CN111413193A - Hardness detection equipment of corrosion resistance new material structure - Google Patents

Abstract

The invention discloses a hardness detection device of a corrosion-resistant new material structure, which comprises a main machine body, wherein a round cavity with an upward opening is formed in the middle of the main machine body, a feeding groove is formed in the rear side of the round cavity, a new material cylinder is placed into the round cavity through the feeding groove, a clamp disc is rotationally arranged in the round cavity, four grooves distributed in an array manner are formed in the periphery of the clamp disc, electromagnets are fixedly embedded in two side walls of each groove, and magnetic clamping blocks used for clamping the new material cylinder are arranged on the two side walls of each groove in a sliding manner. Time and manpower are saved, and errors caused by improper manual operation are avoided.

Description

Hardness detection equipment of corrosion resistance new material structure

Technical Field

The invention relates to the technical field of hardness detection, in particular to hardness detection equipment for a corrosion-resistant new material structure.

Background

With the continuous development of society and the continuous progress of science and technology, more and more new materials are created by people, the new materials are generally required to be subjected to performance detection before the actual life of application, whether the new materials reach the standard or are applicable to the field is judged, the traditional detection method needs to firstly manufacture the new materials into blocks, then workers manually install the new material blocks on the clamps, and then the clamps carrying the new material blocks are installed on the detection equipment by the workers.

Disclosure of Invention

The invention aims to provide a hardness detection device for a corrosion-resistant new material structure, which is used for overcoming the defects in the prior art.

The hardness detection device for the corrosion-resistant new material structure comprises a main machine body, wherein a round cavity with an upward opening is formed in the middle of the main machine body, a feeding groove is formed in the rear side of the round cavity, a new material cylinder is placed into the round cavity through the feeding groove, a clamp disc is rotationally arranged in the round cavity, four grooves distributed in an array mode are formed in the periphery of the clamp disc, electromagnets are fixedly embedded in two side walls of each groove, magnetic clamping blocks used for clamping the new material cylinder are arranged on the two side walls of each groove in a sliding mode, the electromagnets are used for controlling the magnetic clamping blocks to clamp the new material cylinder, two bilaterally symmetrical sliding plates are arranged on the top surface of the main machine body in a sliding mode, a fixed disc is fixedly arranged on one side surface, close to each other, of the two sliding plates, and clamping claws are hinged to each fixed disc, gripper jaw is used for the centre gripping of new material cylinder, two bilateral symmetry's stand has set firmly on the top surface of the host computer body, two equal slip on the side that the stand is close to each other is equipped with elevator slide, two elevator plate has set firmly before the elevator slide, it is equipped with the rotary disk to rotate on the bottom surface of elevator plate, fixed pipe has set firmly on the bottom surface of rotary disk, it is used for knocking the cylindrical hammering ball of new material to slide to be equipped with in fixed pipe, hollow post has still set firmly on the bottom surface of rotary disk, it is used for measuring to slide to be equipped with in the hollow post the hammering ball strikes sunken probe.

According to the technical scheme, a bottom box is fixedly arranged on the lower side of the round cavity, a material pushing block is arranged in the bottom box in a sliding mode from top to bottom, a first air pump is fixedly embedded in the bottom box and is in power connection with the material pushing block, the material pushing block is located on the right lower side of the round cavity, and the material pushing block is used for pushing the new material cylinder at the bottom of the round cavity into the groove.

According to the technical scheme, the two sliding plates are connected with each other in a threaded fit mode, a bottom motor is fixedly arranged on the bottom surface of the main body, a bottom shaft extending rightwards is connected to the right end of the bottom motor in a power connection mode, two power belt wheels in bilateral symmetry are fixedly arranged on the periphery of the bottom shaft, two driven belt wheels are fixedly arranged on the periphery of the transverse screw and are respectively connected with the two corresponding power belt wheels in a belt power mode, and the bottom motor is controlled to work to enable the transverse screw to rotate and further drive the two sliding plates to be close to or far away from each other.

In a further technical scheme, spline sleeves are rotatably arranged in the two sliding plates, clamping rotating wheels are fixedly arranged on one sides of the two spline sleeves, which are close to each other, protrusions are fixedly arranged on the peripheries of the clamping rotating wheels, the protrusions can press the clamping claws, so that the clamping claws clamp a new material cylinder, spline shafts are rotatably arranged in the two upright posts, the two spline shafts are respectively in spline fit connection with the corresponding spline sleeves, first bevel gears are fixedly arranged at the ends of the two spline shafts, which are far away from each other, second bevel gears are rotatably arranged at the rear sides of the first bevel gears, the second bevel gears are meshed with the first bevel gears, third bevel gears are fixedly arranged at the rear ends of the second bevel gears, a rear motor is arranged at the rear side of the clamp disc, fourth bevel gears are dynamically connected to the left and right ends of the rear motor, and the fourth bevel gears are meshed with the third bevel gears, the rear motor is controlled to work, so that the spline shaft drives the clamping rotating wheel to rotate, and the clamping claws clamp the new material cylinder.

The technical scheme is further that the lifting slide block is arranged on the left side and connected with the left side in a threaded fit mode, a lifting motor is fixedly arranged at the top end of the stand column and connected with the lifting slide block in a power mode, a clamp motor is fixedly embedded in the left side wall of the circular cavity, and the clamp motor is connected with the clamp disc in a power mode.

Further technical scheme, the lifter plate is embedded with the rotating electrical machines, the rotating electrical machines with rotary disk power is connected, the left side of rotating electrical machines is embedded with the second air pump admittedly, the top of second air pump with through the hose intercommunication between the fixed pipe, through the work of second air pump makes the hammer batting can reciprocate, the position department that is close to the top in the hollow column has set firmly and has detected the piece, the probe with detect and install the detection spring between the piece, it can detect to detect the piece the elasticity change of detection spring.

The invention has the beneficial effects that: the invention realizes automatic clamping of a new material cylinder through the magnetic clamping block, then realizes automatic feeding through the overturning of the clamping disc, enables the clamping claws to automatically clamp the new material cylinder through the mutual approaching of the two sliding plates and the rotation of the clamping rotating wheel, saves the trouble of manually installing the new material cylinder on the clamp, saves time and manpower, avoids errors caused by improper manual operation, simultaneously, a hammering ball impacts the new material cylinder, then a rotating disc rotates, and a probe moves downwards to detect the depth of a recess, thereby obtaining the hardness of the new material cylinder, and simultaneously, because the feeding of the invention is simple and does not need manpower, a plurality of new material cylinders can be detected in a short time, so as to be convenient for taking an average value, and lead the measurement result to be more accurate, and simultaneously, the invention has simple structure, convenient operation and popularization.

Drawings

FIG. 1 is a schematic view of the internal structure of a hardness testing device of a new corrosion-resistant material structure according to the present invention;

FIG. 2 is a left side view of the present invention at the chuck plate;

FIG. 3 is a side schematic view of a clamping rotor of the present invention;

FIG. 4 is a partially enlarged view of the rear side motor of the present invention;

FIG. 5 is an enlarged partial view of the probe of the present invention;

fig. 6 is a partially enlarged view of the gripper jaw of the present invention.

Detailed Description

For purposes of making the objects and advantages of the present invention more apparent, the following detailed description of the invention, taken in conjunction with the examples, should be understood that the following text is only intended to describe one or several specific embodiments of the invention, and not to strictly limit the scope of the invention as specifically claimed, and as used herein, the terms upper, lower, left and right are not limited to their strict geometric definitions, but include tolerances for reasonable and inconsistent machining or human error, the following detailed description of the specific features of the hardness testing apparatus for the new material structure of corrosion resistance:

referring to fig. 1 to 6, the hardness testing apparatus for a new corrosion-resistant material structure according to an embodiment of the present invention includes a main body 10, a circular cavity 30 having an upward opening is formed in a middle position of the main body 10, a feeding chute 32 is formed at a rear side of the circular cavity 30, a new material cylinder is placed in the circular cavity 30 through the feeding chute 32, a clamp plate 22 is rotatably disposed in the circular cavity 30, four grooves 36 are formed in the periphery of the clamp plate 22, four rows of grooves 36 are distributed in an array, an electromagnet 38 is fixedly embedded in two side walls of each groove 36, magnetic clamping blocks 37 for clamping the new material cylinder are slidably disposed on two side walls of each groove 36, the electromagnet 38 is used for controlling the magnetic clamping blocks 37 to clamp the new material cylinder, two sliding plates 39 which are symmetrical to each other are slidably disposed on a top surface of the main body 10, a fixed plate 41 is disposed on one side surface of the two sliding plates 39 which are close to each other, it has gripper jaw 40 all to articulate on the fixed disk 41, gripper jaw 40 is used for the new material cylinder centre gripping, two bilateral symmetry's stand 12 has set firmly on the top surface of host computer body 10, two all slide on the side that stand 12 is close to each other and be equipped with lifting slide 14, two lifting slide 14 has set firmly lifter plate 13 before, it is equipped with rotary disk 20 to rotate on the bottom surface of lifter plate 13, fixed pipe 35 has set firmly on the bottom surface of rotary disk 20, it is used for striking the cylindrical hammering ball 33 of new material to slide in the fixed pipe 35, hollow post 55 has still set firmly on the bottom surface of rotary disk 20, it is used for measuring to slide in the hollow post 55 hammer 33 hits the sunken probe 52 of batting.

Advantageously or exemplarily, a bottom box 27 is fixedly arranged on the lower side of the circular cavity 30, a material pushing block 29 is slidably arranged in the bottom box 27 up and down, a first air pump 28 is fixedly embedded in the bottom box 27, the first air pump 28 is in power connection with the material pushing block 29, the material pushing block 29 is positioned on the right lower side of the circular cavity 30, and the material pushing block 29 is used for pressing the new material cylinder at the bottom of the circular cavity 30 into the groove 36.

Beneficially or exemplarily, a lateral surface of each of the two upright posts 12 close to each other is rotatably provided with a transverse screw 46, the two transverse screws 46 are respectively in threaded fit connection with the two corresponding sliding plates 39, a bottom motor 11 is fixedly arranged on the bottom surface of the main body 10, a right end of the bottom motor 11 is in power connection with a bottom shaft 26 extending rightwards, two power pulleys 61 symmetrical to each other are fixedly arranged on the periphery of the bottom shaft 26, driven pulleys 62 are fixedly arranged on the peripheries of the two transverse screws 46, the two driven pulleys 62 are respectively in power connection with the two corresponding power pulleys 61 through belts 25, and the transverse screws 46 are rotated by controlling the operation of the bottom motor 11, so as to drive the two sliding plates 39 to approach to each other or move away from each other.

Advantageously or exemplarily, spline housings 43 are rotatably provided in both the sliding plates 39, clamping rotating wheels 42 are fixedly provided on the sides of the spline housings 43 close to each other, protrusions 47 are fixedly provided on the peripheries of the clamping rotating wheels 42, the protrusions 47 can press against the clamping claws 40, so that the clamping claws 40 clamp the new material cylinder, spline shafts 44 are rotatably provided in both the columns 12, the spline shafts 44 are respectively in spline fit connection with the corresponding spline housings 43, first bevel gears 24 are fixedly provided on the ends of the spline shafts 44 far away from each other, second bevel gears 21 are rotatably provided on the rear sides of the first bevel gears 24, the second bevel gears 21 are engaged with the first bevel gears 24, third bevel gears 50 are fixedly provided on the rear ends of the second bevel gears 21, rear side motors 48 are provided on the rear sides of the fixture discs 22, fourth bevel gears 51 are dynamically connected to both the left and right ends of the rear motors 48, the fourth bevel gear 51 is engaged with the third bevel gear 50, and the spline shaft 44 drives the clamping runner 42 to rotate by controlling the rear motor 48 to work, so that the clamping claw 40 clamps the new material cylinder.

Beneficially or exemplarily, a vertical screw rod 19 is rotatably disposed in the left-side upright 12, the vertical screw rod 19 is in threaded fit connection with the left-side lifting slider 14, a lifting motor 18 is fixedly disposed at the top end of the left-side upright 12, the lifting motor 18 is in power connection with the vertical screw rod 19, a clamp motor 23 is fixedly embedded in the left-side wall of the circular cavity 30, the clamp motor 23 is in power connection with the clamp disc 22, the clamp disc 22 is rotated by controlling the clamp motor 23, and the lifting plate 13 can move up and down by controlling the lifting motor 18.

Beneficially or exemplarily, a rotary motor 16 is fixedly embedded in the lifting plate 13, the rotary motor 16 is in power connection with the rotary disk 20, a second air pump 15 is fixedly embedded at the left side of the rotary motor 16, the top end of the second air pump 15 is communicated with the fixed pipe 35 through a hose 34, the hammer ball 33 can move up and down by the operation of the second air pump 15, a detection block 54 is fixedly arranged at a position close to the top inside of the hollow column 55, a detection spring 53 is installed between the probe 52 and the detection block 54, and the detection block 54 can detect the change of the elastic force of the detection spring 53.

When the novel material cylinder clamping device is used, a plurality of novel material cylinders are firstly placed into the circular cavity 30, the first air pump 28 is controlled to work, the material pushing block 29 upwards pushes the novel material cylinders to enable the novel material cylinders to be pushed into the bottommost groove 36, the electromagnet 38 in the bottommost part is controlled to work, the two magnetic clamping blocks 37 clamp the novel material cylinders, the clamp motor 23 is controlled to work at the moment, the clamp disc 22 is rotated, the novel material cylinders are turned to the top, the bottom motor 11 is controlled to work, the bottom shaft 26 is rotated, the transverse screw rod 46 is rotated, the two sliding plates 39 are close to each other, the rear side motor 48 is controlled to work, the fourth bevel gear 51 drives the third bevel gear 50 to rotate, the second bevel gear 21 drives the first bevel gear 24 to rotate, the spline shaft 44 drives the spline sleeve 43 to rotate, and the clamping rotating wheel 42 is rotated, so that the protrusion 47 presses against the clamping jaw 40, the clamping jaw 40 clamps the new material cylinder, the electromagnet 38 is controlled to operate to release the magnetic clamping block 37, the lifting motor 18 is controlled to operate to rotate the vertical screw 19, the lifting plate 13 moves downwards for a fixed distance, the probe 52 is attached to the new material cylinder downwards, the detection block 54 detects the elastic force of the detection spring 53, the lifting motor 18 is controlled to rotate reversely to move the lifting plate 13 upwards for a fixed distance, the rotating motor 16 is controlled to operate, the rotating disc 20 rotates to enable the hammer ball 33 to be positioned right above the new material cylinder, the second air pump 15 is controlled to operate to enable the hammer ball 33 to impact the new material cylinder, the rotating motor 16 is controlled to rotate reversely, the probe 52 is positioned above the new material cylinder, the lifting motor 18 is controlled to operate again to enable the lifting plate 13 to move downwards for a fixed distance, and the probe 52 is attached to the impacted part, further, the detection block 54 detects the elastic force of the detection spring 53 again, and the magnitude of the elastic force is calculated twice, and the hardness of the new material cylinder is calculated by the obtained depth of the recess.

The invention has the beneficial effects that: the invention realizes automatic clamping of a new material cylinder through the magnetic clamping block, then realizes automatic feeding through the overturning of the clamping disc, enables the clamping claws to automatically clamp the new material cylinder through the mutual approaching of the two sliding plates and the rotation of the clamping rotating wheel, saves the trouble of manually installing the new material cylinder on the clamp, saves time and manpower, avoids errors caused by improper manual operation, simultaneously, a hammering ball impacts the new material cylinder, then a rotating disc rotates, and a probe moves downwards to detect the depth of a recess, thereby obtaining the hardness of the new material cylinder, and simultaneously, because the feeding of the invention is simple and does not need manpower, a plurality of new material cylinders can be detected in a short time, so as to be convenient for taking an average value, and lead the measurement result to be more accurate, and simultaneously, the invention has simple structure, convenient operation and popularization.

It will be apparent to those skilled in the art that various modifications may be made to the above embodiments without departing from the general spirit and concept of the invention. All falling within the scope of protection of the present invention. The protection scheme of the invention is subject to the appended claims.

Claims (6)

1. The utility model provides a hardness check out test set of corrosion resistance new material structure, includes the host computer body, its characterized in that: the middle position department of the main machine body is provided with a round cavity with an upward opening, the rear side of the round cavity is provided with a feed chute, a new material cylinder is placed into the round cavity through the feed chute, a clamp disc is rotationally arranged in the round cavity, four grooves distributed in an array are arranged on the periphery of the clamp disc, electromagnets are fixedly embedded in two side walls of each groove, magnetic clamping blocks used for clamping the new material cylinder are arranged on the two side walls of each groove in a sliding manner, the electromagnets are used for controlling the magnetic clamping blocks to clamp the new material cylinder, two bilaterally symmetrical sliding plates are arranged on the top surface of the main machine body in a sliding manner, a fixed disc is fixedly arranged on one side surface of each two sliding plates close to each other, clamping claws are hinged to the fixed disc, the clamping claws are used for clamping the new material cylinder, and two bilaterally symmetrical stand columns are fixedly arranged on the top surface of the main machine body, two all slide on the side that the stand is close to each other and be equipped with the elevator slider, two the lifter slider has set firmly the lifter plate before, it is equipped with the rotary disk to rotate on the bottom surface of lifter plate, fixed pipe has set firmly on the bottom surface of rotary disk, it is used for knocking the cylindrical hammering ball of new material to slide to be equipped with in the fixed pipe, hollow post has still set firmly on the bottom surface of rotary disk, it is used for measuring to slide in the hollow post the hammering ball strikes sunken probe.

2. The apparatus for detecting hardness of a new material structure against corrosion according to claim 1, wherein: the novel round cavity structure is characterized in that a bottom box is fixedly arranged on the lower side of the round cavity, a material pushing block is arranged in the bottom box in a vertically sliding mode, a first air pump is fixedly embedded in the bottom box and is in power connection with the material pushing block, the material pushing block is located on the right lower side of the round cavity, and the material pushing block is used for pushing a new material cylinder at the bottom of the round cavity into the groove.

3. The apparatus for detecting hardness of a new material structure against corrosion according to claim 2, wherein: two all rotate on the side that the stand is close to each other and be equipped with horizontal screw rod, two horizontal screw rod respectively with two that correspond the sliding plate screw-thread fit is connected, the bottom motor has set firmly on the bottom surface of the host computer body, the right-hand member power of bottom motor is connected with the bottom shaft that extends right, set firmly two bilateral symmetry's power band pulley in the periphery of bottom shaft, two all set firmly from the driven pulleys in the periphery of horizontal screw rod, two from the driven pulleys respectively with two that correspond the power band pulley passes through belt power and connects, through control bottom motor work makes horizontal screw rod is rotatory, and then drives two the sliding plate is close to each other or keeps away from.

4. The apparatus for detecting hardness of a new material structure against corrosion according to claim 3, wherein: spline sleeves are rotatably arranged in the two sliding plates, clamping rotating wheels are fixedly arranged on one sides, close to each other, of the two spline sleeves, protrusions are fixedly arranged on the peripheries of the clamping rotating wheels and can press the clamping claws, so that the clamping claws clamp a new material cylinder, spline shafts are rotatably arranged in the two upright posts and are respectively in spline fit connection with the corresponding spline sleeves, first bevel gears are fixedly arranged at the ends, far away from each other, of the two spline shafts, second bevel gears are rotatably arranged at the rear sides of the first bevel gears and are meshed with the first bevel gears, third bevel gears are fixedly arranged at the rear ends of the second bevel gears, rear motors are arranged at the rear sides of the clamp discs, fourth bevel gears are dynamically connected to the left ends and the right ends of the rear motors and are meshed with the third bevel gears, the rear motor is controlled to work, so that the spline shaft drives the clamping rotating wheel to rotate, and the clamping claws clamp the new material cylinder.

5. The apparatus for detecting hardness of a new material structure against corrosion according to claim 4, wherein: be located the left the stand internal rotation is equipped with perpendicular screw rod, it is connected with left to erect the screw rod the elevator slide screw-thread fit is connected, is located left the top of stand has set firmly elevator motor, elevator motor with erect screw rod power and connect, the left side wall in circle chamber is embedded to have the anchor clamps motor, the anchor clamps motor with anchor clamps dish power is connected.

6. The apparatus for detecting hardness of a new material structure against corrosion according to claim 5, wherein: the lifting plate is embedded with a rotating motor, the rotating motor is in power connection with the rotating disc, a second air pump is embedded in the left side of the rotating motor, the top end of the second air pump is communicated with the fixed pipe through a hose, the hammer striking ball can move up and down through the work of the second air pump, a detection block is fixedly arranged at a position close to the top in the hollow column, a detection spring is installed between the probe and the detection block, and the detection block can detect the elastic force change of the detection spring.

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