CN114000183A - Diamond wire magnetic suspension sanding assembly and electroplating sanding method - Google Patents

Abstract

The invention belongs to the technical field of diamond wire production, and particularly relates to a diamond wire magnetic suspension sanding assembly and an electroplating sanding method. The diamond wire magnetic suspension sanding component comprises a liquid storage pipe, a magnet bearing cylinder, a plurality of magnets and a rotary driving mechanism. According to the invention, the magnet bearing cylinder is driven to rotate around the liquid storage pipe by the rotation driving mechanism, a plurality of magnets which attract each other in pairs are arranged on the magnet bearing cylinder, and when the magnet bearing cylinder carries the magnets which attract each other in pairs to rotate, a circular magnetic field can be formed between the attracted magnets; the magnetic diamond particles are gathered by the center of the liquid storage pipe in a spiral state under the action of a magnetic field; when the steel wire passes through the center of the liquid storage pipe, the magnetic diamond particles can be quickly and uniformly embedded on the steel wire through the conduction of the negative steel wire and the positive nickel-ion-containing electroplating solution.

Description

Diamond wire magnetic suspension sanding assembly and electroplating sanding method

Technical Field

The invention belongs to the technical field of diamond wire production, and particularly relates to a diamond wire magnetic suspension sanding assembly and a manufacturing method thereof.

Background

The diamond wire is called diamond cutting wire or diamond wire for short, and is made by inlaying diamond particles on a cutting steel wire. Therefore, the diamond wire has diamond micro saw teeth, the cutting capability of the steel wire is improved, and the cutting speed and the cutting capability can be greatly accelerated.

Diamond particles are embedded on a steel wire, and the key step is electroplating and sanding. The traditional sand electroplating method comprises a sand burying method, a sand shakeout method, a magnetic suspension method and the like. The magnetic suspension method is a technique for suspending diamond particles by overcoming gravity through magnetic force, but the method does not have proper structural hardware as a support, and the problems of non-uniform agglomeration and diamond inlaying of electroplated diamond particles, unstable diamond wire cutting rate and the like often occur.

Therefore, structural components that cooperate to implement the magnetic levitation method are also to be designed. Therefore, the technical scheme of researching the magnetic suspension sanding component and the manufacturing method thereof, which can reduce the agglomeration and the non-uniform embedding of the diamond particles and improve the exposure rate, is of great significance.

Disclosure of Invention

In order to solve the technical problems, the invention aims to provide a magnetic suspension sanding assembly for diamond wires, which can quickly and uniformly inlay diamond particles on steel wires.

In order to achieve the technical purpose, the invention adopts the following technical scheme:

diamond wire magnetic suspension sanding assembly, including:

the liquid storage pipe is used for containing nickel-ion-containing electroplating liquid and magnetic diamond particles;

the magnet bearing cylinder is sleeved on the periphery of the liquid storage pipe and can rotate relative to the liquid storage pipe; the wall of the magnet bearing cylinder is provided with a plurality of groups of magnet mounting holes which are arranged oppositely;

the magnets are correspondingly arranged in each group of magnet mounting holes in pairs respectively, and the adjacent magnetic poles of each pair of magnets are opposite in magnetism;

and the rotary driving mechanism drives the magnet bearing cylinder to rotate around the liquid storage pipe.

As the preferred technical scheme, the periphery of the magnet bearing cylinder is fixedly sleeved with a magnet protective sleeve.

According to a preferable technical scheme, the rotary driving mechanism comprises a driving motor, a driving wheel is installed at the output end of the driving motor, a driving wheel is fixedly connected to the lower end of the magnet bearing cylinder, and the driving wheel is in transmission connection with the driving wheel.

As the preferred technical scheme, the upper end of the liquid storage pipe is provided with an upper fixing seat, and the lower end of the liquid storage pipe is provided with a lower fixing seat.

As a preferred technical scheme, an upper bearing is installed on the upper fixing seat, and the upper end of the magnet bearing cylinder is tightly matched with the upper bearing; the lower fixing seat is provided with a lower bearing, the driving wheel is tightly matched with the lower bearing, and the driving wheel is fixedly connected with the magnet bearing barrel through a positioning pin.

As the preferred technical scheme, a positioning flange is installed at the upper end of the magnet bearing cylinder, and a positioning groove is formed in the driving wheel.

According to the preferable technical scheme, four magnet mounting areas are uniformly machined on the outer wall of the magnet bearing cylinder along the circumferential direction, the magnet mounting holes are uniformly machined on each magnet mounting area along the axial direction, and locking holes are respectively machined in the magnet mounting areas corresponding to the magnet mounting holes.

As a preferable technical scheme, the manufacturing method of the magnet bearing cylinder comprises the following steps:

clamping one end of a magnet installation cylinder on a machine tool indexing head clamp, positioning the other end of the magnet installation cylinder on a machine tool locking thimble, and setting a machining size through the machine tool;

step two, processing magnet mounting holes, side planes and locking holes of the first magnet mounting area to ensure that all the magnet mounting holes of the first magnet mounting area have the same diameter and size and are uniformly distributed at the same positions, the distances among the magnet mounting holes are the same, and the depths of all the magnet mounting holes are the same;

step three, after the magnet mounting hole, the side plane and the locking hole of the first magnet mounting area are machined, loosening a machine tool locking thimble, enabling the dividing head clamp to drive the magnet mounting cylinder to rotate 90 degrees, and then machining the magnet mounting hole, the side plane and the locking hole of the second magnet mounting area; and by analogy, processing the magnet mounting holes, the side planes and the locking holes of the third magnet mounting area and the fourth magnet mounting area by the same method, and ensuring that the four magnet mounting areas are uniformly distributed along the circumferential direction.

The invention also provides an electroplating sanding method using the diamond wire magnetic suspension sanding component, which comprises the following steps:

s1, containing nickel-ion-containing electroplating solution and magnetic diamond particles in a liquid storage tube;

s2, taking the steel wire as a negative electrode and taking the nickel-ion-containing electroplating solution as a positive electrode;

s3, driving the magnet bearing cylinder to rotate around the liquid storage pipe through the rotation driving mechanism, wherein the magnet bearing cylinder carries the magnet to rotate, and when the magnet rotates, the attracted ferromagnetism can form a circular magnetic field; the magnetic diamond particles are gathered by the center of the liquid storage pipe in a spiral state under the action of a magnetic field;

and S4, when the steel wire penetrates through the center of the liquid storage pipe, the steel wire is conducted through the negative steel wire and the positive nickel-ion-containing electroplating solution, and the magnetic diamond particles are quickly and uniformly embedded on the steel wire.

Due to the adoption of the technical scheme, the invention has at least the following beneficial effects:

(1) the magnet bearing cylinder is driven to rotate around the liquid storage pipe through the rotation driving mechanism, a plurality of magnets which attract each other in pairs are installed on the magnet bearing cylinder, and when the magnet bearing cylinder carries the magnets which attract each other in pairs to rotate, a circular magnetic field can be formed between the attracted magnets; the magnetic diamond particles are gathered by the center of the liquid storage pipe in a spiral state under the action of a magnetic field; when the steel wire passes through the center of the liquid storage pipe, the magnetic diamond particles can be quickly and uniformly embedded on the steel wire through the conduction of the negative steel wire and the positive nickel-ion-containing electroplating solution.

(2) The more the magnet layers are attracted in pairs, the longer the cylinder of the magnetic field is; the faster the magnet rotation speed, the denser the spiral layers of the magnetic diamond particles, and the rotating attracting magnet can control the concentration and spiral state of the magnetic diamond particles. Therefore, the assembly can effectively control the problems of agglomeration of electroplated diamond particles, uneven diamond inlaying and the like.

Drawings

The drawings are only for purposes of illustrating and explaining the present invention and are not to be construed as limiting the scope of the present invention. Wherein:

FIG. 1 is a schematic perspective view of an embodiment of the present invention;

FIG. 2 is a schematic cross-sectional view of an embodiment of the present invention;

FIG. 3 is a schematic view of the mounting of a magnet in an embodiment of the invention;

FIG. 4 is a schematic view of a magnet carrier cartridge in accordance with an embodiment of the present invention;

FIG. 5 is a schematic diagram of a sanding state during electroplating sanding according to an embodiment of the present invention.

Detailed Description

The invention is further illustrated below with reference to the figures and examples. In the following detailed description, certain exemplary embodiments of the present invention are described by way of illustration only. Needless to say, a person skilled in the art realizes that the described embodiments can be modified in various different ways without departing from the spirit and scope of the present invention. Accordingly, the drawings and description are illustrative in nature and not intended to limit the scope of the claims.

As shown in fig. 1 to 5, the diamond wire magnetic suspension sanding assembly includes a liquid storage tube 1, a magnet carrying cylinder 5, a plurality of magnets 14 and a rotary driving mechanism, wherein: the liquid storage pipe 1 is used for containing nickel-ion-containing electroplating liquid 16 and magnetic diamond particles 17;

the magnet bearing cylinder 5 is sleeved on the periphery of the liquid storage pipe 1, and the magnet bearing cylinder 5 can rotate around the liquid storage pipe 1 under the driving action of the rotary driving mechanism; the wall of the magnet bearing cylinder 5 is provided with a plurality of groups of magnet mounting holes 51 which are arranged oppositely; in this embodiment, an upper fixed seat 2 is installed at the upper end of the liquid storage pipe 1, a lower fixed seat 9 is installed at the lower end of the liquid storage pipe 1, the upper fixed seat 2 is an upper reference, the lower fixed seat 9 is a lower reference, and the upper reference and the lower reference position the vertical position of the sanding component; an upper bearing 3 is arranged on the upper fixed seat 2, and the upper end of the magnet bearing cylinder 5 is tightly matched with the upper bearing 3; the lower fixing seat 2 is provided with a lower bearing 8, and the middle part assembly can freely rotate through the upper bearing and the lower bearing.

Referring to fig. 2, the magnets 14 are respectively installed in pairs in the magnet installation holes 51, and the adjacent magnetic poles of each pair of magnets 14 are opposite in magnetism; the magnets 14 are uniformly distributed along the circumference in the radial direction and are linearly distributed in multiple layers in the axial direction, and the N poles and the S poles of the magnets are respectively arranged on two sides of the magnet bearing cylinder 5 to form a mutually attractive state. The purpose of this structure is to concentrate the magnetic diamond particles in the reservoir 1 to the center of the reservoir. When the magnetic diamond particles and the nickel ion-containing plating solution flow to the liquid storage tube 1, the concentration and the spiral state of the magnetic diamond particles can be controlled by the rotating attracting magnet, and therefore, the plating of the diamond wire can be performed rapidly and uniformly.

In this embodiment, the rotation driving mechanism includes a driving motor 13, a driving wheel 12 is installed at an output end of the driving motor 13, a driving wheel 7 is fixedly connected to a lower end of the magnet bearing cylinder 5, the driving wheel 7 is closely matched with the lower bearing 8, the driving wheel 7 is coaxially and closely matched with the magnet bearing cylinder 5 and is fixedly connected through a positioning pin 10, so as to prevent the two from rotating relatively; the driving wheel 12 and the transmission wheel 7 are preferably belt wheels, the transmission wheel 7 is in transmission connection with the driving wheel 12 through a toothed belt 11, and the transmission precision of the structure is high. The driving wheel 12 is driven to rotate by the driving motor 13, the driving wheel 7 is pulled to rotate through the toothed belt 11, and the driving wheel 7 drives the magnet bearing cylinder 5 to rotate. Of course, other common driving mechanisms may be adopted to realize the rotation driving of the magnet carrying cylinder 5, and all of them should fall into the protection scope of the present invention.

In this embodiment, the upper end of the magnet bearing cylinder 5 is provided with a positioning flange 4, and the driving wheel 7 is provided with a positioning groove. The fixed cover in periphery of magnet bearing cylinder 5 is equipped with magnet protective sheath 6, and the coaxial cooperation equipment of magnet protective sheath 6 lower extreme and drive wheel 7, the upper end and the coaxial cooperation equipment of positioning flange 4 of magnet protective sheath 6. This structure makes it possible to make the magnet protecting sleeve 6 coaxial with the magnet bearing cylinder 5 without swinging.

In this embodiment, the liquid storage tube 1, the upper fixing seat 2, the positioning flange 4, the magnet bearing cylinder 5, the magnet protecting sleeve 6, the driving wheel 7, the lower fixing seat 9, the toothed belt 11 and the driving wheel 12 are all made of insulating, acid and alkali resistant materials.

Referring to fig. 4, four magnet mounting areas are uniformly processed on the outer wall of the magnet bearing cylinder 5 along the circumferential direction, each magnet mounting area is uniformly processed with the magnet mounting holes 51 along the axial direction, the magnet mounting areas are located on the side portions of the magnet mounting holes and are respectively processed with side planes 52, and the side planes 52 are correspondingly provided with locking holes 53 respectively processed with the magnet mounting holes 51 for installing locking screws to lock the magnets and prevent the magnets from being separated in the rotating process.

The specific manufacturing method of the magnet bearing cylinder comprises the following steps:

step one, clamping one end of a magnet mounting cylinder 5 on a machine tool indexing head fixture, positioning the other end of the magnet mounting cylinder on a machine tool locking thimble, and setting a machining size through the machine tool;

step two, processing magnet mounting holes, side planes and locking holes of the first magnet mounting area to ensure that all the magnet mounting holes of the first magnet mounting area have the same diameter and size and are uniformly distributed at the same positions, the distances among the magnet mounting holes are the same, and the depths of all the magnet mounting holes are the same;

step three, after the magnet mounting hole, the side plane and the locking hole of the first magnet mounting area are machined, loosening a machine tool locking thimble, enabling the dividing head clamp to drive the magnet mounting cylinder to rotate 90 degrees, and then machining the magnet mounting hole, the side plane and the locking hole of the second magnet mounting area; and by analogy, processing the magnet mounting holes, the side planes and the locking holes of the third magnet mounting area and the fourth magnet mounting area by the same method, and ensuring that the four magnet mounting areas are uniformly distributed along the circumferential direction. This mode of manufacture makes the mounted position equipartition of magnet, and magnet installation degree of depth is the same moreover, can guarantee that when magnet is rotatory, and magnetism diamond particle concentrates to the liquid storage pipe center, and stable be the heliciform. The structure has high manufacturing precision, low manufacturing cost and simplicity. Therefore, the structure can effectively solve the problems of agglomeration of electroplated diamond particles, uneven diamond inlaying and the like by ensuring the precision of the magnet installation position, thereby improving the edge emergence rate of the diamond wire.

Referring to fig. 3, the method and rules for mounting the magnet 14 to the magnet carrier 5 are mainly described. The magnets 14 are symmetrically mounted, and in the first layer, the N pole of one magnet 14 faces one surface of the magnet bearing cylinder 5, and the S pole of the other magnet 14 faces the other surface of the magnet bearing cylinder 5, so as to form symmetry and attraction. And the second layer, the mounting position is rotated by 90 degrees, the N pole of one magnet 14 faces one surface of the magnet bearing cylinder 5, and the S pole of the other magnet 14 faces the other surface of the magnet bearing cylinder 5, so as to form symmetry and attraction. And so on, other layers are installed in the same way. When the magnet rotates, the magnet forms a circular magnetic field and a spiral shape, and the more the layers of the magnet are, the longer the cylindrical shape of the magnetic field is; the faster the magnet rotates, the denser the spiral layers of magnetic diamond. Therefore, the assembly can effectively control the problems of agglomeration of electroplated diamond particles, uneven diamond inlaying and the like.

Referring to fig. 5, the invention also provides an electroplating sanding method using the diamond wire magnetic suspension sanding assembly, which comprises the following steps:

s1, the liquid storage pipe 1 is filled with nickel-ion-containing electroplating solution 16 and magnetic diamond particles 17;

s2, using the steel wire 15 as a negative electrode and the nickel-ion-containing electroplating solution 16 as a positive electrode;

s3, the magnet bearing cylinder 5 is driven to rotate around the liquid storage pipe 1 through the rotation driving mechanism, the magnet bearing cylinder 5 carries the magnet 14 to rotate, and when the magnet rotates, the attracted ferromagnetism can form a circular magnetic field; the magnetic diamond particles 17 are spirally gathered by the center of the liquid storage pipe 1 under the action of a magnetic field;

and S4, when the steel wire 15 passes through the center of the liquid storage pipe 1, the steel wire 15 can be quickly and uniformly embedded with the magnetic diamond particles 17 through the conduction of the negative steel wire and the positive nickel-ion-containing electroplating solution.

The above description is only an exemplary embodiment of the present invention, and is not intended to limit the scope of the present invention. Any equivalent changes and modifications that can be made by one skilled in the art without departing from the spirit and principles of the invention shall fall within the protection scope of the invention.

Claims (9)

1. Sand subassembly in diamond wire magnetic suspension, its characterized in that includes:

the liquid storage pipe is used for containing nickel-ion-containing electroplating liquid and magnetic diamond particles;

the magnet bearing cylinder is sleeved on the periphery of the liquid storage pipe and can rotate relative to the liquid storage pipe; the wall of the magnet bearing cylinder is provided with a plurality of groups of magnet mounting holes which are arranged oppositely;

the magnets are correspondingly arranged in each group of magnet mounting holes in pairs respectively, and the adjacent magnetic poles of each pair of magnets are opposite in magnetism;

and the rotary driving mechanism drives the magnet bearing cylinder to rotate around the liquid storage pipe.

2. A diamond wire magnetic levitation sanding assembly as defined in claim 1, wherein: the periphery of the magnet bearing cylinder is fixedly sleeved with a magnet protective sleeve.

3. A diamond wire magnetic levitation sanding assembly as defined in claim 2, wherein: the rotary driving mechanism comprises a driving motor, a driving wheel is installed at the output end of the driving motor, a driving wheel is fixedly connected to the lower end of the magnet bearing cylinder, and the driving wheel is in transmission connection with the driving wheel.

4. A diamond wire magnetic levitation sanding assembly as defined in claim 3, wherein: the upper end of the liquid storage pipe is provided with an upper fixing seat, and the lower end of the liquid storage pipe is provided with a lower fixing seat.

5. The diamond-wire magnetic levitation sanding assembly of claim 4, wherein: the upper fixing seat is provided with an upper bearing, and the upper end of the magnet bearing cylinder is tightly matched with the upper bearing; the lower fixing seat is provided with a lower bearing, the driving wheel is tightly matched with the lower bearing, and the driving wheel is fixedly connected with the magnet bearing barrel through a positioning pin.

6. A diamond wire magnetic suspension sanding assembly according to claim 5, wherein: and a positioning flange is arranged at the upper end of the magnet bearing cylinder, and a positioning groove is formed in the driving wheel.

7. A diamond wire magnetic levitation sanding assembly as defined in claim 1, wherein: four magnet installing areas are formed on the outer wall of the magnet bearing cylinder in a circumferential and uniform processing mode, each magnet installing area is provided with magnet installing holes in an axial and uniform processing mode, and locking holes are formed in the magnet installing holes corresponding to the magnet installing holes respectively in the magnet installing areas.

8. A diamond wire magnetic suspension sanding assembly according to claim 7, wherein the magnet carrying cylinder is manufactured by the following method:

clamping one end of a magnet installation cylinder on a machine tool indexing head clamp, positioning the other end of the magnet installation cylinder on a machine tool locking thimble, and setting a machining size through the machine tool;

step two, processing magnet mounting holes, side planes and locking holes of the first magnet mounting area to ensure that all the magnet mounting holes of the first magnet mounting area have the same diameter and size and are uniformly distributed at the same positions, the distances among the magnet mounting holes are the same, and the depths of all the magnet mounting holes are the same;

step three, after the magnet mounting hole, the side plane and the locking hole of the first magnet mounting area are machined, loosening a machine tool locking thimble, enabling the dividing head clamp to drive the magnet mounting cylinder to rotate 90 degrees, and then machining the magnet mounting hole, the side plane and the locking hole of the second magnet mounting area; and by analogy, processing the magnet mounting holes, the side planes and the locking holes of the third magnet mounting area and the fourth magnet mounting area by the same method, and ensuring that the four magnet mounting areas are uniformly distributed along the circumferential direction.

9. The electroplating sanding method using the diamond wire magnetic suspension sanding assembly according to any one of claims 1 to 8, characterized by comprising the following steps:

s1, containing nickel-ion-containing electroplating solution and magnetic diamond particles in a liquid storage tube;

s2, taking the steel wire as a negative electrode and taking the nickel-ion-containing electroplating solution as a positive electrode;

s3, driving the magnet bearing cylinder to rotate, wherein the magnet bearing cylinder carries the magnet to rotate, and when the magnet rotates, the attracted ferromagnetism can form a circular magnetic field; the magnetic diamond particles are gathered by the center of the liquid storage pipe in a spiral state under the action of a magnetic field;

and S4, when the steel wire penetrates through the center of the liquid storage pipe, the steel wire is conducted through the negative steel wire and the positive nickel-ion-containing electroplating solution, and the magnetic diamond particles are quickly and uniformly embedded on the steel wire.

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