CN111536866A - Conductive material roughness detection device - Google Patents

Abstract

The invention discloses a flatness detection device for a conductive material, which comprises a machine body, wherein a detection cavity is arranged in the machine body, lifting devices are symmetrically arranged at the left side and the right side of the lower side of the detection cavity, each lifting device comprises a lifting cavity communicated with the left side and the right side of the detection cavity, a lifting block capable of sliding up and down is arranged in each lifting cavity, and a lifting plate is fixedly arranged on one end surface of each of the lifting blocks at the left side and the right side, respectively, the flatness of the surface of the conductive material is detected by utilizing the characteristics of the conductive material, a conductive plate is arranged on the lower surface of the conductive material, a conductive probe moving on the upper surface of the conductive material can form a current loop through a wire, when the surface of the conductive material is sunken, the current loop is disconnected, the conductive probe can be detected immediately, the detection efficiency is higher, meanwhile, a skillful mechanism is utilized to control, and the flatness detection of the upper surface and the lower surface is realized.

Description

Conductive material roughness detection device

Technical Field

The invention relates to the technical field of detection equipment, in particular to a flatness detection device for a conductive material.

Background

In production and life, a conductive material is often required to be used, the conductive material needs to meet the requirement of higher accuracy when being applied to some precision equipment, the flatness of the surface of the conductive material is also an important index, the flatness of the surface of some materials has a crucial influence on the use of the conductive material, the flatness detection through naked-eye judgment or by using a simple instrument is often not accurate enough, and the conductive material can be used for more accurate surface flatness detection due to the special conductive characteristic of the conductive material. The present invention sets forth a device that solves the above problems.

Disclosure of Invention

The technical problem is as follows: the flatness of the surface of the conductive material has a crucial influence on the use of the conductive material, and due to the special conductive property of the conductive material, the surface flatness can be accurately detected by utilizing the property.

In order to solve the problems, the embodiment designs a conductive material flatness detection device, which comprises a machine body, wherein a detection cavity is arranged in the machine body, lifting devices are symmetrically arranged on the left side and the right side of the lower side of the detection cavity, each lifting device comprises a lifting cavity communicated with the left side and the right side of the detection cavity, a lifting block capable of sliding up and down is arranged in each lifting cavity, a lifting plate is fixedly arranged on one end surface of each lifting block on the left side and the right side, a lifting screw rod is symmetrically and rotatably arranged in the lower wall of the detection cavity, the upper ends of the lifting screw rods on the left side and the right side penetrate through the lifting plates on the left side and the right side respectively and are in threaded connection, insulating support plates are fixedly arranged on the front side and the rear side of the upper end surface of each lifting plate on the left side and the right side, the front and back of the lower side are symmetrically provided with turnover devices, the turnover devices comprise turnover cavities which are communicated with the front and back sides of the detection cavity, the turnover cavities are mutually far away from one side and are respectively communicated with a slider cavity, a slider is arranged in the slider cavity and can slide up and down, the opposite end faces of the slider on the front and back sides are respectively fixedly provided with turnover blocks, the turnover blocks can slide up and down in the turnover cavities, a turnover screw rod is rotatably arranged between the upper wall and the lower wall of the turnover cavities on the front and back sides, the upper end face of the turnover screw rod penetrates through the turnover blocks and is in threaded connection with the turnover blocks, the opposite end faces of the turnover blocks on the front and back sides are respectively rotatably provided with turnover shafts, the turnover shafts on the front and back sides are close to the outer circular face of one end of the turnover blocks and are fixedly provided with a ratchet inner wheel, the outer circular, clamping blocks are fixedly arranged on the opposite end faces of the turnover shaft on the front side and the rear side respectively, the opposite end faces of the clamping blocks on the front side and the rear side are communicated with the detection cavity, the detection material enters the clamping cavities on the front side and the rear side, scanning devices are symmetrically arranged on the left side and the right side of the detection cavity, each scanning device comprises a hanging block cavity which is symmetrically arranged on the upper side of the detection cavity, a hanging block is arranged in the hanging block cavity in a front-back sliding manner, a hanging column groove is communicated between the hanging block cavity and the detection cavity, a hanging column is fixedly arranged on the lower end face of the hanging block and can slide in the hanging column groove in a front-back sliding manner, moving columns are fixedly arranged on the lower end faces of the hanging columns on the left side and the right side respectively, roller shafts are rotatably arranged in the end faces of the moving columns on the left side and the right side, the detection device is characterized in that roller plates are fixedly arranged on the left wall and the right wall of the upper side of the detection cavity, roller grooves with upward openings are formed in the upper end faces of the roller plates on the left side and the right side, rollers can roll in the roller grooves, rotating shafts are arranged on the left side and the right side between the moving columns in a rotating mode, a rotating drum is fixedly arranged on the outer circular face of each rotating shaft, a spiral thread groove is formed in the outer circular face of each rotating drum, scanning rods are fixedly arranged between the moving columns on the left side and the right side and on the lower side of each rotating drum, scanning columns are arranged on the outer circular face of each scanning rod in a sliding mode, groove blocks are fixedly arranged on the upper end faces of the scanning columns and can slide in the thread grooves, and a detection device is arranged at the lower ends of the scanning columns and can detect the flatness of.

Preferably, the lower end face of the conductive plate is fixedly provided with a conductive joint, and the lower end of the conductive joint is fixedly provided with a conductive plate end lead.

Preferably, the detection device comprises a scanning motor which is arranged at the lower side of the scanning column and has a downward opening, a detection slider cavity is communicated with the upper side of the scanning motor, a detection slider is arranged in the detection slider cavity and can slide up and down, a detection slider spring is fixedly connected between the upper end surface of the detection slider and the upper wall of the detection slider cavity, front and rear universal handles are fixedly arranged at the front and rear sides of the lower end surface of the detection slider, front and rear rotating shafts are fixedly arranged between the front and rear universal handles at the front and rear sides, a universal block is rotationally arranged on the outer circular surface of the front and rear rotating shafts, left and right rotating shafts are rotationally arranged in the left and right end surfaces of the universal block respectively, left and right universal handles are fixedly arranged at the end surfaces far away from each other at the left and right rotating shafts respectively, a detection block is fixedly arranged at the, the detection device is characterized in that a probe cavity with a downward opening is formed in the lower side of the detection block, a conductive probe is fixedly arranged in the upper wall of the probe cavity, and the lower end face of the conductive probe is abutted to the upper end face of the detection material.

Preferably, the detection block and the upper end of the conductive probe are provided with a probe wire cavity communicated with the scanning motor, the scanning column is internally provided with a wire cavity communicated with the scanning motor and the detection cavity at the right side, the upper end face of the conductive probe is fixedly provided with a probe end wire, the probe end wire passes through the probe wire cavity and extends into the detection cavity through the wire cavity, and the other end of the probe end wire is connected with the lower end of the conductive plate end wire.

Preferably, the front side and the rear side are provided with clamping block cavities which are respectively in bilateral symmetry and communicated, the clamping block cavities can be provided with clamping blocks in a left-right sliding mode, and the clamping blocks are arranged on the left side and the right side and are mutually far away from one end face and fixedly provided with clamping springs between the left wall and the right wall of the clamping block cavities.

Preferably, the detection cavity downside is equipped with the lift transmission chamber, the left and right sides the lifting screw lower extreme extends to in the lift transmission chamber lower wall and rotate the connection, the left and right sides the outer disc of lifting screw just be in the lift transmission intracavity is the fixed lifting transmission band pulley that is equipped with respectively, the left and right sides around being equipped with the lift drive belt between the lifting transmission band pulley, lift transmission chamber left side lower wall internal fixation is equipped with elevator motor, the left side is connected to elevator motor up end power the lifting screw lower extreme.

Preferably, the detection cavity lower side is provided with a turnover transmission cavity, the front side and the rear side of the detection cavity lower end extend to the lower wall of the turnover transmission cavity and are connected in a rotating mode, the front side and the rear side of the turnover transmission cavity are respectively and fixedly provided with a turnover transmission belt wheel in the turnover transmission cavity, the front side and the rear side of the turnover transmission cavity are respectively and fixedly provided with a turnover transmission belt wheel, a turnover motor is arranged in the lower wall of the front side of the turnover transmission cavity in a fixed mode, and the front side is in power connection with the upper end face of the turnover motor and is connected.

Preferably, the lower side of the left and right moving columns is provided with a gear cavity, the left and right ends of the rotating shaft extend into the left wall of the gear cavity and the right wall of the gear cavity and are rotatably connected, the outer circular surfaces of the left and right ends of the rotating shaft are fixedly provided with driving gears in the gear cavity, the moving columns on the left and right sides are communicated with the gear cavity and are provided with grooved wheel cavities, the gear cavities on the left and right sides are close to the side wall of the rotating drum and are rotatably provided with transmission shafts between the side walls of the grooved wheel cavities far away from the rotating drum, the outer circular surfaces of the left and right sides of the transmission shafts far away from the rotating drum are fixedly provided with transmission gears meshed with the driving gears, the outer circular surfaces of the side of the transmission shafts far away from the rotating drum are fixedly provided with driving discs, one ends of the left and right side, and a grooved wheel matched with the driving drive plate is fixedly arranged on the outer circular surface of one end of the roller shaft close to the rotary drum.

Preferably, a scanning motor is fixedly arranged in the left wall of the gear cavity on the left side, and the right end face of the scanning motor is in power connection with the left end of the rotating shaft.

The invention has the beneficial effects that: the invention utilizes the characteristics of the conductive material to detect the flatness of the surface of the conductive material, the conductive plate is arranged on the lower surface of the conductive material, and the conductive probe moving on the upper surface of the conductive material can form a current loop through a wire, when the surface of the conductive material is sunken, the current loop is disconnected, so that the detection can be immediately carried out, the detection efficiency is higher, meanwhile, the conductive probe is controlled by a smart mechanism to automatically scan the upper surface of the detection material, the automatic turnover of the detection material can be realized, and the flatness detection of the upper surface and the lower surface can be realized.

Drawings

For ease of illustration, the invention is described in detail by the following specific examples and figures.

FIG. 1 is a schematic view of the overall structure of a device for detecting flatness of conductive material according to the present invention;

FIG. 2 is a schematic view of the structure in the direction "A-A" of FIG. 1;

FIG. 3 is a schematic view of the structure in the direction "B-B" of FIG. 1;

FIG. 4 is a schematic view of the structure in the direction "C-C" of FIG. 1;

FIG. 5 is an enlarged view of the structure of "D" of FIG. 1;

FIG. 6 is an enlarged view of the structure of "E" of FIG. 1;

fig. 7 is an enlarged view of the structure of "F" of fig. 2.

Detailed Description

The invention will now be described in detail with reference to fig. 1-7, for ease of description, the orientations described below will now be 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 a flatness detection device for a conductive material, which comprises a machine body 11, wherein a detection cavity 12 is arranged in the machine body 11, lifting devices 101 are symmetrically arranged at the left side and the right side of the lower side of the detection cavity 12, the lifting devices 101 comprise lifting cavities 13 communicated with the left side and the right side of the detection cavity 12, lifting blocks 14 capable of sliding up and down are arranged in the lifting cavities 13, lifting plates 15 are respectively and fixedly arranged at the opposite end faces of the lifting blocks 14 at the left side and the right side, lifting screw rods 17 are symmetrically and rotatably arranged in the lower wall of the detection cavity 12, the upper ends of the lifting screw rods 17 at the left side and the right side respectively penetrate through the lifting plates 15 at the left side and the right side and are in threaded connection, insulating support plates 16 are fixedly arranged at the front side and the rear side of the upper end faces of the lifting plates 15 at the left side and the right side, a conductive plate 19, the turnover device 102 comprises turnover cavities 37 communicated with the front side and the rear side of the detection cavity 12, the turnover cavities 37 are mutually far away from one side and respectively communicated with a slider cavity 38, a slider 39 can slide up and down in the slider cavity 38, the opposite end faces of the slider 39 are respectively fixedly provided with turnover blocks 40 at the front side and the rear side, the turnover blocks 40 can slide up and down in the turnover cavities 37, turnover screws 41 are rotatably arranged between the upper wall and the lower wall of the turnover cavities 37 at the front side and the rear side, the upper end faces of the turnover screws 41 penetrate through the turnover blocks 40 and are in threaded connection, turnover shafts 36 are respectively rotatably arranged in the opposite end faces of the turnover blocks 40 at the front side and the rear side, the turnover shafts 36 at the front side and the rear side are close to the outer circular face at one end of the turnover blocks 40, ratchet inner wheels 42 are fixedly arranged on the outer circular face of the ratchet inner wheels 42, ratchet outer wheels 43 are rotatably arranged on the front side, front and back both sides the relative terminal surface of trip shaft 36 is fixed respectively and is equipped with presss from both sides tight piece 35, front and back both sides press from both sides tight piece 35 and communicate in the relative terminal surface of tight piece 35, it presss from both sides tight chamber 49 to detect the material 18 front and back side and enter front and back both sides in pressing from both sides tight chamber 49, it is equipped with scanning device 103 to detect chamber 12 upside bilateral symmetry, scanning device 103 includes bilateral symmetry locates hang piece chamber 25 of detection chamber 12 upside, hang piece chamber 25 internal energy gliding be equipped with hang piece 26 around, hang piece chamber 25 with it is equipped with hang post groove 82 to detect between the chamber 12 intercommunication, hang under the piece 26 terminal surface fixed be equipped with hang post 27, hang post 27 can slide around in hang post groove 82, the left and right sides the terminal surface is fixed respectively to be equipped with removal post 28 under hang post 27, the left and right sides it rotates respectively in the terminal surface to keep away from each other to move post, the outer circular surface of one end of the left and right roller shafts 62, which is far away from each other, is fixedly provided with a roller 63, the left and right walls of the upper side of the detection cavity 12 are fixedly provided with a roller plate 24, the upper end surface of the left and right roller plates 24 is provided with a roller groove 53 with an upward opening, the roller 63 can roll in the roller groove 53, a rotating shaft 30 is rotatably arranged between the left and right moving columns 28, the outer circular surface of the rotating shaft 30 is fixedly provided with a rotating drum 31, the outer circular surface of the rotating drum 31 is provided with a circle of spiral thread groove 29, a scanning rod 34 is fixedly arranged between the left and right moving columns 28 and at the lower side of the rotating drum 31, the outer circular surface of the scanning rod 34 is provided with a scanning column 33 capable of sliding left and right, the upper end surface of the scanning column 33 is fixedly provided with a groove block 32, the groove block 32 can slide in the thread groove 29, the lower end of the, The conductive plate 19 and the guide form a loop to detect the flatness of the upper end surface of the detection material 18.

Advantageously, the lower end surface of the conductive plate 19 is fixedly provided with a conductive joint 80, and the lower end of the conductive joint 80 is fixedly provided with a conductive plate end lead 81.

Beneficially, the detection device 104 includes a scanning motor 65 disposed at the lower side of the scanning column 33 and having a downward opening, the scanning motor 65 is communicated with the upper side thereof to be provided with a detection slider cavity 66, the detection slider cavity 66 is provided with a detection slider 68 capable of sliding up and down, a detection slider spring 67 is fixedly connected between the upper end surface of the detection slider 68 and the upper wall of the detection slider cavity 66, front and rear universal handles 69 are fixedly disposed at the front and rear sides of the lower end surface of the detection slider 68, front and rear rotating shafts 71 are fixedly disposed between the front and rear universal handles 69 at the front and rear sides, a universal block 70 is rotatably disposed on the outer circumferential surface of the front and rear rotating shafts 71, left and right rotating shafts 73 are rotatably disposed in the left and right end surfaces of the universal block 70, left and right rotating shafts 73 are respectively fixedly disposed at the end surfaces far away from each other, left, the lower end face of the detection block 74 abuts against the upper end face of the detection material 18, a probe cavity 75 with a downward opening is formed in the lower side of the detection block 74, a conductive probe 76 is fixedly arranged in the upper wall of the probe cavity 75, and the lower end face of the conductive probe 76 abuts against the upper end face of the detection material 18.

Advantageously, a probe wire cavity 77 communicating with the scanning motor 65 is disposed in the detecting block 74 and at the upper end of the conductive probe 76, a wire cavity 78 communicating with the scanning motor 65 and the detecting cavity 12 is disposed at the right side in the scanning column 33, a probe end wire 79 is fixedly disposed on the upper end surface of the conductive probe 76, the probe end wire 79 extends into the detecting cavity 12 through the probe wire cavity 77 and the wire cavity 78, and the other end of the probe end wire 79 is connected to the lower end of the conductive plate end wire 81.

The clamping cavities 49 on the front side and the rear side are respectively in bilateral symmetry and are communicated with clamping block cavities 50, clamping blocks 51 are arranged in the clamping block cavities 50 in a left-right sliding mode, and clamping springs 52 are fixedly arranged between end faces, away from each other, of the clamping blocks 51 on the left side and the right side of the clamping block cavities 50.

Beneficially, the detection cavity 12 is provided with a lifting transmission cavity 20 at a lower side thereof, lower ends of the lifting screws 17 at left and right sides thereof extend into a lower wall of the lifting transmission cavity 20 and are rotatably connected, outer circular surfaces of the lifting screws 17 at left and right sides thereof are respectively and fixedly provided with a lifting transmission belt wheel 21 in the lifting transmission cavity 20, a lifting transmission belt 23 is wound between the lifting transmission belt wheels 21 at left and right sides thereof, a lifting motor 22 is fixedly provided in the lower wall of the left side of the lifting transmission cavity 20, and an upper end surface of the lifting motor 22 is in power connection with a lower end of the lifting screw 17 at the left side.

Beneficially, the lower side of the detection cavity 12 is provided with an overturning transmission cavity 45, the lower ends of the front and rear overturning screws 41 extend into the lower wall of the overturning transmission cavity 45 and are rotatably connected, the outer circular surfaces of the front and rear overturning screws 41 are respectively and fixedly provided with overturning transmission belt wheels 46 in the overturning transmission cavity 45, an overturning transmission belt 48 is wound between the overturning transmission belt wheels 46 on the front and rear sides, an overturning motor 47 is fixedly provided in the lower wall of the front side of the overturning transmission cavity 45, and the upper end surface of the overturning motor 47 is in power connection with the lower end of the front side overturning screw 41.

Beneficially, a gear cavity 54 is provided at the inner and lower sides of the left and right moving columns 28, the left and right ends of the rotating shaft 30 respectively extend into the left wall of the left gear cavity 54 and the right wall of the right gear cavity 54 and are rotatably connected, a driving gear 55 is fixedly provided at the outer circumferential surface of the left and right ends of the rotating shaft 30 in the gear cavity 54, a grooved cavity 57 is provided at the left and right moving columns 28 communicating with the gear cavity 54, a driving shaft 58 is rotatably provided between the side wall of the left and right gear cavities 54 close to the drum 31 and the side wall of the grooved cavity 57 away from the drum 31, a driving gear 56 engaged with the driving gear 55 is fixedly provided at the outer circumferential surface of the left and right driving shaft 58 away from the drum 31, a driving dial 59 is fixedly provided at the outer circumferential surface of the side of the left and right driving shafts 58 away from the drum 31, one end of the left and right roller shafts 62 close to the drum 31 extends into the side wall, a grooved wheel 61 matched with the driving dial 59 is fixedly arranged on the outer circular surface of one end of the roller shaft 62 close to the drum 31.

Advantageously, a scanning motor 65 is fixedly arranged in the left wall of the gear cavity 54 on the left side, and the right end face of the scanning motor 65 is in power connection with the left end of the rotating shaft 30.

The following describes in detail the use steps of a conductive material flatness detecting apparatus according to the present disclosure with reference to fig. 1 to 7: in the initial state, the moving column 28 is at the rear limit position, the scanning column 33 is at the left limit position, the elevation plate 15 is at the upper limit position, the detection material 18 is at the upper limit position, and the clamp spring 52 is in a compressed state.

In operation, the scanning motor 65 is started to drive the rotation shaft 30 to rotate through power connection, and further drive the driving gear 55 to rotate, and further drive the transmission gear 56 to rotate through gear engagement, and further drive the transmission shaft 58 to rotate, and further drive the driving dial 59 to rotate, and further drive the grooved pulley 61 to rotate intermittently, and further drive the roller shaft 62 to rotate intermittently, and further drive the roller 63 to rotate intermittently, and further drive the moving column 28 to move intermittently forward, and further drive the hanging column 27 to move intermittently forward, and further drive the hanging block 26 to move intermittently forward, and further drive the rotation shaft 30 to move intermittently forward, and further drive the revolving drum 31 to move intermittently forward, and further drive the scanning rod 34 to move intermittently forward, and further drive the groove block 32 to move intermittently forward, and further drive the scanning column 33 to move intermittently forward, and simultaneously the rotation shaft 30 rotates the revolving drum 31, and further drive the groove block 32 to reciprocate, further, the scanning column 33 is driven to intermittently move forward and simultaneously reciprocate left and right, further the detection slide block 68 is driven to intermittently move forward and simultaneously reciprocate left and right, further the front and rear universal handles 69 are driven to intermittently move forward and simultaneously reciprocate left and right, further the left and right universal handles 72 are driven to intermittently move forward and simultaneously reciprocate left and right, further the universal block 70 is driven to intermittently move forward and simultaneously reciprocate left and right, further the detection block 74 is driven to intermittently move forward and simultaneously reciprocate left and right, further the conductive probe 76 is driven to intermittently move forward and simultaneously reciprocate left and right, when the upper end surface of the detection material 18 is flat, the conductive probe 76 abuts against the upper end surface of the detection material 18, further the conductive loop is formed with the conductive plate 19 of the lower end surface of the detection material 18 through the probe end lead 79 and the conductive plate end lead 81, and when the upper end surface of the detection material 18 is concave, the conductive probe 76 does not abut against the upper end surface of the detection material 18, furthermore, when the upper end surface of the detection material 18 has a small inclination, the detection block 74 can slide up and down and rotate simultaneously, so as to drive the left and right universal handles 72 to slide up and down and rotate simultaneously, so as to drive the universal blocks 70 to slide up and down and rotate simultaneously, so as to drive the front and rear rotating shafts 71 to slide up and down, so as to drive the front and rear universal handles 69 to slide up and down, so as to drive the detection slide block 68 to slide up and down, and after the conductive probe 76 sweeps over the upper end surface of the detection material 18 completely and once to complete a detection step, the scanning motor 65 is stopped, at the same time, the lifting motor 22 is started, and the left lifting screw 17 is driven to rotate through power connection, thereby driving the left lifting transmission belt wheel 21 to rotate, further driving the right lifting transmission belt wheel 21 to rotate through the lifting transmission belt 23, further driving the right lifting screw 17 to rotate, further driving the lifting plate 15 to descend through the threaded connection, further driving the lifting block 14 to descend, further driving the insulating support plate 16 to descend, further driving the conductive plate 19 to descend, when the conductive plate 19 descends to the lower limit position, the turning motor 47 is started, driving the front turning screw 41 to rotate through the power connection, further driving the front turning transmission belt wheel 46 to rotate, further driving the rear turning transmission belt wheel 46 to rotate through the turning transmission belt 48, further driving the rear turning screw 41 to rotate, further driving the turning block 40 to descend through the threaded connection, further driving the slide block 39 to descend, further driving the turning shaft 36 to descend, further driving the clamping block 35 to descend, further driving the detection material 18 to descend, when the turning shaft 36 descends to a half, the ratchet outer wheel 43 is meshed with the rack 44, the turning shaft 36 descends continuously to drive the ratchet outer wheel 43 to rotate, the ratchet outer wheel 43 can drive the ratchet inner wheel 42 to rotate so as to drive the turning shaft 36 to rotate so as to drive the clamping block 35 to rotate so as to drive the detection material 18 to turn over, when the turning block 40 descends to the lower limit position, the detection material 18 turns over by one hundred eighty degrees, the turning motor 47 rotates reversely, the turning block 40 is driven to ascend, the turning shaft 36 is driven to ascend, the ratchet outer wheel 43 rotates reversely, the ratchet outer wheel 43 cannot drive the ratchet inner wheel 42 to rotate so as to drive the detection material 18 to ascend to the upper limit position, the turning motor 47 is stopped, the lifting motor 22 is started at the moment, the conductive plate 19 ascends to the upper limit position, the upper end face of the conductive plate 19 abuts against the lower end face of the conductive plate 19, and the, the other side of the test material 18 is subjected to a test step.

The invention has the beneficial effects that: the invention utilizes the characteristics of the conductive material to detect the flatness of the surface of the conductive material, the conductive plate is arranged on the lower surface of the conductive material, and the conductive probe moving on the upper surface of the conductive material can form a current loop through a wire, when the surface of the conductive material is sunken, the current loop is disconnected, so that the detection can be immediately carried out, the detection efficiency is higher, meanwhile, the conductive probe is controlled by a smart mechanism to automatically scan the upper surface of the detection material, the automatic turnover of the detection material can be realized, and the flatness detection of the upper surface and the lower surface can be realized.

In the above manner, a person skilled in the art can make various changes depending on the operation mode within the scope of the present invention.

Claims (9)

1. The utility model provides a conducting material roughness detection device, includes the organism, its characterized in that: the machine body is internally provided with a detection cavity, lifting devices are symmetrically arranged on the left side and the right side of the lower side of the detection cavity, the lifting devices comprise lifting cavities communicated with the left side and the right side of the detection cavity, lifting blocks capable of sliding up and down are arranged in the lifting cavities, lifting plates are fixedly arranged on the left side and the right side of the lifting blocks respectively, lifting screws are symmetrically and rotatably arranged in the lower wall of the detection cavity, the upper ends of the lifting screws on the left side and the right side penetrate through the lifting plates on the left side and the right side respectively and are in threaded connection, insulating support plates are fixedly arranged on the front side and the rear side of the upper end surface of the lifting plates on the left side and the right side, a current-conducting plate is fixedly arranged on the upper end surface of the insulating support plates, a detection material is placed on the upper end surface of the current-conducting plate, the detection device is characterized in that a slide block is arranged in the slide block cavity in a vertically sliding manner, the opposite end faces of the slide block at the front side and the rear side are respectively fixedly provided with a turnover block, the turnover block can slide vertically in the turnover cavity, a turnover screw rod is rotatably arranged between the upper wall and the lower wall of the turnover cavity at the front side and the rear side, the upper end face of the turnover screw rod penetrates through the turnover block and is in threaded connection with the turnover block, the opposite end faces of the turnover block at the front side and the rear side are respectively rotatably provided with a turnover shaft, the turnover shafts at the front side and the rear side are close to the outer circular face at one end of the turnover block and are fixedly provided with an inner ratchet wheel, the outer circular face of the inner ratchet wheel is rotatably provided with an outer wheel, the front side and the rear side of the turnover cavity are respectively fixedly provided with racks capable of, the front side and the rear side of the detection material enter the front-rear side clamping cavities, scanning devices are symmetrically arranged on the upper side of the detection cavity in the left-right direction, the scanning devices comprise hanging block cavities which are symmetrically arranged on the upper side of the detection cavity in the left-right direction, hanging blocks capable of sliding back and forth are arranged in the hanging block cavities, hanging column grooves are communicated between the hanging block cavities and the detection cavity, hanging columns are fixedly arranged on the lower end faces of the hanging blocks and can slide back and forth in the hanging column grooves, moving columns are respectively fixedly arranged on the lower end faces of the hanging columns on the left side and the right side, roller shafts are respectively rotatably arranged in end faces of the moving columns on the left side and the right side, the outer circular faces of the roller shafts on the left side and the right side, which are far away from each other, roller plates are fixedly arranged on the left wall and the right wall of the upper side of the detection cavity, roller grooves, the left and right sides it is equipped with the axis of rotation to rotate between the removal post, the fixed rotary drum that is equipped with in the outer disc of axis of rotation, the outer disc of rotary drum is equipped with the thread groove of round spiral, the left and right sides it just is in to remove between the post the fixed scanning rod that is equipped with of rotary drum downside, the outer disc of scanning rod can the horizontal slip be equipped with the scanning post, scanning post up end is fixed and is equipped with the groove piece, the groove piece can slide in the thread groove, scanning post lower extreme is equipped with detection device, detection device can pass through detect the roughness of detection material up end with the direction formation return circuit.

2. The conductive material flatness detecting apparatus of claim 1, wherein: the terminal surface is fixed to be equipped with the conductive joint under the current-conducting plate, the fixed conducting plate end wire that is equipped with of conductive joint lower extreme.

3. The conductive material flatness detecting apparatus of claim 1, wherein: the detection device comprises a scanning motor which is arranged at the lower side of the scanning column and has a downward opening, the upper side of the scanning motor is communicated with a detection slide block cavity, a detection slide block is arranged in the detection slide block cavity in a manner of sliding up and down, a detection slide block spring is fixedly connected between the upper end surface of the detection slide block and the upper wall of the detection slide block cavity, front and back universal handles are fixedly arranged at the front and back sides of the lower end surface of the detection slide block, front and back rotating shafts are fixedly arranged between the front and back universal handles at the front and back sides, a universal block is rotationally arranged on the outer circular surface of the front and back rotating shafts, left and right rotating shafts are respectively rotationally arranged in the left and right end surfaces of the universal block, left and right universal handles are respectively fixedly arranged at the end surfaces far away from each other at the left and right rotating shafts, a detection block is fixedly arranged at the lower, and a conductive probe is fixedly arranged in the upper wall of the probe cavity, and the lower end face of the conductive probe is abutted against the upper end face of the detection material.

4. A conductive material flatness detecting apparatus according to claim 3, wherein: the utility model discloses a scanning probe, including scanning motor, detection piece, scanning column, conductive probe, probe end wire, conductive probe, probe end wire, detection piece, and the detection piece is interior and be in the conductive probe upper end is equipped with the intercommunication scanning motor's probe wire chamber, the right side is equipped with the intercommunication in the scanning column scanning motor with the wire chamber in detection chamber, the fixed probe end wire that is equipped with of conductive probe up end, probe end wire passes through probe wire chamber just extends to through the wire chamber the detection intracavity, the other one end of probe end wire.

5. The conductive material flatness detecting apparatus of claim 1, wherein: the clamping cavities are respectively arranged on the front side and the rear side in a bilateral symmetry mode and are communicated with clamping block cavities, clamping blocks are arranged in the clamping block cavities in a sliding mode, the clamping blocks can slide left and right, and clamping springs are fixedly arranged between the clamping blocks, far away from one end face and the left wall and the right wall of the clamping block cavity.

6. The conductive material flatness detecting apparatus of claim 1, wherein: detect the chamber downside and be equipped with lift transmission chamber, the left and right sides the lifting screw lower extreme extends to in the lift transmission chamber lower wall and rotate the connection, the left and right sides the outer disc of lifting screw just be in the lift transmission intracavity is the fixed lifting transmission band pulley that is equipped with respectively, the left and right sides around being equipped with the lift drive belt between the lifting transmission band pulley, lift transmission chamber left side lower wall internal fixation is equipped with elevator motor, the left side is connected to elevator motor up end power the lifting screw lower extreme.

7. The conductive material flatness detecting apparatus of claim 1, wherein: the detection cavity downside is equipped with the upset transmission chamber, both sides around the upset screw rod lower extreme extends to just rotate in the upset transmission chamber lower wall and connect, both sides around the upset screw rod outer disc just is in the upset transmission intracavity is fixed respectively and is equipped with the upset driving pulley, both sides around be equipped with the upset drive belt between the upset driving pulley, upset transmission chamber front side lower wall internal fixation is equipped with the upset motor, the front side is connected to upset motor up end power upset screw rod lower extreme.

8. The conductive material flatness detecting apparatus of claim 1, wherein: the inner lower side of the moving column on the left and right sides is provided with a gear cavity, the left and right ends of the rotating shaft respectively extend to the left side and the right side in the left wall of the gear cavity and are rotatably connected, the outer circular surface of the left and right ends of the rotating shaft is fixedly provided with a driving gear in the gear cavity, the moving column on the left and right sides is communicated with the gear cavity, the gear cavity on the left and right sides is provided with a grooved wheel cavity, the gear cavity on the left and right sides is close to the first side wall of the rotating drum and is rotatably provided with a transmission shaft between the grooved wheel cavity and the side wall far away from the rotating drum, the outer circular surface of the side of the left and right sides of the transmission shaft far away from the rotating drum is fixedly provided with a driving plate, one end of the roller shaft on the left and right sides is, and a grooved wheel matched with the driving drive plate is fixedly arranged on the outer circular surface of one end of the roller shaft close to the rotary drum.

9. The conductive material flatness detecting apparatus of claim 8, wherein: and a scanning motor is fixedly arranged in the left wall of the gear cavity on the left side, and the right end face of the scanning motor is in power connection with the left end of the rotating shaft.

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