CN118664452A - Wear-resistant copper supporting tile preparation device and method - Google Patents

Abstract

The invention provides a wear-resistant copper lining tile preparation device and a method thereof, belonging to the field of preparation devices. The device is composed of a bottom plate, a clamping mechanism, a wear-resistant copper lining tile, a lifting and rotating mechanism, an adjusting mechanism, a grinding rod and a conveying mechanism. In the scheme, the output end of the forward and reverse motor is rotated to realize the rotation of a gear E. Since the two gears E are meshed with each other, the two gears E can be rotated simultaneously. The rotation of the gear E can drive the screw rod B to rotate. The rotation of the screw rod B can drive the transmission shaft to rotate. The rotation of the transmission shaft can realize the simultaneous rotation of the two screw rods B. The rotation of the screw rod B can drive the movement of a special-shaped screw rod sleeve. The movement of the special-shaped screw rod sleeve can drive the movement of a connecting rod. The movement of the connecting rod can drive the movement of the grinding rod, thereby adjusting the spacing between the two grinding rods, so that the two grinding rods can be adjusted according to the inner diameters of wear-resistant copper lining tiles of different sizes, thereby grinding wear-resistant copper lining tiles of different sizes.

Description

A wear-resistant copper lining tile preparation device and method

Technical Field

The invention belongs to the technical field of preparation devices, and in particular relates to a preparation device and a method for a wear-resistant copper lining tile.

Background Art

Copper bushings, also known as copper bushings, are divided into many types, including copper rollers for machines, copper bearings, etc. They are used in various light, large and heavy machinery and are important components of machinery. The product has the function of traditional tin bronze bearings. It is made of electrolytic copper as raw material and matched with a variety of trace metal elements, sintered at high temperature, and processed by air pressure centrifugal casting. It has high hardness, excellent wear resistance, and is not easy to produce seizure. It has good casting performance and cutting performance, and has good corrosion resistance in the atmosphere and fresh water. In the absence of lubricants and using water-based lubricants, it has good sliding and self-lubricating properties, is easy to cut, has poor casting performance, and has good corrosion resistance to dilute sulfuric acid. General-purpose structural parts, simple-shaped castings used in ships, instruments, etc., such as sleeves, bushings, bearings, sliders, etc.

The authorization publication number "CN219542758U" records "a copper sleeve inner wall polisher, comprising: a base plate, support columns are fixedly installed at the four corners of the bottom surface of the base plate, a first sliding groove is opened on the top surface of the base plate, a second sliding groove is opened on the top surface of the base plate, the first sliding groove and the second sliding groove are in the same straight line, and a first fixed plate is fixedly installed on the top surface of the base plate; a polishing assembly, the polishing assembly is arranged on the top surface of the base plate, and is used to polish the inner wall of the copper sleeve. By setting the first fixed plate, the first electric push rod can be installed through the first fixed plate, so that the polishing assembly can polish the inner wall of the copper sleeve under the action of the first electric push rod, thereby improving the practicality of the polisher, and by setting the first mounting plate, the drive motor can be installed through the first mounting plate, so that the drive motor drives the grinding wheel to rotate, thereby rotating back and forth to polish the inner wall surface of the copper sleeve."

The above patent polishes the inner wall of the copper sleeve in a rotating manner, but the above patent is not easy to realize the polishing of copper lining tiles with different inner diameters, and can only polish a single size, which has limitations.

Summary of the invention

The object of the present invention is to provide a wear-resistant copper lining tile preparation device and method thereof, aiming to solve the problem in the prior art that it is difficult to grind and polish copper lining tiles with different inner diameters.

To achieve the above object, the present invention provides the following technical solutions:

A wear-resistant copper lining tile preparation device, comprising:

Base plate;

A clamping mechanism, arranged on the top of the base plate;

Wear-resistant copper lining pads are installed on the clamping mechanism;

A lifting and rotating mechanism is arranged on the clamping mechanism;

An adjusting mechanism is arranged on the lifting and rotating mechanism;

Two grinding rods are provided, and the two grinding rods are symmetrically arranged on the adjustment mechanism; and

The conveying mechanism is arranged on the clamping mechanism.

As a preferred solution of the present invention, the clamping mechanism comprises:

A supporting member, arranged on the top of the base plate;

A lifting component is arranged on the top of the base plate;

A clamping component, which is provided in multiple groups, and the multiple groups of clamping components are all arranged on the lifting component; and

The adjusting component is arranged on the lifting component, and the adjusting component is connected with a plurality of groups of clamping components.

As a preferred solution of the present invention, the supporting component includes a supporting column, a clamping plate and a clamping claw A, the supporting column is fixedly connected to the top of the base plate, the clamping plate is fixedly connected to the top of the supporting column, and a plurality of clamping claws A are provided, and the plurality of clamping claws A are all fixedly connected to the top of the clamping plate, and the plurality of clamping claws A are evenly distributed.

As a preferred solution of the present invention, the lifting component includes a guide rod, an electric telescopic rod A, a lifting sleeve, a top plate and a mounting plate. Four guide rods are provided, and the four guide rods are fixedly connected to the top of the bottom plate, and the four guide rods are evenly distributed. The top plate is fixedly connected to the top of the four guide rods, and the lifting sleeve is slidingly sleeved on the four guide rods. Two electric telescopic rods A are provided, and one end of each electric telescopic rod A is fixedly connected to the top of the bottom plate, and the extended end of each electric telescopic rod A is fixedly connected to the lifting sleeve, and the mounting plate is fixedly connected to the circumferential inner wall of the lifting sleeve.

As a preferred solution of the present invention, each group of the clamping components includes a limit rod, a movable plate, a clamping claw B, a T-shaped slide groove and a sliding hole. There are two T-shaped slide grooves, and the two T-shaped slide grooves are both opened at the bottom of the mounting plate, and the two T-shaped slide grooves are symmetrically arranged. The sliding hole is opened at the bottom of the mounting plate, and the sliding hole is located between the two T-shaped slide grooves. There are two T-shaped sliders, and each of the T-shaped sliders is slidably connected in each T-shaped slide groove. The movable plate is fixedly connected to the bottom of the two T-shaped sliders, the limit rod is fixedly connected to the bottom of the movable plate, and one end of the limit rod movably passes through the movable plate and the sliding hole and extends to the upper side of the mounting plate, and the clamping claw B is fixedly connected to the bottom of the limit rod.

As a preferred solution of the present invention, the adjusting component includes a rack, an arc hole, a gear A, a turntable A, a T-shaped mounting groove, a screw rod A, a T-shaped screw rod sleeve, a handwheel and a mounting cylinder, the mounting cylinder is fixedly connected to the top of the mounting disk, the turntable A is rotatably connected to the circumferential surface of the mounting cylinder, a plurality of arc holes are provided, a plurality of the arc holes are all opened at the top of the turntable A, and the plurality of arc holes are evenly distributed, each of the limit rods is movably inserted in each arc hole, the gear A is fixedly connected to the circumferential surface of the turntable A, the T-shaped mounting groove is opened at the top of the lifting sleeve, the screw rod A is rotatably connected between the side walls of the T-shaped mounting groove, and one end of the screw rod A rotates through the lifting sleeve and extends to the outside of the lifting sleeve, the handwheel is fixedly connected to one end of the screw rod A, the T-shaped screw rod sleeve is threadedly connected to the screw rod A, and the T-shaped screw rod sleeve is slidably connected in the T-shaped mounting groove, the rack is fixedly connected to the top of the T-shaped screw rod sleeve, and the rack and gear A are meshed with each other.

As a preferred solution of the present invention, the lifting and rotating mechanism includes an annular slide rail, an electric telescopic rod B, a slide bar, a gear C, a gear D, a driving motor, a T-shaped swivel, a lifting plate, a turntable B and a mounting ring, the annular slide rail is fixedly connected to the top of the mounting cylinder, the T-shaped swivel is rotatably connected in the annular slide rail, the turntable B is fixedly connected to the top of the T-shaped swivel, three slide bars are provided, the three slide bars are movably plugged into the top of the turntable B, and the three slide bars are movably inserted through the turntable B and extend to the outside of the turntable B, and the mounting ring is fixedly connected to the bottom of the three slide bars. The lifting plate is fixedly connected to the circumferential surface of the three sliding rods, and the lifting plate is located between the turntable B and the mounting ring. One end of the electric telescopic rod B is fixedly connected to the top of the turntable B, and the extended end of the electric telescopic rod B movably passes through the turntable B and is fixedly connected to the lifting plate. The gear C is fixedly connected to the circumferential surface of the turntable B. The driving motor is fixedly connected to the bottom of the annular slide rail, and the output end of the driving motor rotates through the annular slide rail and extends to the upper side of the annular slide rail. The gear D is fixedly connected to the output end of the driving motor, and the gear D and the gear C are meshed with each other.

As a preferred solution of the present invention, the adjustment mechanism includes a special-shaped screw sleeve, a cylindrical mounting shell, a screw B, a transmission shaft, a connecting rod, a forward and reverse motor and a gear E. The cylindrical mounting shell is fixedly connected to the bottom of the mounting ring. Two screws B are provided. The two screws B are rotatably connected to the two ends of the cylindrical mounting shell respectively, and the two screws B are rotated through the cylindrical mounting shell and extend to the inner side of the cylindrical mounting shell. The transmission shaft is fixedly connected between the two screws B. Two special-shaped screw sleeves are provided. Each of the special-shaped screw sleeves is threadedly connected to each screw B, and each special-shaped screw sleeve They are all slidably connected in a cylindrical mounting shell, there are four connecting rods, the four connecting rods are respectively movably hinged on two special-shaped screw sleeves, and the four connecting rods are symmetrically arranged, the four connecting rods are respectively movably hinged with two grinding rods, and the four connecting rods are symmetrically arranged, the forward and reverse motor is fixedly connected to the bottom of the mounting ring, and the output end of the forward and reverse motor rotates through the mounting ring and extends to the outside of the mounting ring, there are two gears E, one of which is fixedly connected to the output end of the forward and reverse motor, and the other gear E is fixedly connected to one end of one of the screws B, and the two gears E are meshed with each other.

As a preferred solution of the present invention, the conveying mechanism includes a cross bar, a linear slide rail, a U-shaped frame, an electric telescopic rod C, an arc-shaped clamping block and a slide rail slider. The cross bars are provided with four, and each of the cross bars is fixedly connected to the circumferential surface of each guide rod. The linear slide rails are provided with two, and each of the linear slide rails is fixedly connected to the side ends of each two cross bars. The slide rail sliders are provided with two, and each of the slide rail sliders is slidably connected in each linear slide rail. The U-shaped frame is fixedly connected to the top of the two slide rail sliders. The electric telescopic rod C is provided with two, and each of the electric telescopic rod C is fixedly connected to one side end of the U-shaped frame, and each electric telescopic rod C movably passes through the U-shaped frame and extends to the outside of the U-shaped frame. The arc-shaped clamping block is provided with two, and each of the arc-shaped clamping block is fixedly connected to the extended end of each electric telescopic rod C.

A method for preparing a wear-resistant copper lining tile comprises the following steps:

S1. The electric telescopic rod C extends to drive the arc-shaped clamping block to move. The two arc-shaped clamping blocks move at the same time to clamp the wear-resistant copper lining tile, pushing the U-shaped frame to move. The movement of the U-shaped frame drives the slide block to slide in the linear slide rail. The movement of the U-shaped frame drives the two arc-shaped clamping blocks to move. The movement of the two arc-shaped clamping blocks drives the wear-resistant copper lining tile to move. The wear-resistant copper lining tile moves to the upper side of the clamping plate and is placed on the top of multiple clamping claws A.

S2. Turn the handwheel. The handwheel rotation drives the screw A to rotate. The screw A rotation drives the T-type screw sleeve to move. The T-type screw sleeve movement drives the rack to move. The rack movement drives the gear A to rotate. The gear A rotation drives the turntable A to rotate. The turntable A rotation drives the limit rod to slide in the arc hole. The limit rod movement drives the moving plate to move. The moving plate movement drives the T-type slider to slide in the T-type slide groove. The limit rod movement drives the clamping jaw B to move.

S3, the electric telescopic rod A contracts and drives the lifting sleeve to slide on the guide rod, the lifting sleeve descends and drives the limit rod to descend, the limit rod descends and drives the clamping claw B to descend, and the clamping claw B presses the wear-resistant copper lining tile after it descends;

S4. The output end of the forward and reverse motor rotates to drive the gear E to rotate. Since the two gears E are meshed with each other, the two gears E rotate at the same time. The rotation of the gear E drives the screw rod B to rotate. The rotation of the screw rod B drives the transmission shaft to rotate. The rotation of the transmission shaft realizes the simultaneous rotation of the two screw rods B. The rotation of the screw rod B drives the special-shaped screw rod sleeve to move. The two special-shaped screw rod sleeves move close to each other and drive the four connecting rods to move. The simultaneous movement of every two connecting rods can push each grinding rod to move, thereby adjusting the distance between the two grinding rods, so that the grinding rod fits the inner wall of the wear-resistant copper lining tile;

S5, the output end of the driving motor rotates to drive the gear D to rotate, the gear D rotates to drive the gear C to rotate, the gear C rotates to drive the turntable B to rotate, the turntable B rotates to drive the T-shaped swivel on the annular slide rail, the turntable B rotates to drive the three slide bars to make circular motion, the movement of the slide bars drives the mounting ring to rotate, the rotation of the mounting ring drives the cylindrical mounting shell to rotate, the rotation of the cylindrical mounting shell drives the two grinding rods to make circular motion;

S6. The electric telescopic rod B contracts and drives the lifting plate to rise. The lifting plate rises and drives the three slide bars to rise. The rising slide bars drive the mounting ring to rise. The rising mounting ring drives the cylindrical mounting shell to rise. The rising cylindrical mounting shell drives the two grinding rods to rise.

Compared with the prior art, the present invention has the following beneficial effects:

1. In this scheme, the rotation of gear E can be achieved by rotating the output end of the forward and reverse motor. Since the two gears E are meshed with each other, the two gears E can rotate simultaneously. The rotation of gear E can drive the screw rod B to rotate. The rotation of screw rod B can drive the transmission shaft to rotate. The rotation of the transmission shaft can achieve the simultaneous rotation of the two screw rods B. The rotation of screw rod B can drive the movement of the special-shaped screw rod sleeve. The movement of the special-shaped screw rod sleeve can drive the movement of the connecting rod. The movement of the connecting rod can drive the movement of the grinding rod, thereby adjusting the spacing between the two grinding rods, so that the two grinding rods can be adjusted according to the inner diameter of the wear-resistant copper lining tiles of different sizes, thereby grinding the wear-resistant copper lining tiles of different sizes.

2. In this scheme, the top plate is fixedly connected to the top of the four guide rods, so that the stability of the four guide rods can be improved. The lifting sleeve is set on the four guide rods, so that the lifting sleeve can slide on the four guide rods. The lifting of the lifting sleeve can drive multiple clamps B to lift, and the lifting of multiple clamps B can clamp wear-resistant copper lining tiles of different lengths.

3. In this scheme, the handwheel can be rotated to drive the screw rod A to rotate, and the screw rod A can be rotated to drive the T-shaped screw rod sleeve to move, and the movement of the T-shaped screw rod sleeve can drive the rack to move, and the movement of the rack can drive the gear A to rotate, and the rotation of the gear A can drive the turntable A to rotate, and the rotation of the turntable A can push the limit rod to slide in the arc hole, and the rotation of the turntable A can realize the simultaneous movement of multiple limit rods, and the movement of the limit rod can drive the moving plate to move, and the movement of the moving plate can drive the T-shaped slider to slide in the T-shaped slide groove, and the movement of the limit rod can drive the clamping jaw B to move, thereby adjusting the position of the clamping jaw B, and by adjusting the positions of multiple clamping jaws B, multiple clamping jaws B can clamp wear-resistant copper lining tiles of different diameters.

4. In this scheme, the output end of the driving motor can rotate to realize the rotation of gear D, and the rotation of gear C can realize the rotation of gear D, and the rotation of gear C can drive the turntable B to rotate, and the rotation of turntable B can drive the three sliding bars to make circular motion, and the movement of the sliding bar can drive the mounting ring to rotate, and the rotation of the mounting ring can drive the two grinding rods to make circular motion, and the inner wall of the wear-resistant copper lining tile can be polished by the circular motion of the two grinding rods, and the lifting plate can be lifted by contracting the electric telescopic rod B, and the lifting plate can drive the three sliding bars to rise by rising, and the mounting ring can be lifted by rising sliding bars, and the two grinding rods can be lifted by rising mounting ring.

5. In this scheme, the electric telescopic rod C is extended to drive the arc-shaped clamping block to move, and the two arc-shaped clamping blocks move at the same time to clamp the wear-resistant copper lining tile, pushing the U-shaped frame to move, and the movement of the U-shaped frame drives the slide block to slide in the linear slide rail, and the movement of the U-shaped frame drives the two arc-shaped clamping blocks to move, and the movement of the two arc-shaped clamping blocks drives the wear-resistant copper lining tile to move, and the wear-resistant copper lining tile moves to the upper side of the clamping plate and is placed on the top of multiple clamps A.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings are used to provide a further understanding of the present invention and constitute a part of the specification. Together with the embodiments of the present invention, they are used to explain the present invention and do not constitute a limitation of the present invention. In the accompanying drawings:

FIG1 is a schematic diagram of a three-dimensional structure of the present invention;

FIG2 is an enlarged view of point A in FIG1 of the present invention;

Fig. 3 is a cross-sectional view of the present invention;

FIG4 is an enlarged view of point B in FIG3 of the present invention;

FIG5 is a cross-sectional view of the present invention from another perspective;

FIG6 is an enlarged view of point C in FIG5 of the present invention;

FIG7 is a schematic structural diagram of a U-shaped frame of the present invention;

FIG8 is an exploded view of the U-shaped frame of the present invention;

FIG9 is a schematic diagram of the structure of the mounting plate of the present invention;

FIG10 is an exploded view of the turntable A of the present invention;

FIG. 11 is an exploded view of the screw rod B of the present invention.

In the figure: 1, bottom plate; 2, guide rod; 3, electric telescopic rod A; 4, cross bar; 5, support column; 6, clamping plate; 7, clamping claw A; 8, linear slide rail; 9, U-shaped frame; 10, lifting sleeve; 11, top plate; 12, rack; 13, ring slide rail; 14, arc hole; 15, gear A; 16, turntable A; 17, limit rod; 18, T-shaped installation groove; 19, screw rod A; 20, T-shaped screw rod sleeve; 21, hand wheel; 22, moving plate; 23, clamping claw B; 24, wear-resistant copper lining tile; 25, grinding rod; 26, installation Mounting plate; 27. Electric telescopic rod B; 28. Slide rod; 29. Gear C; 30. Gear D; 31. Driving motor; 32. T-shaped swivel; 33. Mounting cylinder; 34. Lifting plate; 35. Turntable B; 36. Mounting ring; 37. Special-shaped screw sleeve; 38. Cylindrical mounting shell; 39. Screw rod B; 40. Transmission shaft; 41. Connecting rod; 42. Forward and reverse motor; 43. Gear E; 44. Electric telescopic rod C; 45. Arc clamping block; 46. Slide rail slider; 47. T-shaped slide groove; 48. T-shaped slider; 49. Slide hole.

DETAILED DESCRIPTION

The following will be combined with the drawings in the embodiments of the present invention to clearly and completely describe the technical solutions in the embodiments of the present invention. Obviously, the described embodiments are only part of the embodiments of the present invention, not all of the embodiments. Based on the embodiments of the present invention, all other embodiments obtained by ordinary technicians in this field without creative work are within the scope of protection of the present invention.

Example 1

Please refer to Figures 1 to 11. The technical solution provided by this embodiment is as follows:

A wear-resistant copper lining tile preparation device and method thereof, which consists of a base plate 1, a clamping mechanism, a wear-resistant copper lining tile 24, a lifting and rotating mechanism, an adjustment mechanism, a grinding rod 25 and a conveying mechanism. The wear-resistant copper lining tile 24 is arranged on the clamping mechanism, and two grinding rods 25 are provided, and the two grinding rods 25 are symmetrically arranged on the adjustment mechanism.

In a specific embodiment of the present invention, the wear-resistant copper lining tile 24 is placed on the top of multiple clamps A7, two grinding rods 25 are respectively hinged to four connecting rods 41, and the two grinding rods 25 are symmetrically arranged between the inner walls of the wear-resistant copper lining tile 24. The inner wall of the wear-resistant copper lining tile 24 can be polished by the arrangement of the grinding rods 25.

Specifically, the supporting component is arranged at the top of the base plate 1, and the supporting component includes a supporting column 5, a clamping plate 6 and a clamping claw A7. The supporting column 5 is fixedly connected to the top of the base plate 1, and the clamping plate 6 is fixedly connected to the top of the supporting column 5. A plurality of clamping claws A7 are arranged, and the plurality of clamping claws A7 are all fixedly connected to the top of the clamping plate 6, and the plurality of clamping claws A7 are evenly distributed.

In a specific embodiment of the present invention, the support column 5 is used to connect the clamping plate 6, and the clamping plate 6 is used to connect the clamping claw A7. The wear-resistant copper lining tile 24 can be clamped by the clamping claw A7 and the clamping claw B23.

Specifically, the lifting component is arranged at the top of the base plate 1, and the lifting component includes a guide rod 2, an electric telescopic rod A3, a lifting sleeve 10, a top plate 11 and a mounting plate 26. Four guide rods 2 are provided, and the four guide rods 2 are fixedly connected to the top of the base plate 1, and the four guide rods 2 are evenly distributed. The top plate 11 is fixedly connected to the top of the four guide rods 2, and the lifting sleeve 10 is slidingly sleeved on the four guide rods 2. Two electric telescopic rods A3 are provided, and one end of each electric telescopic rod A3 is fixedly connected to the top of the base plate 1, and the extended end of each electric telescopic rod A3 is fixedly connected to the lifting sleeve 10, and the mounting plate 26 is fixedly connected to the circumferential inner wall of the lifting sleeve 10.

In a specific embodiment of the present invention, the guide rod 2 is configured to connect the lifting sleeve 10, which is fixedly connected to the top of the four guide rods 2 through the top plate 11, so that the stability of the four guide rods 2 can be improved. The lifting sleeve 10 is slidably sleeved on the four guide rods 2, so that the lifting sleeve 10 can slide on the four guide rods 2. The lifting and lowering of the lifting sleeve 10 can drive the lifting and lowering of multiple clamps B23, and the lifting and lowering of multiple clamps B23 can clamp wear-resistant copper lining tiles 24 of different lengths.

Specifically, there are multiple groups of clamping components, and the multiple groups of clamping components are all arranged on the lifting components. Each group of clamping components includes a limit rod 17, a movable plate 22, a clamping claw B23, a T-shaped slide groove 47 and a sliding hole 49. There are two T-shaped slide grooves 47, and the two T-shaped slide grooves 47 are both opened at the bottom of the mounting plate 26, and the two T-shaped slide grooves 47 are symmetrically arranged. The sliding hole 49 is opened at the bottom of the mounting plate 26, and the sliding hole 49 is located between the two T-shaped slide grooves 47. There are two T-shaped sliders 48, and each T-shaped slider 48 is slidably connected in each T-shaped slide groove 47. The movable plate 22 is fixedly connected to the bottom of the two T-shaped sliders 48. The limit rod 17 is fixedly connected to the bottom of the movable plate 22, and one end of the limit rod 17 movably passes through the movable plate 22 and the sliding hole 49 and extends to the upper side of the mounting plate 26. The clamping claw B23 is fixedly connected to the bottom of the limit rod 17.

In a specific embodiment of the present invention, the sliding hole 49 is set for moving the limit rod 17, the T-shaped slide groove 47 is set for slidingly connecting the T-shaped slider 48, the T-shaped slider 48 is set for connecting the movable plate 22, the movable plate 22 is set for connecting the limit rod 17, the limit rod 17 is set for connecting the clamping claw B23, the movement of the limit rod 17 can drive the movable plate 22 to move, the movement of the movable plate 22 can drive the T-shaped slider 48 to slide in the T-shaped slide groove 47, the movement of the limit rod 17 can drive the clamping claw B23 to move, thereby adjusting the position of the clamping claw B23, and by adjusting the positions of multiple clamping claws B23, multiple clamping claws B23 can clamp wear-resistant copper lining tiles 24 of different diameters.

Specifically, the adjusting component is arranged on the lifting component, and the adjusting component is connected with multiple groups of clamping components. The adjusting component includes a rack 12, an arc hole 14, a gear A15, a turntable A16, a T-shaped mounting groove 18, a screw rod A19, a T-shaped screw rod sleeve 20, a hand wheel 21 and a mounting cylinder 33. The mounting cylinder 33 is fixedly connected to the top of the mounting disk 26, and the turntable A16 is rotatably connected to the circumferential surface of the mounting cylinder 33. A plurality of arc holes 14 are provided, and the plurality of arc holes 14 are all opened on the top of the turntable A16, and the plurality of arc holes 14 are evenly distributed, and each limit rod 17 is movably plugged into each arc hole 1 4, the gear A15 is fixedly connected to the circumferential surface of the turntable A16, the T-shaped mounting groove 18 is opened at the top of the lifting sleeve 10, the screw rod A19 is rotatably connected between the side walls of the T-shaped mounting groove 18, and one end of the screw rod A19 rotates through the lifting sleeve 10 and extends to the outside of the lifting sleeve 10, the hand wheel 21 is fixedly connected to one end of the screw rod A19, the T-shaped screw rod sleeve 20 is threadedly connected to the screw rod A19, and the T-shaped screw rod sleeve 20 is slidably connected in the T-shaped mounting groove 18, the rack 12 is fixedly connected to the top of the T-shaped screw rod sleeve 20, and the rack 12 and the gear A15 are meshed with each other.

In a specific embodiment of the present invention, the rotation of the handwheel 21 can drive the screw rod A19 to rotate, the rotation of the screw rod A19 can drive the T-shaped screw rod sleeve 20 to move, the movement of the T-shaped screw rod sleeve 20 can drive the rack 12 to move, the movement of the rack 12 can drive the gear A15 to rotate, the rotation of the gear A15 can drive the turntable A16 to rotate, the rotation of the turntable A16 can push the limit rod 17 to slide in the arc hole 14, and the rotation of the turntable A16 can realize the simultaneous movement of multiple limit rods 17.

Specifically, the lifting and rotating mechanism is arranged on the clamping mechanism, and the lifting and rotating mechanism includes an annular slide rail 13, an electric telescopic rod B27, a slide bar 28, a gear C29, a gear D30, a driving motor 31, a T-shaped swivel 32, a lifting plate 34, a turntable B35 and a mounting ring 36. The annular slide rail 13 is fixedly connected to the top of the mounting cylinder 33, the T-shaped swivel 32 is rotatably connected in the annular slide rail 13, the turntable B35 is fixedly connected to the top of the T-shaped swivel 32, three slide bars 28 are provided, and the three slide bars 28 are all movably inserted in the top of the turntable B35, and the three slide bars 28 are all movably inserted into the turntable B35 and extend to the outside of the turntable B35, and the mounting ring 36 is fixedly connected to the three slide bars. The bottom of the annular slide rail 13 is fixedly connected to the bottom of the annular slide rail 13, and the lifting plate 34 is fixedly connected to the circumferential surface of the three slide bars 28, and the lifting plate 34 is located between the turntable B35 and the mounting ring 36, one end of the electric telescopic rod B27 is fixedly connected to the top of the turntable B35, and the extended end of the electric telescopic rod B27 movably passes through the turntable B35 and is fixedly connected to the lifting plate 34, the gear C29 is fixedly connected to the circumferential surface of the turntable B35, the driving motor 31 is fixedly connected to the bottom of the annular slide rail 13, and the output end of the driving motor 31 rotates through the annular slide rail 13 and extends to the upper side of the annular slide rail 13, the gear D30 is fixedly connected to the output end of the driving motor 31, and the gear D30 is meshed with the gear C29.

In a specific embodiment of the present invention, the gear D30 can be rotated by rotating the output end of the driving motor 31, and the gear C29 can be rotated by rotating the gear D30. The turntable B35 can be driven to rotate by rotating the gear C29. The three slide bars 28 can be driven to make circular motion by rotating the turntable B35. The installation ring 36 can be driven to rotate by moving the slide bar 28. The two polishing rods 25 can be driven to make circular motion by rotating the installation ring 36. The inner wall of the wear-resistant copper lining tile 24 can be polished by the circular motion of the two polishing rods 25. The lifting plate 34 can be raised by contracting the electric telescopic rod B27. The three slide bars 28 can be driven to rise by rising the lift plate 34. The installation ring 36 can be raised by rising the slide bar 28. The two polishing rods 25 can be raised by rising the installation ring 36.

Specifically, the adjustment mechanism is arranged on the lifting and rotating mechanism, and the adjustment mechanism includes a special-shaped screw sleeve 37, a cylindrical mounting shell 38, a screw B39, a transmission shaft 40, a connecting rod 41, a forward and reverse motor 42 and a gear E43. The cylindrical mounting shell 38 is fixedly connected to the bottom of the mounting ring 36. Two screws B39 are provided. The two screws B39 are respectively rotatably connected to the two ends of the cylindrical mounting shell 38, and the two screws B39 are rotated to penetrate the cylindrical mounting shell 38 and extend to the inner side of the cylindrical mounting shell 38. The transmission shaft 40 is fixedly connected between the two screws B39. Two special-shaped screw sleeves 37 are provided. Each special-shaped screw sleeve 37 is threadedly connected to each screw B39, and each special-shaped The screw sleeves 37 are all slidably connected in the cylindrical mounting shell 38, four connecting rods 41 are provided, and the four connecting rods 41 are respectively movably hinged on the two special-shaped screw sleeves 37, and the four connecting rods 41 are symmetrically arranged, the four connecting rods 41 are respectively movably hinged with the two grinding rods 25, and the four connecting rods 41 are symmetrically arranged, the forward and reverse motors 42 are fixedly connected to the bottom of the mounting ring 36, and the output end of the forward and reverse motors 42 rotates through the mounting ring 36 and extends to the outside of the mounting ring 36, two gears E43 are provided, one of which is fixedly connected to the output end of the forward and reverse motors 42, and the other gear E43 is fixedly connected to one end of one of the screws B39, and the two gears E43 are meshed with each other.

In a specific embodiment of the present invention, the gear E43 can be rotated by rotating the output end of the forward and reverse motor 42. Since the two gears E43 are meshed with each other, the two gears E43 can be rotated simultaneously. The rotation of the gear E43 can drive the screw rod B39 to rotate. The rotation of the screw rod B39 can drive the transmission shaft 40 to rotate. The rotation of the transmission shaft 40 can realize the simultaneous rotation of the two screw rods B39. The rotation of the screw rod B39 can drive the special-shaped screw rod sleeve 37 to move. The movement of the special-shaped screw rod sleeve 37 can drive the connecting rod 41 to move. The movement of the connecting rod 41 can drive the grinding rod 25 to move, thereby adjusting the spacing between the two grinding rods 25, so that the two grinding rods 25 can be adjusted according to the inner diameter of the wear-resistant copper lining tile 24 of different sizes.

Specifically, the conveying mechanism is arranged on the clamping mechanism, and the conveying mechanism includes a cross bar 4, a linear slide rail 8, a U-shaped frame 9, an electric telescopic rod C44, an arc clamping block 45 and a slide rail slider 46. Four cross bars 4 are provided, and each cross bar 4 is fixedly connected to the circumferential surface of each guide rod 2. Two linear slide rails 8 are provided, and each linear slide rail 8 is fixedly connected to the side ends of every two cross bars 4. Two slide rail sliders 46 are provided, and each slide rail slider 46 is slidably connected in each linear slide rail 8. The U-shaped frame 9 is fixedly connected to the top of the two slide rail sliders 46. Two electric telescopic rods C44 are provided, and each electric telescopic rod C44 is fixedly connected to one side end of the U-shaped frame 9, and each electric telescopic rod C44 is movable through the U-shaped frame 9 and extends to the outside of the U-shaped frame 9. Two arc clamping blocks 45 are provided, and each arc clamping block 45 is fixedly connected to the extended end of each electric telescopic rod C44.

In a specific embodiment of the present invention, the cross bar 4 is configured to connect the linear slide rail 8, and the linear slide rail 8 is configured to slidably connect the slide rail slider 46. The slide rail slider 46 is slidably connected to the linear slide rail 8, so that the slide rail slider 46 can slide on the linear slide rail 8. The arc clamp block 45 at the extended end of the electric telescopic rod C44 is fixedly connected, and the electric telescopic rod C44 can be extended to drive the arc clamp block 45 to move. The wear-resistant copper lining tile 24 can be clamped by the movement of the two arc clamp blocks 45, and the wear-resistant copper lining tile 24 can be driven to move by the movement of the U-shaped frame 9.

A method for preparing a wear-resistant copper lining tile comprises the following steps:

S1, the electric telescopic rod C44 extends to drive the arc-shaped clamping block 45 to move, and the two arc-shaped clamping blocks 45 move at the same time to clamp the wear-resistant copper lining tile 24, pushing the U-shaped frame 9 to move, and the movement of the U-shaped frame 9 drives the slide rail slider 46 to slide in the linear slide rail 8, and the movement of the U-shaped frame 9 drives the two arc-shaped clamping blocks 45 to move, and the movement of the two arc-shaped clamping blocks 45 drives the wear-resistant copper lining tile 24 to move, and the wear-resistant copper lining tile 24 moves to the upper side of the clamping plate 6 and is placed on the top of the multiple clamping claws A7;

S2, turn the hand wheel 21, the hand wheel 21 rotates to drive the screw rod A19 to rotate, the screw rod A19 rotates to drive the T-shaped screw rod sleeve 20 to move, the T-shaped screw rod sleeve 20 moves to drive the rack 12 to move, the rack 12 moves to drive the gear A15 to rotate, the gear A15 rotates to drive the turntable A16 to rotate, the turntable A16 rotates to push the limit rod 17 to slide in the arc hole 14, the limit rod 17 moves to drive the moving plate 22 to move, the moving plate 22 moves to drive the T-shaped slider 48 to slide in the T-shaped slide groove 47, the limit rod 17 moves to drive the clamping claw B23 to move;

S3, the electric telescopic rod A3 contracts to drive the lifting sleeve 10 to slide on the guide rod 2, the lifting sleeve 10 descends to drive the limit rod 17 to descend, the limit rod 17 descends to drive the clamping claw B23 to descend, and the clamping claw B23 presses the wear-resistant copper lining tile 24 after descending;

S4, the output end of the forward and reverse motor 42 rotates to drive the gear E43 to rotate. Since the two gears E43 are meshed with each other, the two gears E43 rotate simultaneously. The rotation of the gear E43 drives the screw rod B39 to rotate. The rotation of the screw rod B39 drives the transmission shaft 40 to rotate. The rotation of the transmission shaft 40 realizes the simultaneous rotation of the two screw rods B39. The rotation of the screw rod B39 drives the special-shaped screw rod sleeve 37 to move. The two special-shaped screw rod sleeves 37 move close to each other and drive the four connecting rods 41 to move. The simultaneous movement of every two connecting rods 41 can push each grinding rod 25 to move, thereby adjusting the distance between the two grinding rods 25, so that the grinding rod 25 fits the inner wall of the wear-resistant copper lining tile 24;

S5, the output end of the driving motor 31 rotates to drive the gear D30 to rotate, the gear D30 rotates to drive the gear C29 to rotate, the gear C29 rotates to drive the turntable B35 to rotate, the turntable B35 rotates to drive the T-shaped swivel 32 to rotate on the annular slide rail 13, the turntable B35 rotates to drive the three slide bars 28 to make circular motion, the movement of the slide bar 28 drives the mounting ring 36 to rotate, the rotation of the mounting ring 36 drives the cylindrical mounting shell 38 to rotate, and the rotation of the cylindrical mounting shell 38 drives the two grinding rods 25 to make circular motion;

S6. The electric telescopic rod B27 contracts and drives the lifting plate 34 to rise. The lifting plate 34 rises and drives the three slide bars 28 to rise. The rising slide bars 28 drive the mounting ring 36 to rise. The rising mounting ring 36 drives the cylindrical mounting shell 38 to rise. The rising cylindrical mounting shell 38 drives the two grinding rods 25 to rise.

Finally, it should be noted that the above are only preferred embodiments of the present invention and are not intended to limit the present invention. Although the present invention has been described in detail with reference to the aforementioned embodiments, those skilled in the art can still modify the technical solutions described in the aforementioned embodiments or replace some of the technical features therein by equivalents. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present invention shall be included in the protection scope of the present invention.

Claims (10)

1. The preparation device of the wear-resistant copper supporting tile is characterized by comprising the following components;

A bottom plate (1);

The clamping mechanism is arranged at the top of the bottom plate (1);

A wear-resistant copper backing shoe (24) arranged on the clamping mechanism;

The lifting rotating mechanism is arranged on the clamping mechanism;

The adjusting mechanism is arranged on the lifting rotating mechanism;

The polishing rods (25) are arranged, and the two polishing rods (25) are symmetrically arranged on the adjusting mechanism; and

The conveying mechanism is arranged on the clamping mechanism.

2. The wear resistant copper shoe preparation device of claim 1, wherein the clamping mechanism comprises:

The supporting component is arranged at the top of the bottom plate (1);

The lifting component is arranged at the top of the bottom plate (1);

The clamping parts are provided with a plurality of groups, and the plurality of groups of clamping parts are arranged on the lifting part; and

The adjusting part is arranged on the lifting part and is connected with the plurality of groups of clamping parts.

3. The wear resistant copper shoe preparation device of claim 2, wherein: the supporting component comprises a supporting column (5), clamping plates (6) and clamping jaws A (7), wherein the supporting column (5) is fixedly connected to the top of a bottom plate (1), the clamping plates (6) are fixedly connected to the top of the supporting column (5), the clamping jaws A (7) are provided with a plurality of clamping jaws A (7) which are fixedly connected to the top of the clamping plates (6), and the clamping jaws A (7) are uniformly distributed.

4. A wear resistant copper shoe preparation device according to claim 3, wherein: the lifting part comprises guide rods (2), electric telescopic rods A (3), lifting sliding sleeves (10), top plates (11) and mounting plates (26), wherein the four guide rods (2) are arranged, the four guide rods (2) are fixedly connected to the top of the bottom plate (1), the four guide rods (2) are uniformly distributed, the top plates (11) are fixedly connected to the top of the four guide rods (2), the four guide rods (2) are sleeved with the lifting sliding sleeves (10) in a sliding mode, the two electric telescopic rods A (3) are arranged, one ends of the electric telescopic rods A (3) are fixedly connected to the top of the bottom plate (1), and the extending ends of the electric telescopic rods A (3) are fixedly connected with the lifting sliding sleeves (10), and the mounting plates (26) are fixedly connected to the circumferential inner wall of the lifting sliding sleeves (10).

5. The wear resistant copper shoe preparation device of claim 4, wherein: every group clamping part all includes gag lever post (17), movable plate (22), clamping jaw B (23), T type spout (47) and slide opening (49), T type spout (47) are provided with two, two T type spout (47) all offer in the bottom of mounting disc (26), and two T type spout (47) symmetry settings, slide opening (49) are offered in the bottom of mounting disc (26), and slide opening (49) are located between two T type spouts (47), T type slider (48) are provided with two, every T type slider (48) all sliding connection in every T type spout (47), movable plate (22) fixed connection is in the bottom of two T type sliders (48), gag lever post (17) fixed connection in the bottom of movable plate (22), and the one end activity of gag lever post (17) runs through movable plate (22) and slide opening (49) and extends to the upside of mounting disc (26), B (23) fixed connection is in the bottom of clamping jaw (17).

6. The wear resistant copper shoe preparation device of claim 5, wherein: the adjusting part comprises racks (12), arc holes (14), gears A (15), rotating discs A (16), T-shaped mounting grooves (18), screw rods A (19), T-shaped screw rod sleeves (20), hand wheels (21) and mounting cylinders (33), wherein the mounting cylinders (33) are fixedly connected to the tops of the mounting plates (26), the rotating discs A (16) are rotationally connected to the circumferential surfaces of the mounting cylinders (33), the arc holes (14) are formed in a plurality, the arc holes (14) are formed in the tops of the rotating discs A (16), the arc holes (14) are uniformly distributed, each limiting rod (17) is movably inserted into each arc hole (14), the gears A (15) are fixedly connected to the circumferential surfaces of the rotating discs A (16), the T-shaped mounting grooves (18) are formed in the tops of lifting sliding sleeves (10), one ends of the screw rods A (19) are rotationally connected to the side walls of the T-shaped mounting grooves (18), one ends of the screw rods A (19) penetrate through the lifting sliding sleeves (10) and extend to the outer sides of the screw rods (20) which are fixedly connected to the screw rods (19) which are connected to the screw rods (20) of the screw rods (20), the rack (12) is fixedly connected to the top of the T-shaped screw rod sleeve (20), and the rack (12) is meshed with the gear A (15).

7. The wear resistant copper shoe preparation device of claim 6, wherein: the lifting rotating mechanism comprises an annular sliding rail (13), an electric telescopic rod B (27), sliding rods (28), a gear C (29), a gear D (30), a driving motor (31), a T-shaped rotating ring (32), a lifting disc (34), a rotary disc B (35) and a mounting ring (36), wherein the annular sliding rail (13) is fixedly connected to the top of a mounting cylinder (33), the T-shaped rotating ring (32) is rotationally connected to the annular sliding rail (13), the rotary disc B (35) is fixedly connected to the top of the T-shaped rotating ring (32), the three sliding rods (28) are arranged, the three sliding rods (28) are movably inserted into the top of the rotary disc B (35), the three sliding rods (28) movably penetrate through the rotary disc B (35) and extend to the outer side of the rotary disc B (35), the mounting ring (36) is fixedly connected to the bottom of the three sliding rods (28), the lifting disc (34) is fixedly connected to the circumferential surface of the three sliding rods (28), the lifting disc (34) is positioned between the rotary disc B (35) and the mounting ring (36), the electric sliding rods (27) are movably inserted into the top of the rotary disc B (35) and are fixedly connected to one end of the rotary disc (35) which penetrates through the electric telescopic rod B (27), the gear C (29) is fixedly connected to the circumferential surface of the rotary table B (35), the driving motor (31) is fixedly connected to the bottom of the annular sliding rail (13), the output end of the driving motor (31) rotates to penetrate through the annular sliding rail (13) and extends to the upper side of the annular sliding rail (13), the gear D (30) is fixedly connected to the output end of the driving motor (31), and the gear D (30) is meshed with the gear C (29).

8. The wear resistant copper shoe preparation device of claim 7, wherein: the adjusting mechanism comprises a special-shaped screw rod sleeve (37), a cylindrical mounting shell (38), screw rods B (39), a transmission shaft (40), connecting rods (41), a forward and reverse rotating motor (42) and a gear E (43), wherein the cylindrical mounting shell (38) is fixedly connected to the bottom of a mounting ring (36), the screw rods B (39) are respectively and rotatably connected to the two ends of the cylindrical mounting shell (38), the two screw rods B (39) respectively penetrate through the cylindrical mounting shell (38) in a rotating way and extend to the inner side of the cylindrical mounting shell (38), the transmission shaft (40) is fixedly connected between the two screw rods B (39), the special-shaped screw rod sleeve (37) is provided with two special-shaped screw rod sleeves (37) which are respectively and rotatably connected to the bottom of each screw rod B (39), the connecting rods (41) are respectively and slidably connected to the cylindrical mounting shell (38), the four connecting rods (41) are respectively and movably hinged to the two special-shaped screw rod sleeves (37) and symmetrically arranged on the four connecting rods (41) which are respectively and fixedly connected to the bottom of the four connecting rods (41) and the four connecting rods (41 are respectively and fixedly connected to the two connecting rods (25), and the output end of the forward and backward rotating motor (42) rotates to penetrate through the mounting ring (36) and extends to the outer side of the mounting ring (36), two gears E (43) are arranged, one of the gears E (43) is fixedly connected to the output end of the forward and backward rotating motor (42), the other gear E (43) is fixedly connected to one end of one screw rod B (39), and the two gears E (43) are meshed with each other.

9. The wear resistant copper shoe preparation device of claim 8, wherein: conveying mechanism includes horizontal pole (4), linear slide rail (8), U type frame (9), electric telescopic handle C (44), arc clamp splice (45) and slide rail slider (46), horizontal pole (4) are provided with four, every horizontal pole (4) all fixed connection is on the circumference surface of every guide arm (2), linear slide rail (8) are provided with two, every linear slide rail (8) all fixed connection is in the side of every two horizontal poles (4), slide rail slider (46) are provided with two, every slide rail slider (46) all sliding connection in every linear slide rail (8), U type frame (9) fixed connection is in the top of two slide rail sliders (46), electric telescopic handle C (44) are provided with two, every electric telescopic handle C (44) all fixed connection is in one side of U type frame (9), and every electric telescopic handle C (44) all movably run through U type frame (9) and extend to the side of every two arc clamp splice (45) are provided with in each arc clamp splice (45).

10. A method for preparing wear-resistant copper lining tiles is characterized by comprising the following steps: a wear resistant copper shoe preparation apparatus employing the method of claim 9, comprising the steps of:

S1, an electric telescopic rod C (44) stretches to drive arc-shaped clamping blocks (45) to move, two arc-shaped clamping blocks (45) move simultaneously to clamp wear-resistant copper lining tiles (24), a U-shaped frame (9) is pushed to move, the U-shaped frame (9) moves to drive a sliding rail sliding block (46) to slide in a linear sliding rail (8), the U-shaped frame (9) moves to drive the two arc-shaped clamping blocks (45) to move, the two arc-shaped clamping blocks (45) move to drive the wear-resistant copper lining tiles (24) to move, and the wear-resistant copper lining tiles (24) move to the upper side of a clamping plate (6) and then are placed at the tops of a plurality of clamping jaws A (7);

S2, rotating a hand wheel (21), wherein the hand wheel (21) rotates to drive a screw rod A (19) to rotate, the screw rod A (19) rotates to drive a T-shaped screw rod sleeve (20) to move, the T-shaped screw rod sleeve (20) moves to drive a rack (12) to move, the rack (12) moves to drive a gear A (15) to rotate, the gear A (15) rotates to drive a rotary table A (16) to rotate, the rotary table A (16) rotates to push a limiting rod (17) to slide in an arc-shaped hole (14), the limiting rod (17) moves to drive a moving plate (22) to move, the moving plate (22) moves to drive a T-shaped sliding block (48) to slide in a T-shaped sliding groove (47), and the limiting rod (17) moves to drive a clamping jaw B (23) to move;

S3, the electric telescopic rod A (3) contracts to drive the lifting sliding sleeve (10) to slide on the guide rod (2), the lifting sliding sleeve (10) descends to drive the limiting rod (17) to descend, the limiting rod (17) descends to drive the clamping jaw B (23) to descend, and the clamping jaw B (23) descends to press the wear-resistant copper lining tile (24);

S4, the output end of a forward and backward rotating motor (42) rotates to drive a gear E (43) to rotate, and as the two gears E (43) are meshed with each other, the two gears E (43) rotate simultaneously, the gear E (43) rotates to drive a screw rod B (39) to rotate, the screw rod B (39) rotates to drive a transmission shaft (40) to rotate, the transmission shaft (40) rotates to realize the simultaneous rotation of the two screw rods B (39), the screw rod B (39) rotates to drive a special-shaped screw rod sleeve (37) to move, the two special-shaped screw rod sleeves (37) move close to each other to drive four connecting rods (41) to move, and each two connecting rods (41) can push each polishing rod (25) to move simultaneously, so that the distance between the two polishing rods (25) is adjusted, and the polishing rods (25) are attached to the inner wall of a wear-resistant copper lining tile (24);

S5, the output end of a driving motor (31) rotates to drive a gear D (30) to rotate, the gear D (30) rotates to drive a gear C (29) to rotate, the gear C (29) rotates to drive a rotary table B (35) to rotate, the rotary table B (35) rotates to drive a T-shaped rotary ring (32) to rotate on an annular sliding rail (13), the rotary table B (35) rotates to drive three sliding rods (28) to do circular motion, the sliding rods (28) move to drive a mounting ring (36) to rotate, the mounting ring (36) rotates to drive a cylindrical mounting shell (38) to rotate, and the cylindrical mounting shell (38) rotates to drive two polishing rods (25) to do circular motion;

S6, the electric telescopic rod B (27) contracts to drive the lifting disc (34) to ascend, the lifting disc (34) ascends to drive the three sliding rods (28) to ascend, the sliding rods (28) ascend to drive the mounting ring (36) to ascend, the mounting ring (36) ascends to drive the cylindrical mounting shell (38) to ascend, and the cylindrical mounting shell (38) ascends to drive the two polishing rods (25) to ascend.