CN220446848U - Pressing mechanism and squaring machine - Google Patents

Abstract

The application belongs to the technical field of silicon material processing, and particularly relates to a material pressing mechanism and a squaring machine, wherein the material pressing mechanism comprises a pressing plate, a lifting structure, a detection element and a protective cover assembly; the protective cover assembly is provided with a supporting structural member, the supporting structural member is used for dividing the protective cover assembly into an upper part and a lower part, and the upper part and the lower part of the protective cover assembly are of telescopic structures; the pressing plate is fixedly arranged on the supporting structural member of the protective cover assembly and is positioned at the outer side of the upper part of the protective cover assembly, and the pressing plate is in pressing contact with the workpiece; the lifting structure is fixedly arranged on the supporting structural member and positioned at the inner side of the protective cover assembly, and drives the supporting structural member to ascend or descend; the utility model discloses a for full seal structure, can prevent effectively that cutting fluid from getting into inside, keep the structure precision, need not to maintain maintenance, improve work efficiency and reduce maintenance cost, can adapt to simultaneously and compress tightly the work piece of not co-altitude, prevent the precision loss that the work piece displacement caused of shaking at the cutting opportunity bed.

Description

Pressing mechanism and squaring machine

Technical Field

The utility model belongs to the technical field of silicon material processing, and particularly relates to a material pressing mechanism and a squaring machine.

Background

The main way of opening the silicon rod on the market at present is in wire saw processing by single diamond wire reciprocating cutting. When the squaring machine cuts the silicon rod, the silicon rod needs to be fixed to ensure that the cutting mechanism cuts according to the cutting requirement, the existing silicon rod pressing devices are two, and the first is that an operator needs to frequently disassemble and assemble a clamp to realize fixation before cutting and release fixation after cutting of the silicon rod, so that the manual disassembly production efficiency is extremely low; the second is that cooperation material feeding unit will wait to cut the silicon rod and carry cutting mechanism below, has two closing device that symmetry set up to compress tightly the both ends of silicon rod, and this structure is redundant complicated not only, and occupation space is big, is unfavorable for equipment miniaturization, can't measure the radial runout of silicon rod, can not realize the accurate cutting of silicon rod. In order to lubricate the cutting area, clean the cuttings and control and reduce the temperature of the cutting area during cutting, the cutting area needs to be sprayed with cutting fluid, the cutting fluid splashes into the pressing device to corrode internal parts, the pressing device needs to be frequently maintained, and the use cost of equipment is increased. Therefore, a pressing mechanism of a silicon rod is needed, which can solve the defects of the prior art.

Disclosure of Invention

Aiming at the defects of the prior art, the novel material pressing mechanism and the squaring machine are provided, the lifting mechanism in the material pressing mechanism is of a fully-sealed structure, the occupied space is small, the structure is compact, the stress is reasonable, cutting fluid can be effectively placed into the material pressing mechanism, the structural precision is kept, maintenance is not needed, the working efficiency is improved, the maintenance cost is reduced, meanwhile, the workpiece pressing mechanism can be adapted to press workpieces with different heights, and the precision loss caused by the shaking of the workpiece displacement of a machine during cutting is prevented.

In order to achieve the above purpose, the technical scheme adopted by the utility model provides a material pressing mechanism, which comprises a pressing plate, a lifting structure, a detection element and a protective cover assembly;

the protective cover assembly is provided with a supporting structural member, the supporting structural member is used for dividing the protective cover assembly into an upper part and a lower part, and the upper part and the lower part of the protective cover assembly are telescopic structures;

the pressing plate is fixedly arranged on the supporting structural member of the protective cover assembly and is positioned on the outer side of the upper part of the protective cover assembly, and the pressing plate is in pressing contact with a workpiece;

the lifting structure is fixedly arranged on the supporting structural member and positioned on the inner side of the protective cover assembly, and drives the supporting structural member to ascend or descend.

Further, the device also comprises a drive control assembly; the upper part of the driving control assembly is fixedly connected with the protective cover assembly, and the driving control assembly is in driving connection with the lifting structure.

Further, the device also comprises a detection element; the detection element is positioned on the outer side of the protective cover assembly and is in communication connection with the cutting mechanism and used for measuring the radial runout of the workpiece by contacting with the surface of the workpiece.

Further, the protective cover assembly further comprises a first protective cover and a second protective cover;

the first protective cover is the upper part of the protective cover assembly, and the second protective cover is the lower part of the protective cover assembly; the top of the first protective cover is closed, the first protective cover is connected with the second protective cover through the supporting structural member, and the bottom of the second protective cover is fixedly arranged on the driving control assembly.

Further, the lifting structure comprises a top plate, a linear bearing, a first nut, a bearing guide rod, a screw rod fixing plate and a coupler; the top plate, the linear bearing, the first nut, the bearing guide rod, the screw rod fixing plate and the coupler are all positioned in the protective cover assembly;

the two linear bearings and the first nut vertically penetrate through the supporting structural member to be fixedly installed, the two bearing guide rods penetrate through the two linear bearings, the screw rod penetrates through the first nut, the first nut moves in a screwing mode along the screw rod, the bearing guide rods slide up and down along the linear bearings, and the moving direction of the bearing guide rods is the same as the moving direction of the first nut on the screw rod;

one ends of the two bearing guide rods and the screw rod extend into the first protective cover, and the other ends extend into the second protective cover; the two bearing guide rods extend into the end part of the first protective cover to be fixedly connected with the top plate, the end part of the screw rod extending into the first protective cover is in contact limit with the top plate through a bearing supporting seat, and the end part of the two bearing guide rods extending into the second protective cover is fixedly connected with the driving control assembly;

the screw rod fixing plates are sleeved and installed below the two bearing guide rods, the middle parts of the screw rod fixing plates are provided with mounting holes coaxial with the first nuts of the supporting structural members, the second nuts are fixedly installed in the mounting holes of the screw rod fixing plates, and the end parts of the screw rods, which extend into the second protective covers, penetrate through the second nuts on the screw rod fixing plates and are connected with the driving control assembly through the shaft coupling.

Further, the detection element is a sensor; the sensor is fixedly arranged on the driving control assembly through a sensor bracket, and the head of the sensor faces the side wall of the workpiece.

Further, the first protective cover and the second protective cover are transparent telescopic hoses.

Further, when the protective cover is lifted, the lifting structure drives the pressing plate to lift and compress the upper part of the protective cover component to be in a folded state, and when the protective cover is lifted, the lifting structure drives the pressing plate to lower the top of the workpiece to be tightly pressed and compresses the lower part of the protective cover component to be in a folded state.

Further, the drive control assembly comprises a base and a motor;

the shell of the motor is fixedly arranged inside the base, and an output shaft of the motor extends out of the through hole of the base to be connected with the coupler.

The squaring machine comprises a workbench, a cutting mechanism and a pressing mechanism;

the workbench is provided with a track, the cutting mechanism is positioned at one side of the track of the workbench, the workbench conveys workpieces to the cutting mechanism, and the pressing mechanism is fixedly arranged on a rack of the squaring machine and positioned in front of the workbench moving in place along the track of the workbench towards the cutting mechanism;

the material pressing mechanism is any one of the material pressing mechanisms;

the detection element of the pressing mechanism is in communication connection with the cutting mechanism, and the cutting mechanism is used for receiving the radial runout of the workpiece measured by the detection element and accurately cutting the workpiece based on the measurement result of the detection element.

The beneficial effects of the utility model are as follows:

the first, the utility model of the pressure plate lifting assembly comprises a pressure plate, a lifting structure and a detecting element, wherein the pressure plate is fixedly arranged on a supporting structural member of the protective cover assembly and is positioned at the outer side of the upper part of the protective cover assembly, and the pressure plate is in pressing contact with a workpiece; the detection element is fixedly arranged on the drive control assembly and is positioned on the outer side of the lower part of the protective cover assembly, the detection element is in contact with the surface of a workpiece for measurement, the lifting structure is positioned in the protective cover assembly and is connected with the supporting structural member in the protective cover assembly, the bottom of the lifting structure is connected with the output shaft of the drive control assembly, the lifting structure is of a fully-sealed structure, the occupied space is small, the structure is compact, the stress is reasonable, the protective cover assembly can effectively prevent cutting fluid from entering the interior, the structural precision is maintained, maintenance is not needed, the working efficiency is improved, the maintenance cost is reduced, the detection element can detect the radial runout of the workpiece, the cutting mechanism can accurately cut, meanwhile, the lifting structure can adapt to the pressing of workpieces with different heights, and the precision loss caused by the shaking of the workpiece displacement during cutting is prevented;

the second sensor is connected with the numerical control system of the cutting mechanism of the squaring machine through the signal wire, the head of the sensor horizontally extends to the outer side of the second protective cover, the head of the sensor faces the side wall of the workpiece to be cut, the sensor inputs the acquired radial runout information of the workpiece to the numerical control system of the cutting mechanism of the squaring machine, and when the measurement of the radial runout of the workpiece acquired by the sensor meets the requirement, the numerical control system of the cutting mechanism of the squaring machine starts cutting according to the data feedback of the sensor, so that the accurate cutting of the cutting mechanism is realized;

third, the first protective cover and the second protective cover of the utility model are transparent telescopic hoses, can observe and prevent cutting fluid from entering the pressing mechanism, and can also realize operation under severe acidic liquid environment.

Drawings

FIG. 1 is a perspective view of a press mechanism of the present utility model;

fig. 2 is a front view of the press mechanism of the present utility model.

Wherein, 1-the clamp plate lifting assembly; 10-pressing plates; 11-top plate; 12-a linear bearing; 13-a first nut; 14-bearing guide rod; 15-a screw rod; 16-a screw rod fixing plate; 17-coupling; 18-a sensor; 2-a protective cover assembly; 20-a first protective cover; 21-a shield support plate; 22-a second shield; 3-a drive control assembly; 30-a base; 31-an electric motor; a, a workpiece; b-working table.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

As shown in fig. 1 and 2, the utility model provides a pressing mechanism and a squaring machine, wherein the pressing mechanism is fixedly arranged on a frame of the squaring machine and is adjacent to a cutting mechanism of the squaring machine, and is used for pressing the top of a workpiece a conveyed by a workbench B of the squaring machine along a conveying track and measuring radial runout of the workpiece a so as to realize accurate cutting.

The pressing mechanism comprises a pressing plate lifting assembly 1, a protective cover assembly 2 and a driving control assembly 3. The bottom of the protective cover assembly 2 is fixedly connected with the shell of the drive control assembly 3, the protective cover assembly 2 is provided with a supporting structural member, the supporting structural member divides the protective cover assembly 2 into an upper part and a lower part, and the upper part and the lower part of the protective cover assembly 2 are of telescopic pipe structures. The pressing plate lifting assembly 1 comprises a pressing plate, a lifting structure and a radial runout detection element, wherein the pressing plate is fixedly arranged on a supporting structural member of the protective cover assembly 2 and positioned at the outer side of the upper part of the protective cover assembly 2 and used for pressing a workpiece A; the radial runout detection element is fixedly arranged on the drive control assembly 3 and positioned at the outer side of the lower part of the protective cover assembly 2 and is used for measuring the radial runout of the surface of the workpiece A in a contact manner; the lifting structure is positioned in the protective cover assembly 2 and is connected with a supporting structural member in the protective cover assembly 2, and the bottom of the lifting structure is connected with an output shaft of the drive control assembly 3; the driving control assembly 3 drives the lifting structure to ascend or descend in the protective cover assembly 2, and drives the pressing plate to ascend and compress the upper part of the protective cover assembly 2 to be in a folded state when ascending, and drives the pressing plate to descend and compress the lower part of the protective cover assembly 2 to be in a folded state when descending.

The shield assembly 2 includes a first shield 20, a shield support plate 21, and a second shield 22. The first protective cover 20 and the second protective cover 22 are transparent telescopic hoses and are used for preventing cutting fluid from entering the pressing mechanism, and can be operated in a severe acidic liquid environment. Taking the state shown in fig. 1 and 2 as an example, the first protective cover 20 is in a folded state, and the second protective cover 22 is in a stretched state.

The top of the first shield 20 has a first support plate for closing the top surface of the first shield 20; the first protective cover 20 and the second protective cover 22 are connected through a protective cover supporting plate 21, and the protective cover supporting plate 21 is provided with three round holes which are arranged along the length direction; the bottom of the second shield 22 has a second support plate with a central opening, through which the first shield 20, the shield support plate 21 and the second shield 22 are fixedly mounted on the drive control assembly 3.

The pressing plate lifting assembly 1 comprises a pressing plate 10, a top plate 11, a linear bearing 12, a first nut 13, a bearing guide rod 14, a screw rod 15, a screw rod fixing plate 16, a coupler 17 and a sensor 18.

The pressing plate 10 is an L-shaped structural plate, one end of which is vertically fixed to the shield support plate 21 and located outside the first shield 20, and the other end of which horizontally protrudes toward the workpiece a and is located above the outside of the shield support plate 21.

The top plate 11, the linear bearing 12, the first nut 13, the bearing guide rod 14, the screw rod 15, the screw rod fixing plate 16 and the coupler 17 are all positioned inside the protective cover assembly 2. The two linear bearings 12 are respectively sleeved in round holes on two sides of the protective cover supporting plate 21 from top to bottom, the first nut 13 is sleeved in a round hole in the middle of the protective cover supporting plate 21 from top to bottom, and the linear bearings 12 and the flange structure of the first nut 13 are used for limiting and installing. The two bearing guide rods 14 are arranged, the two bearing guide rods 14 vertically penetrate through the two linear bearings 12, the screw rod 15 vertically penetrates through the first nut 13, the ball inside the first nut 13 is screwed with the screw thread on the screw rod 15 to move, the bearing guide rods 14 slide up and down along the linear bearings 12, and the moving direction is the same as the moving direction of the first nut 13 on the screw rod 15.

One end of the two bearing guide rods 14 and one end of the screw rod 15 extend into the first protective cover 20, and the other end extends into the second protective cover 22; the end parts of the two bearing guide rods 14 extending into the first protective cover 20 are fixedly connected with the top plate 11, the end parts of the screw rods 15 extending into the first protective cover 20 are in contact limit with the top plate 11 through bearing supporting seats, and the end parts of the two bearing guide rods 14 extending into the second protective cover 22 penetrate through the second supporting plate and are fixedly connected with the drive control assembly 3.

The screw rod fixing plate 16 is sleeved below the two bearing guide rods 14, a mounting hole coaxial with a middle round hole of the protective cover supporting plate 21 is formed in the middle of the screw rod fixing plate 16, a second nut is sleeved in the mounting hole of the screw rod fixing plate 16 from bottom to top to be fixed, and the end part of the screw rod 15 extending into the second protective cover 22 penetrates through the second nut on the screw rod fixing plate 16 and is connected with the driving control assembly 3 through the coupler 17.

The sensor 18 is fixedly arranged on the driving control assembly 3 through a sensor bracket, the sensor 18 is connected with a numerical control system of a cutting mechanism of the squaring machine through a signal wire, the head of the sensor 18 horizontally extends out of the second protective cover 22, and the head of the sensor faces to the side wall to be cut of the workpiece A. The sensor 18 adopts a contact sensor, and the acquired radial runout information of the workpiece A is input into a numerical control system of a cutting mechanism of the squaring machine, so as to measure radial runout of the cylindrical workpiece and realize accurate cutting of the cutting mechanism. When the measurement of the radial runout of the workpiece collected by the sensor 18 meets the requirement, the numerical control system of the cutting mechanism of the squaring machine starts cutting according to the data feedback of the sensor 18, and the cutting position accuracy is better controlled.

The drive control assembly 3 includes a base 30 and a motor 31. The top of the base 30 is provided with a through hole coaxial with the second nut mounting hole of the screw rod fixing plate 16, the shell of the motor 31 is fixedly arranged inside the base 30, and the output shaft of the motor 31 extends out of the through hole of the base 30 to be connected with the coupler 17. The motor 31 drives the coupler to rotate so as to drive the shield support plate 21 fixedly connected with the first nut 13 to rotate clockwise or anticlockwise along the screw rod 15 to move up and down, and the pressing plate 10 fixedly connected with the shield support plate 21 moves in the same direction, so that workpieces with different heights can be compressed adaptively, and precision loss caused by workpiece vibration displacement of a machine tool during cutting is prevented.

Examples:

the working method of the pressing mechanism and the squaring machine is as follows:

step 1: the workbench B of the squaring machine conveys a workpiece A to a cutting position of a cutting mechanism along a conveying track, a motor 31 controls a first nut 13 mounted on a protective cover supporting plate 21 to rotate and move downwards, a pressing plate 10 presses the top of the workpiece A tightly under the movement of the protective cover supporting plate 21, a sensor 18 contacts with the cylindrical surface of the workpiece A to measure the radial runout of the workpiece A, when the acquired radial runout meets the cutting requirement, the sensor 18 inputs information into a numerical control system of the cutting mechanism, and the cutting mechanism starts the first cutting.

Step 2: after the first cutting is completed, the motor 31 controls the first nut 13 mounted on the shield support plate 21 to rotate and move upwards, the pressing plate 10 moves upwards to the upper part of the top of the workpiece A, and the workbench B of the squaring machine rotates to a preset angle to perform the second cutting.

Step 3: in the same way as step 1, during the second cutting, the motor 31 controls the first nut 13 mounted on the protective cover supporting plate 21 to rotate and move downwards, the pressing plate 10 presses the top of the workpiece A under the movement of the protective cover supporting plate 21, the sensor 18 contacts with the cylindrical surface of the workpiece A to measure the radial runout of the workpiece A, and when the acquired radial runout meets the cutting requirement, the sensor 18 inputs information into the numerical control system of the cutting mechanism to complete the second cutting.

Step 4: and (3) repeating the steps 1 to 3 until the cutting is completed, and conveying the workpiece A to a blanking structure along a conveying track by a workbench B of the squaring machine in a direction far away from the cutting mechanism.

The foregoing is merely exemplary embodiments of the present utility model, and specific structures and features that are well known in the art are not described in detail herein. It will be evident to those skilled in the art that the utility model is not limited to the details of the foregoing illustrative embodiments, and that the present utility model may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (10)

1. The material pressing mechanism is characterized by comprising a pressing plate, a lifting structure, a detection element and a protective cover assembly (2);

the protective cover assembly (2) is provided with a supporting structural member, the supporting structural member is used for dividing the protective cover assembly (2) into an upper part and a lower part, and the upper part and the lower part of the protective cover assembly (2) are of telescopic structures;

the pressing plate is fixedly arranged on the supporting structural member of the protective cover assembly (2) and is positioned on the outer side of the upper part of the protective cover assembly (2), and the pressing plate is in pressing contact with a workpiece;

the lifting structure is fixedly arranged on the supporting structural member and positioned on the inner side of the protective cover assembly (2), and drives the supporting structural member to ascend or descend.

2. The press mechanism according to claim 1, further comprising a drive control assembly (3); the upper part of the driving control assembly (3) is fixedly connected with the protective cover assembly (2), and the driving control assembly (3) is in driving connection with the lifting structure.

3. The swage of claim 1, further comprising a detection element; the detection element is positioned on the outer side of the protective cover assembly (2) and is in communication connection with the cutting mechanism and used for measuring the radial runout of the workpiece by contacting with the surface of the workpiece.

4. The swage of claim 2, wherein the shroud assembly (2) further comprises a first shroud (20) and a second shroud (22);

the first protective cover (20) is the upper part of the protective cover assembly (2), and the second protective cover (22) is the lower part of the protective cover assembly (2); the top of the first protective cover (20) is closed, the first protective cover (20) and the second protective cover (22) are connected through the supporting structural member, and the bottom of the second protective cover (22) is fixedly arranged on the driving control assembly (3).

5. The pressing mechanism according to claim 4, wherein the lifting structure comprises a top plate (11), a linear bearing (12), a first nut (13), a bearing guide rod (14), a screw rod (15), a screw rod fixing plate (16) and a coupler (17); the top plate (11), the linear bearing (12), the first nut (13), the bearing guide rod (14), the screw rod (15), the screw rod fixing plate (16) and the coupler (17) are all positioned in the protective cover assembly (2);

the linear bearings (12) are provided with two, the two linear bearings (12) and the first nut (13) vertically penetrate through the supporting structural part to be fixedly installed, the bearing guide rods (14) are provided with two, the two bearing guide rods (14) penetrate through the two linear bearings (12), the screw rod (15) penetrates through the first nut (13), the first nut (13) moves in a screwing mode along the screw rod (15), and the bearing guide rods (14) slide up and down along the linear bearings (12) and move in the same direction as the moving direction of the first nut (13) on the screw rod (15);

one ends of the two bearing guide rods (14) and the screw rod (15) extend into the first protective cover (20), and the other ends extend into the second protective cover (22); the end parts of the two bearing guide rods (14) extending into the first protective cover (20) are fixedly connected with the top plate (11), the end parts of the screw rods (15) extending into the first protective cover (20) are in contact limit with the top plate (11) through bearing supporting seats, and the end parts of the two bearing guide rods (14) extending into the second protective cover (22) are fixedly connected with the driving control assembly (3);

the screw rod fixing plates (16) are sleeved and installed below the two bearing guide rods (14), the middle parts of the screw rod fixing plates (16) are provided with mounting holes coaxial with the first nuts (13) of the supporting structural members, the second nuts are fixedly installed in the mounting holes of the screw rod fixing plates (16), the screw rods (15) extend into the end parts of the second protective covers (22) and penetrate through the second nuts on the screw rod fixing plates (16), and the second nuts are connected with the driving control assembly (3) through the couplers (17).

6. The swage of claim 2, wherein the detection element is a sensor; the sensor is fixedly arranged on the driving control assembly (3) through a sensor bracket, and the head of the sensor faces the side wall of the workpiece.

7. The swage of claim 4, wherein the first and second shields (20, 22) are clear flexible hoses.

8. The pressing mechanism according to claim 1, wherein the lifting structure drives the pressing plate to lift and compress the upper portion of the protective cover assembly (2) to be in a folded state when lifting, and drives the pressing plate to lower and press the top of the workpiece and compress the lower portion of the protective cover assembly (2) to be in a folded state when lowering.

9. The press mechanism according to claim 5, wherein the drive control assembly (3) comprises a base and a motor;

the shell of the motor is fixedly arranged inside the base, and an output shaft of the motor extends out of the through hole of the base to be connected with the coupler (17).

10. The squaring machine is characterized by comprising a workbench, a cutting mechanism and a pressing mechanism;

the workbench is provided with a track, the cutting mechanism is positioned at one side of the track of the workbench, the workbench conveys workpieces to the cutting mechanism, and the pressing mechanism is fixedly arranged on a rack of the squaring machine and positioned in front of the workbench moving in place along the track of the workbench towards the cutting mechanism;

the material pressing mechanism is the material pressing mechanism of any one of claims 1-9;

the detection element of the pressing mechanism is in communication connection with the cutting mechanism, and the cutting mechanism is used for receiving the radial runout of the workpiece measured by the detection element and accurately cutting the workpiece based on the measurement result of the detection element.