CN112024435A - Intelligent device for manufacturing and measuring finished product size - Google Patents

Abstract

The invention discloses an intelligent finished product size manufacturing and measuring device, which comprises a measuring box, wherein a measuring cavity with an upward opening is arranged in the measuring box, the upper wall of the measuring cavity is fixedly connected with a measuring motor, the front end of the measuring motor is in power connection with a main driving shaft, the outer peripheral surface of the main driving shaft is fixedly connected with a driving belt pulley, the rear wall of the measuring cavity is rotationally connected with two measuring rotating shafts, and the two measuring rotating shafts are symmetrically distributed in a left-right mode by taking the central line of the measuring motor as a symmetric center, so that after a series of finished products are finished in a workshop, the finished products can be fed into the measuring cavity, the peripheral dimension of the finished products can be accurately measured, and if the size is found to be improper in the measuring process, the scrapped finished product is transported to the outside of the measuring cavity through the transporting device, and the periphery size of the next batch of finished products is continuously detected, so that the increase of labor cost caused by manual measurement of the sizes of the finished products is avoided, and the overall manufacturing efficiency of a workshop is reduced.

Description

Intelligent device for manufacturing and measuring finished product size

Technical Field

The invention relates to the field of intelligent manufacturing, in particular to a device for intelligently manufacturing and measuring the size of a finished product.

Background

In the traditional workshop manufacturing process, after products and finished products are produced, the products and the finished products need to be detected and inspected manually, so that a factory engages in inspectors, the capital cost in the factory is increased, the efficiency of manually detecting the products is low, the production efficiency of the workshop is reduced integrally, and the product supply cannot be kept up with the standard.

Disclosure of Invention

In order to solve the above problems, the present embodiment provides an intelligent device for measuring dimensions of finished products, which comprises a measuring box, a measuring cavity with an upward opening is arranged in the measuring box, a measuring motor is fixedly connected to the upper wall of the measuring cavity, a main driving shaft is connected to the front end of the measuring motor, a driving pulley is fixedly connected to the outer peripheral surface of the main driving shaft, two measuring rotating shafts are rotatably connected to the rear wall of the measuring cavity, the two measuring rotating shafts are distributed and arranged in a bilateral symmetry manner with the central line of the measuring motor as the center of symmetry, a measuring pulley is fixedly connected to the outer peripheral surface of the measuring rotating shaft, a measuring belt is rotatably connected between the measuring pulley and the driving pulley, an extension main rod is fixedly connected to the front end of the measuring rotating shaft, an extension cavity with a downward opening is arranged in the extension, the upper wall of the extension cavity is fixedly connected with an extension inductor, the lower end of the extension inductor is fixedly connected with an extension spring, the lower end of the extension spring is fixedly connected with a moving auxiliary rod, the moving auxiliary rod is connected to the inner wall of the extension cavity in a sliding manner, the rear wall of the measurement cavity is rotationally connected with two judgment shafts, the two judgment shafts are symmetrically distributed on the left and right sides by taking the central line of the main driving shaft as a symmetry center, the outer peripheral surface of each judgment shaft is fixedly connected with a rotating shaft, the lower end of the moving auxiliary rod is fixedly connected to the outer peripheral surface of the rotating shaft, the front end of each judgment shaft is rotationally connected with a length judgment rod, the lower end of each length judgment rod is rotationally connected with a joint rotating shaft, the lower end of each joint rotating shaft is rotationally connected with a joint measuring rod, the length judgment rods are fixedly connected with a, the left end of the side driving shaft is fixedly connected with a side bevel gear, the upper wall of the measuring cavity is rotationally connected with a fixed rotating shaft, the peripheral surface of the fixed rotating shaft is fixedly connected with a transverse bevel gear, the right end of the transverse bevel gear is meshed with the upper end of the side bevel gear, the lower end of the fixed rotating shaft is fixedly connected with a thread block, a thread cavity with a downward opening is arranged in the thread block, the inner wall of the thread cavity is in threaded connection with a movable screw rod, the rear wall of the measuring cavity is fixedly connected with two height measuring blocks, one end of each height measuring block close to the other is provided with a height groove with an opposite opening, the lower end of the movable screw rod is rotationally connected with an upper moving plate, the left end and the right end of the upper moving plate are slidably connected to the side wall of the height groove, the front end of each height measuring, the lower end of the upper moving plate is fixedly connected with two height measuring springs, the two height measuring springs are arranged in a bilateral symmetry mode by taking the central line of the upper moving plate as a symmetry center, the lower ends of the height measuring springs are fixedly connected with a lower moving plate, the left end and the right end of the lower moving plate are connected onto the inner wall of the height groove in a sliding mode, the lower end of the height measuring block is rotatably connected with two static torsion springs, the two static torsion springs are arranged in a bilateral symmetry mode by taking the central line of the lower moving plate as a symmetry center, the inner peripheral surface of each static torsion spring is fixedly connected with a static rotating shaft, the lower end of each static torsion spring is fixedly connected with a static swinging block, when a finished product needs to be measured, and when the finished product enters the measuring cavity, the measuring motor is started at the moment, The thread block rotates to drive the movable screw rod and the upper moving plate to move downwards, when a finished product passes through the position below the height measuring block, the finished product pushes the static swing block to swing so as to drive the static torsion spring and the static rotating shaft to rotate, when the height of the finished product is at the position below the lower moving plate, the lower moving plate is driven to move upwards so as to compress the height measuring spring, the lower moving plate and the upper moving plate slide on the inner wall of the height groove, the lower moving plate is pushed to move upwards through the finished product, the upper moving plate moves downwards, and the position relation of the lower moving plate and the upper moving plate on the scale marks is used for judging the height size of the finished product, and when the height of the finished product is measured, the measuring motor is started to drive the main driving shaft and the driving belt pulley to rotate so as to drive the measuring belt, The measuring belt pulley the measuring rotating shaft rotates, and then drives the extension main rod, the extension inductor, the extension spring, the movable auxiliary rod swings, so that a finished product can enter the position between the movable auxiliary rods, the finished product pushes the attachment measuring rod to swing at the moment, and then the attachment rotating shaft rotates, and then the length judging rod swings and further compresses the length measuring spring to further detect the length of the finished product, and the height of the finished product and the length measurement are finished at the moment.

Preferably, the right end of the measuring motor is in power linkage with a width driving shaft, the upper wall of the measuring cavity is fixedly connected with a width measuring block, the width measuring block is internally provided with a width measuring cavity with a downward opening and a leftward opening, the front wall and the rear wall of the width measuring cavity are rotationally connected with two side threaded rods, the two side threaded rods are distributed and arranged in bilateral symmetry by taking the central line of the width measuring cavity as a symmetry center, one ends of the side threaded rods, which are close to each other, are fixedly connected with opposite bevel gears, the right end of the width driving shaft is fixedly connected with a driving bevel gear, the front end and the rear end of the driving bevel gear are in meshing connection with one ends, which are close to each other, of the opposite bevel gears, the peripheral surfaces of the side threaded rods are in threaded connection with width measuring, move down chamber upper wall fixedly connected with and move down the ware, move down ware lower extreme fixedly connected with and move down the spring, move down spring lower extreme fixedly connected with width measurement piece, when finished product detected height and length, get into this moment when width measurement piece downside, start the measuring motor, and then drive the width drive axle drive the drive bevel gear rotates, and then drives relative bevel gear, the side threaded rod rotates, and then drives width measurement threaded block is close to each other and removes, and then drives move down the mobile jib, move down the ware move down the spring, width measurement piece is close to each other and removes, and this moment move down the ware and start, and then the extension move down the spring with width measurement piece makes width measurement piece contact side around the finished product and then detect the width of finished product.

Preferably, fixedly connected with lifting moving motor on the measuring chamber back wall, lifting moving motor front end power is connected with removes the main shaft, fixedly connected with removes main belt pulley on the removal main shaft outer peripheral face, the rotation is connected with the removal countershaft in the measuring chamber back wall, removal countershaft front end fixedly connected with removes vice belt pulley, remove vice belt pulley with it removes to rotate between the main belt pulley and is connected with the removal belt, when needs carry out finished product detection, the finished product gets into when measuring the intracavity, starts lifting moving motor, and then drives remove the main shaft remove main belt pulley and rotate, and then drive remove the belt remove vice belt pulley remove the countershaft and rotate, make the finished product be in remove the belt up end and remove the right detection that moves peripheral size.

Preferably, the left end of the lifting mobile motor is connected with a driving lifting shaft in a power mode, a driving belt pulley is fixedly connected to the outer peripheral surface of the driving lifting shaft, a driven shaft is rotationally connected to the right side wall of the measuring cavity, a driven belt pulley is fixedly connected to the outer peripheral surface of the driven shaft, a lifting belt is rotatably connected between the driven belt pulley and the driving belt pulley, a lifting block is fixedly connected at the front end of the lifting belt, when the finished product is detected, the lifting moving motor is started, thereby driving the driving lifting shaft and the driving belt pulley to rotate and further driving the driven shaft, the lifting belt and the driven belt pulley to rotate, and then the finished product on the upper end surface of the movable belt moves rightwards to the upper end surface of the lifting block, and the lifting belt drives the lifting block to move upwards so that the finished product is conveyed to the outside.

Preferably, a buffer groove with a leftward opening is formed in the left side wall of the measurement cavity, two buffer springs are fixedly connected to the upper wall and the lower wall of the buffer groove, the two buffer springs are arranged in a bilateral symmetry manner by taking the horizontal central line of the measurement cavity as a symmetry center, a buffer block is fixedly connected between the buffer springs, a buffer rotating shaft is rotatably connected to the right end of the buffer block, a buffer plate is fixedly connected to the right end of the buffer rotating shaft, a swinging shaft is rotatably connected to the upper wall of the measurement cavity, a swinging torsion spring is rotatably connected to the inner circumferential surface of the swinging shaft, a rotating shaft is fixedly connected to the inner circumferential surface of the swinging torsion spring, the rotating shaft is rotatably connected to the upper wall of the measurement cavity, a rebound plate is fixedly connected to the left end of the swinging shaft, the left end of the rebound plate is slidably connected to the left side wall of the measurement, the right side wall of the measuring cavity is rotatably connected with a speed reduction torsion spring, the front end of the speed reduction torsion spring is rotatably connected with a speed reduction rod, when the peripheral dimension of a finished product is required to be detected, the finished product enters the measuring cavity through the upper end of the rebound plate, the rebound plate swings to drive the rotating shaft, the swinging shaft and the swinging torsion spring to rotate, the finished product falls on the upper end surface of the buffer plate, the buffer plate swings downwards to drive the buffer rotating shaft to rotate, the buffer rotating shaft drives the buffer block to move downwards, the buffer block compresses the buffer spring on the lower side to stretch the buffer spring on the upper side, when the finished product falls on the upper end surface of the moving belt, the buffer block, the buffer rotating shaft and the buffer plate are reset by the buffer spring on the upper side, and after the finished product is detected to have the length, the width and the height, the finished product is transported to during the gear lever lower extreme, the finished product contacts when the gear lever left end face, the swing of gear lever slows down the finished product and prevents to lead to the finished product flaw to appear because of the speed is too fast, the gear lever swing and then drive the reduction torsional spring rotates, when the finished product is transported to next step, the reduction torsional spring is right the gear lever resets.

The invention has the beneficial effects that: after can accomplish a series of finished products in the workshop, send into the finished product and measure the intracavity and carry out the accurate measurement of periphery size to the finished product to if the size is improper in the measurement process transports scrapped finished product to measuring the chamber external world through conveyer, and continue to detect the periphery size to the finished product of next batch, avoid increasing the cost of labor and having reduced the holistic manufacturing efficiency in workshop because of manual measurement finished product size.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

The invention is further illustrated with reference to the following figures and examples.

Fig. 1 is a schematic diagram of the overall structure of an intelligent finished product dimension measuring device according to the invention.

Fig. 2 is a schematic view of the structure a-a in fig. 1.

FIG. 3 is a schematic diagram of B-B in FIG. 1.

Fig. 4 is an enlarged schematic view of C in fig. 1.

Fig. 5 is an enlarged schematic view of D in fig. 1.

Fig. 6 is an enlarged schematic view of E in fig. 1.

Detailed Description

The invention will now be described in detail with reference to fig. 1-6, wherein for ease of description the orientations described below are now defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The invention relates to an intelligent device for manufacturing and measuring the size of a finished product, which comprises a measuring box 11, wherein a measuring cavity 12 with an upward opening is arranged in the measuring box 11, the upper wall of the measuring cavity 12 is fixedly connected with a measuring motor 35, the front end of the measuring motor 35 is in power connection with a main driving shaft 37, the outer peripheral surface of the main driving shaft 37 is fixedly connected with a driving belt pulley 36, the rear wall of the measuring cavity 12 is in rotary connection with two measuring rotating shafts 34, the two measuring rotating shafts 34 are distributed and arranged in bilateral symmetry by taking the central line of the measuring motor 35 as the symmetry center, the outer peripheral surface of the measuring rotating shaft 34 is fixedly connected with a measuring belt pulley 32, a measuring belt 38 is in rotary connection between the measuring belt pulley 32 and the driving belt pulley 36, the front end of the measuring rotating shaft 34 is fixedly connected with an, an extension sensor 54 is fixedly connected to the upper wall of the extension cavity 55, an extension spring 56 is fixedly connected to the lower end of the extension sensor 54, a moving auxiliary rod 80 is fixedly connected to the lower end of the extension spring 56, the moving auxiliary rod 80 is slidably connected to the inner wall of the extension cavity 55, two judging shafts 79 are rotatably connected to the rear wall of the measurement cavity 12, the two judging shafts 79 are symmetrically distributed around the center line of the main driving shaft 37, a rotating shaft 81 is fixedly connected to the outer circumferential surface of the judging shaft 79, the lower end of the moving auxiliary rod 80 is fixedly connected to the outer circumferential surface of the rotating shaft 81, a length judging rod 78 is rotatably connected to the front end of the judging shaft 79, a fitting rotating shaft 77 is rotatably connected to the lower end of the length judging rod 78, a fitting measuring rod 76 is rotatably connected to the lower end of the fitting rotating shaft 77, and a length measuring spring 57 is fixedly connected to the length judging rod 78 near, the left end of the measuring motor 35 is in power connection with a dual-side driving shaft 33, the left end of the side driving shaft 33 is fixedly connected with a side bevel gear 30, the upper wall of the measuring cavity 12 is rotationally connected with a fixed rotating shaft 29, the peripheral surface of the fixed rotating shaft 29 is fixedly connected with a transverse bevel gear 28, the right end of the transverse bevel gear 28 is in meshed connection with the upper end of the side bevel gear 30, the lower end of the fixed rotating shaft 29 is fixedly connected with a thread block 24, a thread cavity 22 with a downward opening is arranged in the thread block 24, the inner wall of the thread cavity 22 is in threaded connection with a moving screw 21, the rear wall of the measuring cavity 12 is fixedly connected with two height measuring blocks 20, one ends, close to each other, of the height measuring blocks 20 are provided with height grooves 19 with opposite openings, the lower end of the moving screw 21 is rotationally connected with an upper moving plate, the front end of the height measuring block 20 is fixedly connected with eight scale lines 15, the eight scale lines 15 are arranged in bilateral symmetry with the central line of the upper moving plate 31 as the symmetry center, the lower end of the upper moving plate 31 is fixedly connected with two height measuring springs 70, the two height measuring springs 70 are arranged in bilateral symmetry with the central line of the upper moving plate 31 as the symmetry center, the lower end of the height measuring springs 70 is fixedly connected with a lower moving plate 71, the left end and the right end of the lower moving plate 71 are connected with the inner wall of the height groove 19 in a sliding manner, the lower end of the height measuring block 20 is rotatably connected with two static torsion springs 72, the two static torsion springs 72 are arranged in bilateral symmetry with the central line of the lower moving plate 71 as the symmetry center, the inner peripheral surface of the static torsion spring 72 is fixedly connected with a static rotating shaft 73, the lower end of the static torsion spring 72, when a finished product enters the measuring cavity 12, the measuring motor 35 is started at this time, so as to drive the side driving shaft 33 and the side bevel gear 30 to rotate, so as to drive the fixed rotating shaft 29, the transverse bevel gear 28, the thread block 24 to rotate, so as to drive the moving screw 21 and the upper moving plate 31 to move downwards, at this time, when the finished product passes through the position below the height measuring block 20, the finished product pushes the stationary swing block 74 to swing, so as to drive the stationary torsion spring 72 and the stationary rotating shaft 73 to rotate, and when the height of the finished product is at the position below the lower moving plate 71, so as to drive the lower moving plate 71 to move upwards, so as to compress the height measuring spring 70, at this time, the lower moving plate 71 and the upper moving plate 31 slide on the inner wall of the height groove 19, so as to push the lower moving plate 71 to move upwards through the finished product, and the upper moving plate 31 moves, the height and the size of the finished product are determined according to the position relationship of the two on the scale mark 15, and after the height of the finished product is measured, the measuring motor 35 is started to drive the main driving shaft 37 and the driving belt pulley 36 to rotate, so as to drive the measuring belt 38, the measuring belt pulley 32 and the measuring rotating shaft 34 to rotate, so as to drive the extension main rod 53, the extension inductor 54, the extension spring 56 and the moving auxiliary rod 80 to swing, so that the finished product can enter the position between the moving auxiliary rods 80, and at the moment, the finished product pushes the joint measuring rod 76 to swing, so as to drive the joint rotating shaft 77 to rotate, so as to drive the length determining rod 78 to swing, so as to compress the length measuring spring 57 to detect the length of the finished product, and at the moment, the height and the length of the finished product are measured.

Beneficially, the right end of the measuring motor 35 is dynamically linked with a width driving shaft 39, the upper wall of the measuring cavity 12 is fixedly connected with a width measuring block 40, a width measuring cavity 66 with a downward opening and a leftward opening is arranged in the width measuring block 40, two side threaded rods 63 are rotatably connected to the front and rear walls of the width measuring cavity 66, the two side threaded rods 63 are distributed and arranged in bilateral symmetry with the center line of the width measuring cavity 66 as a symmetry center, one end of each side threaded rod 63 close to each other is fixedly connected with a corresponding bevel gear 65, the right end of the width driving shaft 39 is fixedly connected with a driving bevel gear 69, the front and rear ends of the driving bevel gear 69 are engaged with one end of each corresponding bevel gear 65 close to each other, a width measuring threaded block 64 is threadedly connected to the outer peripheral surface of each side threaded rod 63, and a downward moving, move down be equipped with the downward chamber 61 that moves down of opening in mobile jib 62, move down chamber 61 upper wall fixedly connected with and move down ware 67, move down ware 67 lower extreme fixedly connected with and move down spring 68, move down spring 68 lower extreme fixedly connected with width measurement piece 52, when finished product detected height and length, get into this moment during width measurement piece 52 downside, start measurement motor 35, and then drive width drive axle 39 drive axle 69 the drive bevel gear 69 rotates, and then drives relative bevel gear 65 the side threaded rod 63 rotates, and then drives width measurement threaded block 64 is close to each other and removes, and then drives move down mobile jib 62 move down ware 67 move down spring 68 move down width measurement piece 52 is close to each other and removes, at this moment move down ware 67 start, and then the extension move down spring 68 with width measurement piece 52 make width measurement piece 52 contact the side around the finished product and then detect the width of finished product And (6) measuring.

Advantageously, a lifting mobile motor 47 is fixedly connected to the rear wall of the measuring chamber 12, a mobile spindle 48 is dynamically connected to the front end of the lifting mobile motor 47, a movable main belt pulley 49 is fixedly connected on the outer peripheral surface of the movable main shaft 48, a movable auxiliary shaft 60 is rotationally connected on the rear wall of the measuring cavity 12, a moving auxiliary belt wheel 59 is fixedly connected with the front end of the moving auxiliary shaft 60, a moving belt 58 is rotatably connected between the moving auxiliary belt wheel 59 and the moving main belt wheel 49, when the finished product is required to be detected, and the finished product enters the measuring cavity 12 at the moment, the lifting moving motor 47 is started, thereby driving the moving main shaft 48 and the moving main belt pulley 49 to rotate, and further driving the moving belt 58, the moving auxiliary belt pulley 59 and the moving auxiliary shaft 60 to rotate, the finished product is moved rightward on the upper end surface of the moving belt 58 to perform the detection of the outer peripheral dimension.

Advantageously, the left end of the lifting moving motor 47 is connected with a driving lifting shaft 50 by power, a driving belt pulley 51 is fixedly connected on the outer circumferential surface of the driving lifting shaft 50, a driven shaft 43 is rotationally connected with the right side wall of the measuring cavity 12, a driven belt pulley 42 is fixedly connected with the outer peripheral surface of the driven shaft 43, a lifting belt 44 is rotatably connected between the driven pulley 42 and the driving pulley 51, the front end of the lifting belt 44 is fixedly connected with a lifting block 46, when the product is detected, the lifting moving motor 47 is started, thereby driving the driving lifting shaft 50 and the driving pulley 51 to rotate, and further driving the driven shaft 43, the lifting belt 44 and the driven pulley 42 to rotate, and then the finished product on the upper end surface of the moving belt 58 moves to the right to the upper end surface of the lifting block 46, and at the moment, the lifting belt 44 drives the lifting block 46 to move upwards, so that the finished product is conveyed to the outside.

Beneficially, a buffer groove 13 with a leftward opening is formed in the left side wall of the measurement cavity 12, two buffer springs 14 are fixedly connected to the upper and lower walls of the buffer groove 13, the two buffer springs 14 are symmetrically distributed with the horizontal center line of the measurement cavity 12 as the symmetry center, a buffer block 17 is fixedly connected between the buffer springs 14, a buffer rotating shaft 16 is rotatably connected to the right end of the buffer block 17, a buffer plate 18 is fixedly connected to the right end of the buffer rotating shaft 16, a swinging shaft 26 is rotatably connected to the upper wall of the measurement cavity 12, a swinging torsion spring 27 is rotatably connected to the inner circumferential surface of the swinging shaft 26, a rotating shaft 25 is fixedly connected to the inner circumferential surface of the swinging torsion spring 27, the rotating shaft 25 is rotatably connected to the upper wall of the measurement cavity 12, a rebound plate 23 is fixedly connected to the left end of the swinging shaft 26, and the left end of the, the upper wall of the right side of the measuring cavity 12 is provided with an object taking opening 41, the object taking opening 41 is communicated with the measuring cavity 12 and the outside, the right side wall of the measuring cavity 12 is rotatably connected with a decelerating torsion spring 75, the front end of the decelerating torsion spring 75 is rotatably connected with a decelerating rod 45, when the outer peripheral dimension of a finished product is required to be detected, the finished product enters the measuring cavity 12 through the upper end of the rebounding plate 23, the rebounding plate 23 swings to drive the rotating shaft 25, the swinging shaft 26 and the swinging torsion spring 27 to rotate, the finished product falls on the upper end surface of the buffer plate 18, the buffer plate 18 swings downwards to drive the buffer rotating shaft 16 to rotate, the buffer rotating shaft 16 drives the buffer block 17 to move downwards, the buffer block 17 compresses the buffer spring 14 on the lower side, the buffer spring 14 on the upper side is stretched, and when the finished product falls on the upper end surface of the moving belt 58, upside buffer spring 14 will buffer block 17 buffer shaft 16 buffer plate 18 resets, after the long wide high size of finished product detection, the finished product is transported to when the deceleration pole 45 lower extreme, the finished product contacts when the deceleration pole 45 left end face, the swing of deceleration pole 45 slows down the finished product and prevents because of the speed is too fast and lead to the finished product flaw to appear, deceleration pole 45 swing and then drives deceleration torsion spring 75 rotates, when the finished product is transported to next step, deceleration torsion spring 75 is right deceleration pole 45 resets.

The following describes in detail the steps of using an intelligent finished dimension measuring device according to the present disclosure with reference to fig. 1 to 6:

initially, the measurement motor 35, the lifting movement motor 47, the extension sensor 54, and the down-mover 67 are in a closed state, the buffer plate 18 is located at the horizontal middle position of the measurement cavity 12, the down-mover 71 and the up-mover 31 are located above the height measurement block 20, the height measurement spring 70 is in a stretched state, the width measurement block 52 is located above the measurement cavity 12, the lifting block 46 is located below the right side of the measurement cavity 12, the auxiliary movement rod 80, the length determination rod 78, and the attachment measurement rod 76 are in a mutually separated state, the length measurement spring 57 is in a stretched state, and the width measurement screw block 64 and the down-mover 62 are in mutually separated positions.

When the product detection is needed, when the finished product enters the measuring cavity 12, the lifting moving motor 47 is started to drive the moving main shaft 48 and the moving main belt pulley 49 to rotate, and further drive the moving belt 58, the moving auxiliary belt pulley 59 and the moving auxiliary shaft 60 to rotate, so that the finished product moves rightwards on the upper end surface of the moving belt 58 for detecting the peripheral dimension, at the moment, the finished product enters the measuring cavity 12 through the upper end of the rebound plate 23, at the moment, the rebound plate 23 swings to drive the rotating shaft 25, the swinging shaft 26 and the swinging torsion spring 27 to rotate, at the moment, the finished product falls on the upper end surface of the buffer plate 18, the buffer plate 18 swings downwards to drive the buffer rotating shaft 16 to rotate, the buffer rotating shaft 16 drives the buffer block 17 to move downwards, at the moment, the buffer block 17 compresses the buffer spring 14 and stretches the buffer spring 14 on the upper side, when the finished product falls on the upper end surface of, buffer spring 14 of upside resets buffer block 17, buffering pivot 16, buffer board 18, after the finished length, width and height dimensions of finished product detection, when the finished product was transported to speed reduction pole 45 lower extreme, when the finished product contacted speed reduction pole 45 left end face, the swing of speed reduction pole 45 slowed down the finished product and prevented that the flaw appears because of the speed is too fast leading to the finished product, speed reduction pole 45 swings and then drives speed reduction torsion spring 75 and rotate, when the finished product was transported to next step, speed reduction torsion spring 75 resets speed reduction pole 45.

When the finished product is required to measure the dimension, when the finished product enters the measuring cavity 12, the measuring motor 35 is started, the side driving shaft 33 and the side bevel gear 30 are driven to rotate, the fixed rotating shaft 29, the transverse bevel gear 28 and the thread block 24 are driven to rotate, the moving screw 21 and the upper moving plate 31 are driven to move downwards, when the finished product passes through the position below the height measuring block 20, the finished product pushes the static swinging block 74 to swing, the static torsion spring 72 and the static rotating shaft 73 are driven to rotate, when the height of the finished product is at the position below the lower moving plate 71, the lower moving plate 71 is driven to move upwards, the height measuring spring 70 is compressed, when the lower moving plate 71 and the upper moving plate 31 slide on the inner wall of the height groove 19, the finished product pushes the lower moving plate 71 to move upwards, and when the upper moving plate 31 moves downwards, the position relationship of the lower moving plate 71 and the upper moving plate, after the height of the finished product is measured, the measuring motor 35 is started to drive the main driving shaft 37 and the driving belt pulley 36 to rotate, further drive the measuring belt 38, the measuring belt pulley 32 and the measuring rotating shaft 34 to rotate, further drive the extension main rod 53, the extension sensor 54, the extension spring 56 and the moving auxiliary rod 80 to swing, so that the finished product can enter the position between the moving auxiliary rods 80, at the moment, the finished product pushes the attachment measuring rod 76 to swing, further drive the attachment rotating shaft 77 to rotate, further drive the length judging rod 78 to swing, further compress the length measuring spring 57 to detect the length of the finished product, at the moment, the height and length of the finished product are measured, at the moment, when the finished product enters the lower side of the width measuring block 52, the measuring motor 35 is started, further drive the width driving shaft 39 and the driving bevel gear 69 to rotate, further drive the opposite bevel gear 65 and the side threaded rod 63 to rotate, and then the downward moving main rod 62, the downward moving device 67, the downward moving spring 68 and the width measuring block 52 are driven to move close to each other, at this time, the downward moving device 67 is started, and then the downward moving spring 68 and the width measuring block 52 are extended to enable the width measuring block 52 to contact the front side and the rear side of the finished product so as to detect the width of the finished product.

After the product is detected, the lifting moving motor 47 is started at this time, so as to drive the driving lifting shaft 50 and the driving belt pulley 51 to rotate, further drive the driven shaft 43, the lifting belt 44 and the driven belt pulley 42 to rotate, further enable the finished product on the upper end surface of the moving belt 58 to move rightwards to the upper end surface of the lifting block 46, and at this time, the lifting belt 44 drives the lifting block 46 to move upwards, so that the finished product is conveyed to the outside.

The invention has the beneficial effects that: according to the invention, after a series of finished products are finished in a workshop, the finished products are conveyed into the measuring cavity, the peripheral dimension of the finished products is accurately measured, if the finished products are found to be improper in dimension in the measuring process, the scrapped finished products are conveyed to the outside of the measuring cavity through the conveying device, the peripheral dimension of the finished products in the next batch is continuously detected, the problem that the manual cost is increased due to the fact that the sizes of the finished products are measured manually is avoided, and the overall manufacturing efficiency of the workshop is reduced.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims (5)

1. The utility model provides an intelligence is made and is measured finished product size device, includes the measuring box, its characterized in that: the measuring box is internally provided with a measuring cavity with an upward opening, the upper wall of the measuring cavity is fixedly connected with a measuring motor, the front end of the measuring motor is in power connection with a main driving shaft, the outer peripheral surface of the main driving shaft is fixedly connected with a driving belt pulley, the rear wall of the measuring cavity is rotationally connected with two measuring rotating shafts, the two measuring rotating shafts are arranged in bilateral symmetry distribution by taking the central line of the measuring motor as a symmetry center, the outer peripheral surface of the measuring rotating shaft is fixedly connected with a measuring belt pulley, a measuring belt is rotationally connected between the measuring belt pulley and the driving belt pulley, the front end of the measuring rotating shaft is fixedly connected with an extension main rod, an extension cavity with a downward opening is arranged in the extension main rod, the upper wall of the extension cavity is fixedly connected with an extension inductor, the lower end of the, the movable auxiliary rod is connected to the inner wall of the extension cavity in a sliding manner, two judging shafts are rotationally connected to the rear wall of the measurement cavity, the two judging shafts are symmetrically distributed in a left-right manner by taking the central line of the main driving shaft as a symmetry center, a rotating shaft is fixedly connected to the outer peripheral surface of the judging shaft, the lower end of the movable auxiliary rod is fixedly connected to the outer peripheral surface of the rotating shaft, a length judging rod is rotationally connected to the front end of the judging shaft, the lower end of the length judging rod is rotationally connected with a fitting rotating shaft, the lower end of the fitting rotating shaft is rotationally connected with a fitting measuring rod, length judging rods are fixedly connected to the outer peripheral surfaces of the length judging rods, the length measuring springs are fixedly connected to the end surfaces, the left end of the measuring motor is dynamically connected with a dual-side driving shaft, the left end of the side, the right end of the transverse bevel gear is meshed with the upper end of the lateral bevel gear, the lower end of the fixed rotating shaft is fixedly connected with a thread block, a thread cavity with a downward opening is arranged in the thread block, the inner wall of the thread cavity is in threaded connection with a movable screw rod, the rear wall of the measurement cavity is fixedly connected with two height measurement blocks, one ends of the height measurement blocks, which are close to each other, are provided with height grooves with opposite openings, the lower end of the movable screw rod is rotatably connected with an upper moving plate, the left end and the right end of the upper moving plate are slidably connected to the side walls, which are far away from each other, of the height measurement blocks, the front ends of the height measurement blocks are fixedly connected with eight scale marks, the eight scale marks are distributed and arranged in a bilateral symmetry mode by taking the central line of the upper moving plate as a symmetry center, the, the height measurement spring lower extreme fixedly connected with moves down the board, move down the board left and right ends sliding connection in on the high inslot wall, height measurement piece lower extreme rotates and is connected with two static torsional springs, two static torsional springs use move down the board central line and set up as the symmetry center bilateral symmetry, static torsional spring inner peripheral surface fixedly connected with static pivot, the static pendulum piece of static torsional spring lower extreme fixedly connected with.

2. The intelligent finished product sizing device as recited in claim 1, further comprising: the width measuring device is characterized in that a width driving shaft is dynamically linked at the right end of the measuring motor, a width measuring block is fixedly connected to the upper wall of the measuring cavity, a width measuring cavity with a downward opening and a leftward opening is arranged in the width measuring block, two side threaded rods are rotationally connected to the front wall and the rear wall of the width measuring cavity, the two side threaded rods are symmetrically distributed on the left and right sides of the width measuring cavity by taking the center line of the width measuring cavity as the center of symmetry, the side threaded rods are close to each other, one ends of the side threaded rods are fixedly connected with opposite bevel gears, the right end of the width driving shaft is fixedly connected with a driving bevel gear, the front end and the rear end of the driving bevel gear are meshed with one ends of the opposite bevel gears, the outer peripheral surfaces of the side threaded rods are in threaded connection with width measuring threaded blocks, the lower end of the downward moving device is fixedly connected with a downward moving spring, and the lower end of the downward moving spring is fixedly connected with a width measuring block.

3. The intelligent finished product sizing device as recited in claim 1, further comprising: the measuring device is characterized in that a lifting moving motor is fixedly connected to the rear wall of the measuring cavity, the front end of the lifting moving motor is in power connection with a moving main shaft, a moving main belt pulley is fixedly connected to the outer peripheral surface of the moving main shaft, a moving auxiliary shaft is rotatably connected to the rear wall of the measuring cavity, a moving auxiliary belt pulley is fixedly connected to the front end of the moving auxiliary shaft, and a moving belt is rotatably connected between the moving auxiliary belt pulley and the moving main belt pulley.

4. The intelligent finished product sizing device as recited in claim 3, further comprising: the left end of the lifting moving motor is in power connection with a driving lifting shaft, a driving belt pulley is fixedly connected to the outer peripheral surface of the driving lifting shaft, a driven shaft is connected to the right side wall of the measuring cavity in a rotating mode, a driven belt pulley is fixedly connected to the outer peripheral surface of the driven shaft, a lifting belt is rotatably connected between the driven belt pulley and the driving belt pulley, and a lifting block is fixedly connected to the front end of the lifting belt.

5. The intelligent finished product sizing device as recited in claim 1, further comprising: the left side wall of the measuring cavity is provided with a buffer groove with a leftward opening, the upper wall and the lower wall of the buffer groove are fixedly connected with two buffer springs, the two buffer springs are arranged in a bilateral symmetry mode by taking the horizontal central line of the measuring cavity as a symmetry center, a buffer block is fixedly connected between the buffer springs, the right end of the buffer block is rotatably connected with a buffer rotating shaft, the right end of the buffer rotating shaft is fixedly connected with a buffer plate, the upper wall of the measuring cavity is rotatably connected with a swinging shaft, the inner peripheral surface of the swinging shaft is rotatably connected with a swinging torsional spring, the inner peripheral surface of the swinging torsional spring is fixedly connected with a rotating shaft, the rotating shaft is rotatably connected in the upper wall of the measuring cavity, the left end of the swinging shaft is fixedly connected with a rebound plate, the left end of the rebound plate is slidably connected on the left side wall of, the right side wall of the measuring cavity is rotatably connected with a speed reduction torsion spring, and the front end of the speed reduction torsion spring is rotatably connected with a speed reduction rod.

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