of slender roller shaft of rubber roller - Google Patents

Abstract

The application discloses an automatic detection process for straightness of an elongated roll shaft of a rubber roll, which comprises the following steps: s1, feeding root by root; s2, transferring and detecting an elongated roll shaft; s3, sorting. On one hand, the application automatically and sequentially performs feeding, detecting and sorting, thereby not only being convenient to operate, but also having high accuracy of detection results and low cost; on the other hand, the two ends of the slender roll shaft are supported in a free rolling way, the axial movement is limited under the pressing drive of a driving wheel at one end, the vertical movement and the horizontal movement are also limited under the rotation in a constant space, and the accurate deflection displacement is obtained under a constant and uniform detection standard; according to the third aspect, according to roll shaft sliding speeds with different diameters, the angle of the formed inclined conveying surface can be adjusted and set for feeding, meanwhile, the long and thin roll shafts are ejected out and transferred under the relative movement of the bearing seat and the transfer module for convenient transfer, and a static-moving mode is adopted to rapidly sort qualified and unqualified products.

Description

Automatic detection process for straightness of slender roller shaft of rubber roller

The application relates to a divisional application of an automatic detection device for the straightness of an elongated roll shaft, which is named as a rubber roll, and has the application date of 2019, 5, 31 and 201910473445.4.

Technical Field

The invention belongs to the field of rubber roll shaft processing equipment, and particularly relates to an automatic detection process for straightness of an elongated roll shaft of a rubber roll.

Background

With the development of office automation equipment, finance and circulation equipment, most aspect ratios of the related shaft parts exceed 40, and in view of the functional requirements of the equipment, the straightness of the shaft belongs to an important quality element to be controlled and has high precision requirement. However, such elongated rolls are very subject to bending deformation during production and turnover due to their poor rigidity, both as raw materials and as products. To ensure quality, 100% inspection sorting must be performed on the semi-finished and finished axes.

At present, the sorting work in the industry is basically finished by manpower, two ends of a long shaft are placed on a bracket to be used as detection references, a dial indicator is arranged in the middle of the long shaft, one end of the long shaft is manually rotated, the maximum fluctuation of a dial indicator pointer is observed and read by rotating at least more than 2 circles in the circumferential direction, and whether the straightness meets the standard requirement is manually judged.

The specific process steps are as follows:

1. adjusting and determining reference positions and detection positions at two ends of the shaft;

2. feeding a single piece manually;

3. one end of the long shaft is rotated by more than 2 circles in the manual circumferential direction (the detection precision is affected by uneven manual rotation speed or force);

4. Visual synchronous observation of dial indicator fluctuation (visual method, error of detection data);

5. manually judging whether the straightness is qualified (judging accuracy is insufficient);

6. receiving materials by a manual single branch;

7. manual identification of acceptable and unacceptable products, manual box division (too relying on manual mixing risk)

The whole detection steps are longer, the detection process is completed by manpower, only single machine operation is realized, and meanwhile, the efficiency is low and the requirement of mass production cannot be met; when the manual rotation is performed, the manual intervention cannot ensure complete equality in terms of speed and force, and the operation detection precision of different people is different; in addition, the arms are always in a lifting state when the manual operation works, the waist and shoulder postures are tired when the manual operation works for a long time, and the labor intensity is high.

Disclosure of Invention

The invention aims to solve the technical problem of overcoming the defects of the prior art and providing an automatic detection process for the straightness of an elongated roller shaft of a rubber roller.

In order to solve the technical problems, the invention adopts the following technical scheme: an automatic detection process for straightness of an elongated roller shaft of a rubber roller comprises the following steps:

s1, feeding root by root

Pushing the tongue plate to eject from the stacking roller shaft by the air cylinder, wherein more than one roller shaft possibly exists in a material taking area formed by the top surface of the tongue plate and the frame plate, and then along with the rising of the material taking area, only one roller shaft can be erected in the material taking area, and the redundant roller shafts roll down to the stacking area until the top surface of the tongue plate is flush with the top surface of the frame plate, and then roll to the inclined conveying surface of the conveying plate and roll down to a trough to finish the single feeding of the roller shafts; after the feeding of the previous roll shaft is completed, the tongue plate returns to the stacking area, and the moving process is repeated, so that the continuous feeding of the roll shaft can be realized;

S2, transferring and detecting the slender roll shaft

After the first pushing piece pushes an elongated roll shaft in a trough of the feeding platform to the transfer module, the end part of the elongated roll shaft is abutted against the positioning leaning grid, then the second pushing piece moves the elongated roll shaft to the lower part of the monitor, at the moment, the two bearing seats are lifted upwards, the elongated roll shaft is ejected out of the transfer module from the two end parts of the elongated roll shaft to move towards the monitor, until the driving wheel is contacted with the upper surface of the end part of the elongated roll shaft, the rotation of the driving wheel drives the rotation of the elongated roll shaft, the monitor monitors the deflection displacement of the middle part of the elongated roll shaft, the driving wheel is pressed on the upper surface of the end part of the elongated roll shaft, the driving wheel and the two supporting rollers are distributed in a Chinese character 'pin', and the driving wheel and the supporting rollers limit the movement of the elongated roll shaft in the axial direction;

s3, sorting

After the detection of the elongated roll shaft in the detection center is finished, when the detection result is unqualified, the first conveying surface and the second conveying surface keep the original state, and the elongated roll shaft directly rolls into a unqualified product collecting tank from the second conveying surface; when the detected product is qualified, the adjusting mechanism drives the first conveying surface to lift, the upper part of the first conveying surface is in butt joint with the output end part of the detection center, the upper end part of the second conveying surface is positioned below the first conveying surface, and the long and thin roll shaft rolls off from the first conveying surface to a qualified product collecting tank.

According to a specific implementation and preferred aspect of the present invention, in S1, the feeding device is adapted to supply the elongated roll shafts to the feeding platform one by one, and to adjust and set the inclined conveying surface angle for feeding according to roll shaft sliding speeds of different diameters. Therefore, the angle of the formed inclined conveying surface can be adjusted and set for feeding according to the sliding speeds of the roller shafts with different diameters.

Preferably, the feeding platform is provided with a trough extending along the length direction of the elongated roll shaft, the feeding device comprises a frame plate positioned at one side of the feeding platform, a transmission plate used for butting the frame plate with the feeding platform and forming an inclined conveying surface, a roll shaft carrier positioned at the side surface of the frame plate away from the feeding platform, and a feeding assembly which ejects the roll shafts from the roll shaft carrier one by one and enables the ejected roll shafts to roll to the transmission plate automatically, wherein the roll shafts are stacked in the roll shaft carrier along the direction parallel to the trough.

In some embodiments, the feeding component comprises a tongue plate attached to the side surface of the frame plate and capable of ejecting the roll shaft from the interior of the roll shaft carrier, and a driving piece for driving the tongue plate to move up and down, wherein the thickness of the tongue plate is 1-1.5 times of the diameter of the roll shaft.

According to a specific and preferred aspect of the invention, the top surface of the tongue is arranged obliquely, and the oblique surface and the side surface of the frame plate form a material taking area, wherein only one roll shaft ejected from the roll shaft stacking area by the tongue falls into the material taking area, the rest roll shafts slide to the roll shaft stacking area, and when the top surface of the tongue is level with the top surface of the frame plate, the roll shafts roll towards the oblique conveying surface along the level top surface and roll into the trough. The roller shaft is convenient to stably realize that a single material is taken in the roller shaft pile.

According to a further specific implementation and preferred aspect of the present invention, the roller carrier comprises two end plates vertically arranged on the frame plate and a bottom plate for connecting the two end plates from the bottom, wherein the two end plates, the bottom plate and the frame plate form a roller stacking area with an open top, a channel is formed between the bottom plate and the frame plate, and the tongue plate is arranged on the roller stacking area in a vertically movable manner from the channel.

Preferably, a fixed rod parallel to the trough is arranged between the two end plates, the roll shaft carrier further comprises a leaning grid plate arranged on the fixed rod in a sliding mode, wherein a leaning channel for avoiding the ejection movement of the tongue plate is formed between the leaning grid plate and the grid plate, and the bottom of the leaning grid plate is attached to the bottom plate. In the embodiment, the width of the corresponding stacking area can be adjusted according to the length of the roller shaft by means of moving and adjusting the grid plates so as to meet stacking of long shafts of different batches aligned from two ends.

Preferably, the end plate is in the shape of a right triangle or a right trapezoid and is fixed on the frame plate from one right-angle side, and the bevel edge is arranged downwards. In other words, the bottom plate is obliquely arranged, so that the roller stacking is convenient to concentrate, and continuous material taking of the roller is facilitated.

Preferably, the tongue plate is attached to the inner side surfaces of the two end plates from opposite side surfaces of the top surface, and attached to the wall surfaces of the channel and the avoidance channel from the front surface and the back surface. In this way, the operation of the tongue plate is more stable.

Preferably, the driving member comprises a cylinder positioned below the roller carrier and fixedly arranged on the frame plate, wherein the telescopic direction of the cylinder is consistent with the moving direction of the tongue plate.

In addition, still be equipped with on the material loading platform along silo length direction extension and set up the baffle that the frame plate side was kept away from to the material loading platform. The baffle is arranged to prevent the roller shaft from being flushed out of the trough due to too high rolling speed.

Preferably, the upper end surface of the inclined conveying surface is flush with the top surface of the frame plate, and the lower end surface is in butt joint with one side edge of the trough opening; the included angle formed by the inclined conveying surface and the horizontal plane is inversely proportional to the distance between the feeding platform and the frame plate, and the shorter the distance is, the larger the included angle is; the longer the distance, the smaller the angle. That is, in this example, the distance between the material platform and the frame plate can be adjusted according to the sliding speeds of the roll shafts with different diameters, so that the angle setting of the inclined conveying surface is realized, and the feeding of the roll shafts is facilitated.

According to still another specific implementation and preferred aspect of the present invention, the detection device adopted in S2 includes a detection platform, a bearing seat disposed on the detection platform and supporting the elongated roller shaft in a rolling manner from two ends, a driving member driving the elongated roller shaft mounted on the bearing seat to rotate around its own axis, and a monitor disposed on the detection platform and capable of monitoring a deflection displacement amount of a middle portion of the elongated roller shaft, wherein the bearing seat includes a seat body, two supporting rollers disposed side by side on the seat body, the elongated roller shaft is mounted on the two supporting rollers from the ends, the driving member is located at one end of the elongated roller shaft after positioning, and includes a driving wheel located on the two supporting rollers, and a driver driving the driving wheel to rotate.

Preferably, the two bearing seats move up and down synchronously along the vertical direction, when the detection is performed, the two bearing seats drive the elongated roller to move towards the monitor until the driving wheel contacts with the upper surface of the end part of the elongated roller, the driving wheel rotates to drive the elongated roller to rotate, and the driving wheel and the supporting roller limit the movement of the elongated roller in the axial direction, so that the detection place of the monitor is the middle part of the elongated roller.

Preferably, the transfer device used in S2 is configured to transfer the elongated roller in the loading platform to the bearing seat, and the transfer device includes a positioning fence disposed on the detection platform, a transfer module capable of being aligned with the loading platform, a first pushing member for pushing the elongated roller shaft toward the transfer module and abutting against the positioning fence from an end, and a second pushing member for pushing the transfer module horizontally toward the bearing seat, where when the transfer module moves above the bearing seat, the bearing seats at two ends are pushed out from the transfer module from two ends of the elongated roller shaft.

In addition, the sorting device used in S3 automatically sorts the pass and fail products according to the result monitored by the monitor.

In some embodiments, the sorting device comprises a sorting base, a qualified product collecting tank and a disqualified product collecting tank which are positioned on two opposite sides of the sorting base, a first guide component and a second guide component which are arranged on the sorting base and can guide an elongated roller shaft to the qualified product collecting tank and the disqualified product collecting tank respectively, and an adjusting mechanism, wherein the first guide component and the second guide component are respectively provided with a first conveying surface and a second conveying surface which are obliquely arranged from top to bottom and are intersected at the upper part, the adjusting mechanism is used for adjusting one of the first conveying surface and the second conveying surface to be in butt joint with a detection center output end part, and when a detection result is a qualified product, the first conveying surface is in butt joint with the detection center output end part, and the elongated roller shaft rolls down to the qualified product collecting tank along the first conveying surface; when the detection result is an unqualified product, the second conveying surface is in butt joint with the output end part of the detection center, and the long and thin roll shaft rolls down to the unqualified product collecting groove along the second conveying surface.

Preferably, the first guiding component comprises a first connecting seat arranged on the sorting base, a first inserting rod extending along the length direction of the qualified product collecting groove and crossing the first connecting seat, and at least two first guiding rods aligned on the first inserting rod and obliquely arranged, wherein the inclined upper surfaces of the two or more first guiding rods form a first conveying surface, and the distance between every two adjacent first guiding rods is smaller than the length of the slender roll shaft.

Specifically, the lower end of the first guide rod is arranged on the side edge of the qualified product collecting tank in a building mode, and the upper end of the first guide rod is located below the output end of the detection center.

According to a specific embodiment and preferred aspect of the invention, the first guide rod is arranged on the first insert rod in a sliding adjustable manner, and the first insert rod is arranged on the first connecting seat in a rotationally adjustable or fixed manner around its own axis. The first guide rod is used for adjusting the width of the effective conveying surface to correspond to products with different lengths; as for the rotational adjustment of the first plunger, the angle of the conveying surface is mainly adjusted so that the elongated roller shaft rolls to a desired position in the collecting tank.

According to a further specific implementation and preferred aspect of the present invention, the second guiding component comprises a second connecting seat arranged on the sorting base, a second inserting rod extending along the length direction of the defective product collecting tank and crossing the second connecting seat, and second guiding rods aligned on the second inserting rods and obliquely arranged, wherein at least two second guiding rods are arranged, the inclined upper surfaces of two or more second guiding rods form a second conveying surface, and the distance between two adjacent second guiding rods is smaller than the length of the slender roll shaft.

Preferably, the lower part of the second guide bar is arranged on the side edge of the defective product collecting tank, and the upper end part is arranged below the output end part of the detection center.

Preferably, the first guide rods and the second guide rods are two, and the second guide rods are located on the opposite outer sides of the two first guide rods and are arranged in an intersecting manner at the upper part.

Specifically, the second connecting seat is fixed on the sorting base, the first connecting seat can move up and down along the vertical direction, the adjusting mechanism is arranged between the first connecting seat and the sorting base, the output end of the detection center is positioned above the second conveying surface, when the detected product is unqualified, the adjusting mechanism does not need to move, and the slender roll shaft directly rolls into the unqualified product collecting tank from the second conveying surface; when the detected product is qualified, the adjusting mechanism drives the first conveying surface to lift, the upper part of the first conveying surface is in butt joint with the output end part of the detection center, and the long and thin roll shaft rolls off from the first conveying surface to the qualified product collecting tank. Therefore, the first conveying surface and the second conveying surface can be changed in a static-moving mode, and qualified products and unqualified products can be further sorted.

The second guide rod can be arranged on the second inserted rod in a sliding adjustment mode, and the second inserted rod is arranged on the second connecting seat in a rotating adjustment mode or a fixed mode around the axis of the second inserted rod.

The sorting base comprises a bottom plate, a T-shaped frame located on the bottom plate and positioning modules arranged at two opposite ends of the top of the T-shaped frame, wherein the first guide part and the second guide part are respectively erected on the positioning modules, and the T-shaped frame can be arranged on the bottom plate in an up-down adjusting manner along the vertical direction.

Preferably, the bearing seat can move up and down along the vertical direction, the bearing seat descends after the detection of the monitor is finished, and when the bearing seat is a qualified product, the upper part of the first conveying surface takes out the slender roll shaft from the bearing seat and guides the slender roll shaft to the qualified product collecting tank; and when the product is an unqualified product, the second conveying surface is taken out from the bearing seat and guided to the unqualified product collecting tank.

Preferably, the transfer device comprises a positioning leaning grid arranged on the detection platform, a transfer module capable of being aligned with the feeding platform, a first pushing piece for pushing the elongated roll shaft to the transfer module and abutting against the positioning leaning grid from the end part, and a second pushing piece for pushing the transfer module to the bearing seat horizontally, wherein when the transfer module moves to the position above the bearing seat, the bearing seats at the two end parts are ejected from the transfer module from the two end parts of the elongated roll shaft.

Due to the implementation of the technical scheme, compared with the prior art, the invention has the following advantages:

In the existing slender roll shaft straightness detection process, the whole detection step is longer, the detection process is completed by manpower, only single-machine operation is possible, and meanwhile, the efficiency is low and the requirement of mass production cannot be met; when the manual rotation is performed, the manual intervention cannot ensure complete equality in terms of speed and force, and the operation detection precision of different people is different; the arm is always in a lifting state during manual operation, the waist and shoulder postures are tired during long-time operation, the labor intensity is high, meanwhile, the formed detection conditions cannot be constant and uniform, axial displacement generated in the detection process cannot be avoided, accurate position deflection displacement cannot be obtained, and the like. After the automatic detection process is adopted, firstly, feeding is carried out one by one, after the feeding of the previous roll shaft is finished, the tongue plate retreats to the stacking area, and then the movement process is repeated, so that the continuous feeding of the roll shaft can be realized; secondly, transferring and detecting an elongated roll shaft, namely transferring the elongated roll shaft in a feeding platform to an axial bearing seat, pressing the elongated roll shaft on the upper surface of the end part of the elongated roll shaft by a driving wheel, wherein a driving wheel and two supporting rollers are distributed in a delta shape; finally, sorting adopts a static-dynamic mode, namely the positions of the first conveying surface and the second conveying surface are changed, and qualified and unqualified products are sorted, so that compared with the prior art, the invention has the advantages that on one hand, the operation is convenient, the accuracy of detection results is high, and meanwhile, the cost is low through feeding, detecting and sorting which are automatically and sequentially carried out; on the other hand, the two ends of the slender roll shaft are supported in a free rolling way, the axial movement is limited under the pressing drive of a driving wheel at one end, the vertical movement and the horizontal movement are also limited under the rotation in a constant space, and the accurate deflection displacement is obtained under a constant and uniform detection standard; according to the third aspect, according to roll shaft sliding speeds with different diameters, the angle of the formed inclined conveying surface can be adjusted and set for feeding, meanwhile, the long and thin roll shafts are ejected out and transferred under the relative movement of the bearing seat and the transfer module for convenient transfer, and a static-moving mode is adopted to rapidly sort qualified and unqualified products.

Drawings

FIG. 1 is a schematic diagram of an automated inspection apparatus of the present invention;

FIG. 2 is a schematic top view of FIG. 1;

FIG. 3 is a schematic view of the feeding device of FIG. 1;

FIG. 4 is a schematic front view of FIG. 3 (partially omitted);

FIG. 5 is a schematic top view of FIG. 3;

FIG. 6 is a schematic view of the sorting apparatus of FIG. 1;

FIG. 7 is a schematic front view of FIG. 6;

FIG. 8 is a schematic top view of FIG. 6;

wherein: A. a feeding device; 1. a feeding platform; 10. a trough; 2. a frame plate; 3. a transmission plate; 30. tilting the conveying surface; 4. a roller carrier; 40. an end plate; 41. a bottom plate; 42. a fixed rod; 43. a grid plate; 5. a feeding assembly; 50. a tongue plate; 51. a driving member; 510. a cylinder; 6. a baffle;

B. a detection device; b1, a detection platform; b2, a bearing seat; b20, a seat body; b21, supporting rollers; b3, a driving piece; b30, driving wheels; b31, a driver; b4, a monitor;

C. a transfer device; c1, positioning a leaning grid; c2, a switching module; c3, a first pushing piece; c4, a second pushing piece;

D. a sorting device; d1, sorting bases; d10, a bottom plate; d11, a T-shaped frame; d12, a positioning module; d2, a qualified product collecting tank; d3, collecting a defective product; d4, a first guiding component; a. a first conveying surface; d40, a first connecting seat; d41, a first inserted link; d42, a first guide rod; d5, a second guiding component; b. a second conveying surface; d50, a second connecting seat; d51, a second inserted link; d52, a second guide rod; d6, an adjusting mechanism;

G. An elongated roller.

Detailed Description

The present invention will be described in detail with reference to the drawings and the detailed description, so that the above objects, features and advantages of the present invention can be more clearly understood. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. The present invention may be embodied in many other forms than described herein and similarly modified by those skilled in the art without departing from the spirit of the invention, whereby the invention is not limited to the specific embodiments disclosed below.

In the description of the present invention, it should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "radial", "circumferential", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element being 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 invention.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are 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. In the description of the present utility model, the meaning of "plurality" means at least two, for example, two, three, etc., unless specifically defined otherwise.

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 mechanically or electrically connected; either directly or indirectly, through intermediaries, or both, may be in communication with each other or in interaction with each other, unless expressly defined otherwise. 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.

In the 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 through an intervening medium. Moreover, a first feature being "above," "over" and "on" a second feature may be a first feature being directly above or obliquely above the second feature, or simply indicating that the first feature is level higher than the second feature. The first feature being "under", "below" and "beneath" the second feature may be the first feature being directly under or obliquely below the second feature, or simply indicating that the first feature is less level than the second feature.

It will be understood that when an element is referred to as being "fixed" or "disposed" on another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "upper," "lower," "left," "right," and the like are used herein for illustrative purposes only and are not meant to be the only embodiment.

As shown in fig. 1 and 2, the automatic detecting apparatus for the straightness of the elongated roller shaft of the rubber roller according to the present embodiment includes a feeding device a, a detecting device B, a transferring device C, and a sorting device D.

As shown in fig. 3, the feeding device a includes a loading platform 1 having a trough 10 extending along the length direction of a roll shaft G, a frame plate 2 located at one side of the loading platform 1, a transfer plate 3 for docking the frame plate 2 with the loading platform 1 and forming an inclined transfer surface 30, a roll shaft carrier 4 located on the side of the frame plate 2 away from the loading platform 1, and a feeding assembly 5 for ejecting the roll shaft G from the roll shaft carrier 4 one by one and causing the ejected roll shaft G to roll automatically to the transfer plate 3, wherein the roll shaft G is stacked in the roll shaft carrier 4 in a direction parallel to the trough 10, and the roll shaft G located on the transfer plate 3 freely rolls under its own weight in the trough 10 of the loading platform 1 along the inclined transfer surface 30.

Specifically, the feeding assembly 5 includes a tongue plate 50 attached to a side surface of the frame plate 2 and capable of ejecting the roller shaft G from the inside of the roller shaft carrier 4, and a driving member 51 for driving the tongue plate 50 to move up and down, wherein the thickness of the tongue plate 50 is 1.25 times the diameter of the roller shaft G.

The top surface of the tongue plate 50 is obliquely arranged, and the inclined surface and the side surface of the frame plate 2 form a material taking area, wherein only one roll shaft G ejected from the roll shaft stacking area by the tongue plate 50 falls into the material taking area, the rest roll shaft G slides to the roll shaft stacking area, and when the top surface of the tongue plate 50 is level with the top surface of the frame plate 2, the roll shaft G rolls to the inclined conveying surface 30 along the level top surface and rolls into the trough 10. The roller shaft is convenient to stably realize that a single material is taken in the roller shaft pile.

In this example, the inclination angle of the flush top surface is small, typically about 5-10 °.

As shown in fig. 4 and 5, the roller carrier 4 includes two end plates 40 vertically disposed on the frame plate 2 and a bottom plate 41 for connecting the two end plates 40 from the bottom, wherein the two end plates 40, the bottom plate 41 and the frame plate 2 form a roller stacking area with an open top, a channel is formed between the bottom plate 41 and the frame plate 2, and the tongue plate 50 is movably disposed in the roller stacking area from top to bottom.

A fixing rod 42 parallel to the trough 10 is arranged between the two end plates 40, the roll shaft carrier 4 further comprises a leaning grid plate 43 arranged on the fixing rod 42 in a sliding mode, wherein a leaning channel for leaning on the grid plate 43 to push out the tongue plate 50 is formed between the leaning grid plate 43 and the frame plate 2, and the bottom of the leaning grid plate 43 is attached to the bottom plate 41.

In this example, by moving and adjusting the grid plates 43, the width of the corresponding stacking area can be adjusted according to the length of the roller shaft G, so as to meet stacking with aligned long axes of different batches from two ends.

The end plate 40 is in the shape of a right trapezoid and is fixed on the frame plate 2 from one right-angle side, and the inclined side is arranged downwards. In other words, it is disclosed that the bottom plate 41 is inclined, so that the stacking concentration of the roll shafts is facilitated, and the continuous taking of the roll shafts is facilitated.

The leaning grid plate 43 is also in a right trapezoid shape, and the top surface is flush with the top surface of the frame plate 2.

The tongue plate 50 is attached to the inner side surfaces of the two end plates 40 from opposite side surfaces of the top surface, and attached to the wall surfaces of the passage and the escape passage from the front and back surfaces. In this way, the operation of the tongue plate 50 is more stable.

The driving member 51 includes a cylinder 510 located below the roller carrier 4 and fixedly provided on the frame plate 2, wherein the expansion and contraction direction of the cylinder 510 coincides with the movement direction of the tongue plate 50.

The feeding platform 1 is also provided with a baffle 6 which extends along the length direction of the trough 10 and is arranged on the side surface of the feeding platform 1 far away from the frame plate 2. The baffle 6 prevents the roll shaft from falling too fast to be flushed out of the trough.

In addition, the upper end surface of the inclined conveying surface 30 is flush with the top surface of the frame plate 2, and the lower end surface is in butt joint with one side edge of the opening of the trough 10; the included angle formed by the inclined conveying surface 30 and the horizontal plane is inversely proportional to the distance between the feeding platform 1 and the frame plate 2, and the shorter the distance is, the larger the included angle is; the longer the distance, the smaller the angle. That is, in this example, the distance between the material platform and the frame plate can be adjusted according to the sliding speeds of the roll shafts with different diameters, so that the angle setting of the inclined conveying surface is realized, and the feeding of the roll shafts is facilitated.

A layer of cardboard or cloth may then be laid down in the inclined conveying surface 30 and in the trough 10, taking into account the damage to the surface of the roll shaft during rolling. The arrangement of the paper board or the cloth can also effectively realize the cleaning of the surface of the roll shaft.

The detection device B comprises a detection platform B1, a bearing seat B2 arranged on the detection platform B1 and used for rolling and supporting the slender roll shaft G from two end parts, a driving piece B3 used for driving the slender roll shaft G erected on the bearing seat B2 to rotate around the axis of the driving piece B3, and a monitor B4 arranged on the detection platform B1 and used for monitoring the deflection displacement of the middle part of the slender roll shaft, wherein the bearing seat B2 comprises two seat bodies B20 and two supporting rollers B21 arranged on the seat bodies B20 side by side, the slender roll shaft G is erected on the two supporting rollers B21 from end parts, the driving piece B3 is positioned at one end part of the slender roll shaft G after positioning and comprises a driving wheel B30 positioned on the two supporting rollers B21 and a driver B31 used for driving the driving wheel B30 to rotate, and when detection is carried out, the driving wheel B30 is pressed on the upper surface of the end part of the slender roll shaft G.

Simultaneously, two bearing seats b2 can also vertically and synchronously lift. When the detection is carried out, the two bearing seats b2 drive the slender roll shafts G to move towards the monitor b4 until the driving wheel b30 is in contact with the upper surface of the end part of the slender roll shafts G, the rotation of the slender roll shafts G is driven by the rotation of the driving wheel b30, and the driving wheel b30 and the supporting roller b21 limit the movement of the slender roll shafts G in the axial direction, so that the monitor b4 is the middle part of the slender roll shafts G in the consistent detection place, and the accuracy of the detection result is ensured.

The transfer device C comprises a positioning leaning grid C1 arranged on the detection platform b1, a transfer module C2 capable of being aligned with the feeding platform 1, a first pushing piece C3 used for pushing the long and thin roll shaft to the transfer module C2 and abutting against the positioning leaning grid C1 from the end part, and a second pushing piece C4 used for pushing the transfer module C2 to the bearing seat b2 horizontally, wherein when the transfer module C2 moves to the position above the bearing seat b, the bearing seats b2 at the two end parts are ejected from the transfer module C2 from the two end parts of the long and thin roll shaft.

Specifically, when the first pushing member c3 pushes the elongated roll shaft G in the trough 10 of the feeding platform 1 to the adapting module c2, the end portion of the elongated roll shaft G abuts against the positioning leaning gate c1, then the second pushing member c4 moves the elongated roll shaft G downward toward the monitor b4, at this time, the two bearing seats b2 are lifted upward, and the elongated roll shaft G is ejected out of the adapting module c2 from the two end portions of the elongated roll shaft G and moves toward the monitor b4 until the driving wheel b30 contacts with the upper surface of the end portion of the elongated roll shaft G, and then the rotation of the driving wheel b30 drives the rotation of the elongated roll shaft G.

In this example, the first pushing member c3 and the second pushing member c4 are both cylinders.

As shown in fig. 6 to 8, the sorting device D includes a sorting base D1, a good product collecting tank D2 and a bad product collecting tank D3 located on opposite sides of the sorting base D1, first and second guide members D4 and D5 provided on the sorting base D1 and capable of guiding the elongated roller shaft G to the good product collecting tank D2 and the bad product collecting tank D3, respectively, and an adjusting mechanism D6, wherein the first and second guide members D4 and D5 are respectively formed with first and second conveying surfaces a and b provided obliquely from top to bottom and intersecting at the upper portion, and the adjusting mechanism D6 is used for adjusting one of the first and second conveying surfaces a and b to be abutted with a detection center output end portion, and when the detection result is a good product, the first conveying surface a is abutted with the detection center output end portion, and the elongated roller shaft G rolls down to the good product collecting tank D2 along the first conveying surface a; when the detection result is the defective product, the second conveying surface b is in butt joint with the output end part of the detection center, and the long and thin roll shaft G rolls down to a defective product collecting groove d3 along the second conveying surface b.

The sorting base d1 comprises a bottom plate d10, a T-shaped frame d11 positioned on the bottom plate d10, and positioning modules d12 arranged at two opposite ends of the top of the T-shaped frame d11, wherein a first guide part d4 and a second guide part d5 are respectively erected on the positioning modules d12, and the T-shaped frame d11 can be arranged on the bottom plate d10 in a vertically adjustable manner.

In this example, the positioning modules d12 are symmetrically disposed at two opposite ends of the top of the T-shaped frame d 11.

As shown in fig. 2 and 3, the first guide member d4 includes a first connection seat d40 provided on the positioning module d12, a first insertion rod d41 extending along the length direction of the acceptable product collection tank d2 and crossing the first connection seat d40, and first guide rods d42 aligned on the first insertion rod d41 and inclined, wherein at least two of the first guide rods d42 form a first conveying surface a on inclined upper surfaces of two or more first guide rods d42, and a distance between adjacent two of the first guide rods d42 is smaller than the length of the elongated roller shaft G.

Specifically, the lower end of the first guide bar d42 is set up on the side edge of the acceptable product collecting tank d2, and the upper end is located below the inspection center output end.

The lower portion of the first guide bar d42 extends into the inside of the side edge of the acceptable product collecting tank d 2.

In this example, the first guide rod d42 is slidably and adjustably provided on the first insertion rod d41, and the first insertion rod d41 is rotatably and adjustably provided on the first connection seat d40 about its own axis. The first guide rod d42 is mainly used for adjusting the width of the effective conveying surface so as to correspond to products with different lengths; as for the rotational adjustment of the first plunger d41, mainly, the angle of the conveying surface is adjusted so that the elongated roller shaft G rolls to a desired position in the collecting tank.

The second guide part d5 comprises a second connecting seat d50 arranged on the positioning module d12, a second inserting rod d51 extending along the length direction of the defective product collecting groove d3 and crossing the second connecting seat d50, and second guide rods d52 aligned on the second inserting rod d51 and obliquely arranged, wherein at least two second guide rods d52 are arranged, the inclined upper surfaces of two or more second guide rods d52 form a second conveying surface b, and the distance between two adjacent second guide rods d52 is smaller than the length of the slender roll shaft G.

The lower part of the second guide rod d52 is arranged on the side edge of the defective product collecting tank d3, and the upper end part is positioned below the output end part of the detection center.

The first guide rods d42 and the second guide rods d52 are two, and the second guide rods d52 are positioned on the opposite outer sides of the two first guide rods d42 and are arranged in an intersecting manner at the upper part.

Specifically, the second connecting seat d50 is fixed on the sorting base d1, the first connecting seat d40 can move up and down along the vertical direction, the adjusting mechanism d6 is arranged between the first connecting seat d40 and the sorting base d1, the output end of the detection center is positioned above the second conveying surface b, when the detected product is unqualified, the adjusting mechanism d6 does not need to move, and the slender roll shaft G directly rolls into the unqualified product collecting tank d3 from the second conveying surface b; when the detected product is qualified, the adjusting mechanism d6 drives the first conveying surface a to be lifted, the upper part of the first conveying surface a is in butt joint with the output end part of the detection center, and the long and thin roll shaft G rolls off from the first conveying surface a to the qualified product collecting groove d2. Therefore, the positions of the first conveying surface a and the second conveying surface b can be changed by adopting a static-dynamic mode, and then qualified products and unqualified products can be sorted.

The second guide rod d52 is slidably disposed on the second insert rod d51, and the second insert rod d51 is fixedly disposed on the second connecting seat d 50.

As for the adjusting mechanism d6, the most commonly used cylinder is adopted in this example, and the first conveying surface a is lifted and lowered by the expansion and contraction of the cylinder.

The sorting process in this example is as follows:

after the detection of the detection center is finished, when the detection result is unqualified, the first conveying surface a and the second conveying surface b keep the original state, and the elongated roll shaft G directly rolls into a unqualified product collecting groove d3 from the second conveying surface b; when the detected product is qualified, the adjusting mechanism d6 drives the first conveying surface a to lift, the upper part of the first conveying surface a is in butt joint with the output end part of the detection center, the upper end part of the second conveying surface b is positioned below the first conveying surface a, the long and thin roll shaft G rolls off from the first conveying surface a to the qualified product collecting tank d2, and the positions of the first conveying surface a and the second conveying surface b can be changed in a static-moving mode, so that qualified and unqualified products are sorted.

In summary, the working procedure of this embodiment is as follows:

1) Root by root feed

When the feeding is carried out, the air cylinder pushes the tongue plate to eject out of the stacking roller shafts, more than one roller shaft is likely to be located in a material taking area formed by the top surface of the tongue plate and the frame plate, then along with the rising of the material taking area, at the moment, only one roller shaft can be erected in the material taking area, redundant roller shafts roll down to the stacking area until the top surface of the tongue plate and the top surface of the frame plate are flush, and the roller shafts roll to the inclined conveying surface of the conveying plate and roll down to the trough, so that single feeding of the roller shafts is completed.

After the feeding of the previous roll shaft is completed, the tongue plate returns to the stacking area, and then the moving process is repeated, so that the continuous feeding of the roll shaft can be realized.

2) Transfer and inspection of elongated rolls

After the first pushing piece pushes the slender roll shaft in the trough of the feeding platform to the transfer module, the end part of the slender roll shaft is abutted against the positioning leaning grid, then the second pushing piece moves the slender roll shaft to the lower part of the monitor, at the moment, the two bearing seats are lifted upwards, the slender roll shaft is ejected out of the transfer module from the two end parts of the slender roll shaft to move towards the monitor, until the driving wheel is contacted with the upper surface of the end part of the slender roll shaft, the rotation of the slender roll shaft is driven by the rotation of the driving wheel, and the deflection displacement of the middle part of the slender roll shaft is monitored by the monitor.

3) Sorting (sorting qualified and unqualified products)

After the detection of the elongated roll shaft in the detection center is finished, when the detection result is unqualified, the first conveying surface and the second conveying surface keep the original state, and the elongated roll shaft directly rolls into a unqualified product collecting tank from the second conveying surface; when the detected product is qualified, the adjusting mechanism drives the first conveying surface to lift, the upper part of the first conveying surface is in butt joint with the output end part of the detection center, the upper end part of the second conveying surface is positioned below the first conveying surface, and the long and thin roll shaft rolls off from the first conveying surface to the qualified product collecting tank, so that the positions of the first conveying surface and the second conveying surface can be changed in a static-one-moving mode, and qualified and unqualified products are further sorted.

In a comprehensive way, after the automatic detection process is adopted, firstly, feeding is carried out one by one, after the feeding of the previous roll shaft is completed, the tongue plate retreats to the stacking area, and then the movement process is repeated, so that the continuous feeding of the roll shaft can be realized; secondly, transferring and detecting an elongated roll shaft, namely transferring the elongated roll shaft in a feeding platform to an axial bearing seat, pressing the elongated roll shaft on the upper surface of the end part of the elongated roll shaft by a driving wheel, wherein a driving wheel and two supporting rollers are distributed in a delta shape; finally, sorting adopts a static-dynamic mode, namely the positions of the first conveying surface and the second conveying surface are changed, and qualified and unqualified products are sorted, so that compared with the prior art, the invention has the advantages that on one hand, the operation is convenient, the accuracy of detection results is high, and meanwhile, the cost is low through feeding, detecting and sorting which are automatically and sequentially carried out; on the other hand, the two ends of the slender roll shaft are supported in a free rolling way, the axial movement is limited under the pressing drive of a driving wheel at one end, the vertical movement and the horizontal movement are also limited under the rotation in a constant space, and the accurate deflection displacement is obtained under a constant and uniform detection standard; according to the third aspect, according to roll shaft sliding speeds with different diameters, the angle of the formed inclined conveying surface can be adjusted and set for feeding, meanwhile, the long and thin roll shafts are ejected out and transferred under the relative movement of the bearing seat and the transfer module for convenient transfer, and a static-moving mode is adopted to rapidly sort qualified and unqualified products. The present invention has been described in detail with the purpose of enabling those skilled in the art to understand the contents of the present invention and to implement the same, but not to limit the scope of the present invention, and all equivalent changes or modifications made according to the spirit of the present invention should be included in the scope of the present invention.

Claims (10)

1. An automatic detection process for straightness of an elongated roller shaft of a rubber roller is characterized by comprising the following steps:

s1, feeding root by root

Pushing the tongue plate to eject from the stacking roller shaft by the air cylinder, wherein more than one roller shaft possibly exists in a material taking area formed by the top surface of the tongue plate and the frame plate, and then along with the rising of the material taking area, only one roller shaft can be erected in the material taking area, and the redundant roller shafts roll down to the stacking area until the top surface of the tongue plate is flush with the top surface of the frame plate, and then roll to the inclined conveying surface of the conveying plate and roll down to a trough to finish the single feeding of the roller shafts; after the feeding of the previous roll shaft is completed, the tongue plate returns to the stacking area, and the moving process is repeated, so that the continuous feeding of the roll shaft can be realized;

s2, transferring and detecting the slender roll shaft

After the first pushing piece pushes an elongated roll shaft in a trough of the feeding platform to the transfer module, the end part of the elongated roll shaft is abutted against the positioning leaning grid, then the second pushing piece moves the elongated roll shaft to the lower part of the monitor, at the moment, the two bearing seats are lifted upwards, the elongated roll shaft is ejected out of the transfer module from the two end parts of the elongated roll shaft to move towards the monitor, until the driving wheel is contacted with the upper surface of the end part of the elongated roll shaft, the rotation of the driving wheel drives the rotation of the elongated roll shaft, the monitor monitors the deflection displacement of the middle part of the elongated roll shaft, the driving wheel is pressed on the upper surface of the end part of the elongated roll shaft, the driving wheel and the two supporting rollers are distributed in a Chinese character 'pin', and the driving wheel and the supporting rollers limit the movement of the elongated roll shaft in the axial direction;

S3, sorting

After the detection of the elongated roll shaft in the detection center is finished, when the detection result is unqualified, the first conveying surface and the second conveying surface keep the original state, and the elongated roll shaft directly rolls into a unqualified product collecting tank from the second conveying surface; when the detected product is qualified, the adjusting mechanism drives the first conveying surface to lift, the upper part of the first conveying surface is in butt joint with the output end part of the detection center, the upper end part of the second conveying surface is positioned below the first conveying surface, and the long and thin roll shaft rolls off from the first conveying surface to a qualified product collecting tank.

2. The automated inspection process for straightness of an elongated roll shaft of a rubber roll according to claim 1, wherein in S1, the feeding device is capable of feeding the elongated roll shaft to the feeding platform one by one, and adjusting and setting the angle of the inclined conveying surface according to roll shaft sliding speeds of different diameters.

3. The automated process for detecting the straightness of an elongated roll shaft of a rubber roll according to claim 2, wherein a trough extending along the length direction of the elongated roll shaft is arranged on the feeding platform, the feeding device comprises a frame plate arranged on one side of the feeding platform, a transmission plate used for butting the frame plate with the feeding platform and forming an inclined conveying surface, a roll shaft carrier arranged on the side of the frame plate away from the feeding platform, and a feeding assembly used for ejecting the roll shafts one by one from the roll shaft carrier and enabling the ejected roll shafts to roll to the transmission plate automatically, wherein the roll shafts are stacked in the roll shaft carrier along a direction parallel to the trough.

4. The automated inspection process for straightness of an elongated roller shaft of a rubber roller according to claim 3, wherein the feeding assembly comprises a tongue plate attached to a side surface of the frame plate and capable of ejecting the roller shaft from the inside of the roller shaft carrier, and a driving member for driving the tongue plate to move up and down, wherein the thickness of the tongue plate is 1 to 1.5 times the diameter of the roller shaft.

5. The automatic detection process for the straightness of the long and thin roll shaft of the rubber roll according to claim 1, wherein the detection device adopted in the step S2 comprises a detection platform, a bearing seat, a driving piece and a monitor, wherein the bearing seat is arranged on the detection platform and used for supporting the long and thin roll shaft in a rolling mode from two end portions, the driving piece is arranged on the bearing seat in a driving mode and rotates around the axis of the bearing seat, the monitor is arranged on the detection platform and used for monitoring the deflection displacement of the middle portion of the long and thin roll shaft, the supporting seat comprises a seat body, two supporting rollers are arranged on the seat body side by side, the long and thin roll shaft is arranged on the two supporting rollers from the end portions, the driving piece is positioned at one end portion of the long and thin roll shaft after positioning, and comprises a driving wheel and a driver used for driving the driving wheel to rotate.

6. The automated inspection process for straightness of an elongated roller shaft of a rubber roller according to claim 5, wherein the two carrying seats are moved up and down synchronously along the vertical direction, and when the inspection is performed, the two carrying seats drive the elongated roller shaft to move toward the monitor until the driving wheel contacts with the upper surface of the end portion of the elongated roller shaft, the driving wheel is rotated to drive the elongated roller shaft to rotate, and the driving wheel and the supporting roller limit the movement of the elongated roller shaft in the axial direction, so that the inspection place of the monitor is the middle portion of the elongated roller shaft.

7. The automated process for inspecting the straightness of an elongated roll shaft of a rubber roll according to claim 1, wherein a transfer device is used in S2 for transferring the elongated roll shaft of the loading platform to the carrying seat, and the transfer device includes a positioning fence provided on the inspection platform, a transfer module capable of being aligned with the loading platform, a first pushing member for pushing the elongated roll shaft against the transfer module and abutting against the positioning fence from the end, and a second pushing member for pushing the transfer module horizontally against the carrying seat, wherein the carrying seats at both ends are pushed out of the transfer module from both ends of the elongated roll shaft when the transfer module moves above the carrying seat.

8. The automated inspection process for the straightness of an elongated roller shaft of a rubber roller according to claim 1, wherein the sorting device used in S3 sorts the pass and fail products automatically based on the result monitored by the monitor.

9. The automated inspection process of the straightness of the elongated roller shaft of the rubber roller according to claim 8, wherein the sorting device comprises a sorting base, a qualified product collecting tank and a unqualified product collecting tank which are positioned at two opposite sides of the sorting base, a first guiding component and a second guiding component which are arranged on the sorting base and can guide the elongated roller shaft to the qualified product collecting tank and the unqualified product collecting tank respectively, and an adjusting mechanism, wherein the first guiding component and the second guiding component are respectively provided with a first conveying surface and a second conveying surface which are obliquely arranged from top to bottom and are intersected at the upper part, the adjusting mechanism is used for adjusting one of the first conveying surface and the second conveying surface to be butted with an output end of a detection center, and when the detection result is qualified products, the first conveying surface is butted with the output end of the detection center, and the elongated roller shaft rolls down to the qualified product collecting tank along the first conveying surface; when the detection result is an unqualified product, the second conveying surface is in butt joint with the output end part of the detection center, and the long and thin roll shaft rolls down to the unqualified product collecting groove along the second conveying surface.

10. The automated inspection process of the straightness of an elongated roller shaft of a rubber roller according to claim 9, wherein the first guide member comprises a first connecting seat arranged on the sorting base, a first inserting rod extending along the length direction of the qualified product collecting tank and crossing the first connecting seat, and first guide rods aligned on the first inserting rod and obliquely arranged, wherein at least two first guide rods are arranged, the inclined upper surfaces of two or more first guide rods form the first conveying surface, and the distance between two adjacent first guide rods is smaller than the length of the elongated roller shaft; and/or the second guide part comprises a second connecting seat arranged on the sorting base, a second inserting rod extending along the length direction of the disqualified product collecting groove and crossing the second connecting seat, and second guide rods aligned on the second inserting rods and obliquely arranged, wherein at least two second guide rods are arranged, the inclined upper surfaces of two or more second guide rods form the second conveying surface, and the distance between every two adjacent second guide rods is smaller than the length of the slender roll shaft.