CN114643297A

CN114643297A - Zinc wire production process

Info

Publication number: CN114643297A
Application number: CN202210227036.8A
Authority: CN
Inventors: 张勃; 张中力
Original assignee: Shijiazhuang Zhongli Zinc Industry Co ltd
Current assignee: Shijiazhuang Zhongli Zinc Industry Co ltd
Priority date: 2022-03-08
Filing date: 2022-03-08
Publication date: 2022-06-21
Anticipated expiration: 2042-03-08
Also published as: CN114643297B

Abstract

The application relates to a zinc wire production process, which belongs to the technical field of zinc wire production and comprises the following steps: s1, melting the zinc ingot and horizontally casting the zinc ingot into a zinc strip; s2, rolling the zinc strip to form a semi-finished zinc wire; s3, drawing the semi-finished zinc wire to form a finished zinc wire; s4, winding the finished zinc wire through a winding device; the winding device comprises a winding frame, a winding drum horizontally and rotatably connected to the winding frame, a rotating assembly arranged on the winding frame and used for driving the winding drum to rotate, and a lifting assembly arranged on the winding frame and used for driving the winding drum and the rotating assembly to lift; the zinc wire is downwards wound on the winding drum from the upper part of the winding frame. This application has the effect that reduces winding motor life's shortening speed.

Description

Zinc wire production process

Technical Field

The application relates to the technical field of zinc wire production, in particular to a zinc wire production process.

Background

The zinc wire is widely used in the industries of surface zinc spraying and corrosion prevention of steel structures, containers, bridges, headframes, storage tanks, power towers, capacitors, metal supports, nodular cast iron pipes, transportation equipment and the like.

The existing zinc wire production process comprises the following steps: melting a zinc ingot, horizontally casting the zinc ingot into a zinc strip, heating the zinc strip in an annealing furnace, processing the zinc strip into a semi-finished zinc wire by a large wire drawing machine, drawing the zinc wire by a water tank wire drawing machine to produce finished zinc wires with different specifications, and winding the finished zinc wires by a winding device; the winding device comprises a rack, a winding motor fixed on the rack and a winding drum rotationally connected to the rack and fixed with an output shaft of the motor, and zinc wires are wound on the winding drum.

With respect to the related art among the above, the inventors consider that the following drawbacks exist: because the extrusion of the zinc strips is intermittent discharge, and the subsequent steps of the whole process are required to be the same as the discharge speed of the zinc strips, the winding motor needs to be continuously started and closed at intervals in the last zinc wire winding step, so that the service life shortening speed of the winding motor is increased.

Disclosure of Invention

In order to reduce the shortening speed of the service life of a winding motor, the application provides a zinc wire production process.

The zinc wire production process provided by the application adopts the following technical scheme:

a zinc wire production process comprises the following steps:

s1, melting the zinc ingot and horizontally casting the zinc ingot into a zinc strip;

s2, rolling the zinc strip to form a semi-finished zinc wire;

s3, drawing the semi-finished zinc wire to form a finished zinc wire;

s4, winding the finished zinc wire through a winding device; the winding device comprises a winding frame, a winding drum horizontally and rotatably connected to the winding frame, a rotating assembly arranged on the winding frame and used for driving the winding drum to rotate, and a lifting assembly arranged on the winding frame and used for driving the winding drum and the rotating assembly to lift; the zinc wire is downwards wound on the winding drum from the upper part of the winding frame; the power source of the rotating assembly is a winding motor.

By adopting the technical scheme, when the zinc wire is wound, one end of the zinc wire extends downwards from the upper part of the winding frame and then is fixed on the winding drum, the winding drum is driven by the rotating component to wind the zinc wire, meanwhile, the winding drum and the rotating component are driven by the lifting component to ascend simultaneously, the zinc wire during winding can be in a loose state, so that the winding motor can rotate slowly all the time to wind the zinc wire, after the winding drum and the rotating component move to the top end of the winding frame, the winding motor stops rotating, the winding drum and the rotating component are driven by the lifting component to descend slowly, and the zinc wire is in a stretched state, so that the phenomenon that the wound zinc wire loosens and falls off is avoided as much as possible; after the coiling block and the rotating component move to the bottom of the coiling frame, the coiling motor is started again and the lifting component is started, so that the coiling motor can be started or closed for a long time repeatedly, and can not be started or closed at a quick interval for matching with the speed of the zinc wires, and the service life of the coiling motor is greatly shortened.

Optionally, in S4, the rotating assembly includes an installation plate slidably connected to a sidewall of the winding frame, and a rotating shaft rotatably connected to the installation plate and coaxially fixed to the output shaft of the winding motor, the winding motor is fixed to the installation plate, and the rotating shaft and the winding drum are coaxially fixed; the lifting component is used for driving the mounting plate to lift.

Through adopting above-mentioned technical scheme, start the rolling motor and can make the pivot drive the winding drum and rotate, lifting unit only needs to drive the mounting panel and goes up and down, can make winding drum and rotating assembly go up and down together.

Optionally, a dovetail groove is vertically formed in the side wall of the winding frame, and a dovetail block sliding in the dovetail groove is fixed on the mounting plate.

By adopting the technical scheme, when the lifting assembly drives the mounting plate to lift, the dovetail block slides in the dovetail groove, so that the lifting stability of the winding drum and the rotating assembly is improved.

Optionally, the mounting plate and the winding motor are positioned outside the winding frame, and a lifting hole for lifting the rotating shaft is vertically formed in the winding frame; the inner wall that the lift hole is relative is all vertical has seted up the spacing groove, and the coaxial rolling disc that is fixed with on the pivot circumference lateral wall, rolling disc are located two spacing inslots simultaneously.

By adopting the technical scheme, when the winding drum and the rotating assembly are lifted, the rotating disc is lifted in the limiting groove, and when the rotating shaft rotates, the rotating disc rotates in the limiting groove; the arrangement of the rotating disc can limit the rotating shaft, and the lifting stability of the winding shaft and the rotating assembly is improved.

Optionally, the lifting assembly comprises a rack vertically fixed on the side wall of the winding frame, a gear rotatably connected to the mounting plate and meshed with the rack, and a lifting motor fixed on the mounting plate and coaxially fixed with the gear.

Through adopting above-mentioned technical scheme, start elevator motor and make gear revolve, because gear and rack meshing, consequently along with the rotation of gear, the dress board goes up and down, simple structure and simple operation.

Optionally, a shielding plate is fixed at one end of the winding drum close to the mounting plate.

Through adopting above-mentioned technical scheme, can inject the winding position of zinc silk to the back is accomplished in the zinc silk winding, can follow the winding drum and keep away from the one end of shielding plate and take off.

Optionally, a placing block and a plurality of springs are fixed on the side wall of the shielding plate opposite to the winding drum, the springs are respectively located on two opposite sides of the placing block, and the outer ends of all the springs are respectively fixed with a pressing block opposite to the placing block; when the spring is in a natural state, the pressing block is attached to the placing block.

Through adopting above-mentioned technical scheme, outwards draw the briquetting to improve and place the distance between piece and the briquetting, penetrate the one end of zinc silk and place between piece and the briquetting, loosen the briquetting and make it compress tightly the zinc silk and place the piece on, realized that the portable is fixed to the coiling block to the one end of zinc silk.

Optionally, the placing block and the pressing block are provided with arc-shaped placing grooves opposite to the side walls.

By adopting the technical scheme, the zinc wire can be fixed more firmly, and the damage to the zinc wire is reduced.

Optionally, a spacer ring is fixed on the circumferential side wall of the winding drum at a position close to the shielding plate, a space is reserved between the spacer ring and the shielding plate, and a through hole for the zinc wire to pass through is formed in the spacer ring.

Through adopting above-mentioned technical scheme, the isolating ring can be injectd the position that the winding of zinc silk was coiled on the winding drum, and the zinc silk passes earlier and fixes on the shielding plate after perforating, and the space between isolating ring and the shielding plate can not twine the zinc silk, has consequently avoided the zinc silk to shelter from its fixed one end, buries as far as possible, has made things convenient for taking off of zinc silk.

Optionally, a lifting cylinder is fixed on the ground on the inner side of the winding frame, a supporting block is coaxially arranged on the end face, deviating from the mounting plate, of the winding shaft, and a supporting plate used for supporting the supporting block is fixed at the top end of a piston rod of the lifting cylinder.

Through adopting above-mentioned technical scheme, when the winding drum goes up and down, the lift jar goes up and down along with it, makes the fagging always support the bracer, has improved the lift stability of winding drum.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the winding drum is driven by the rotating assembly to wind the zinc wires, the winding drum and the rotating assembly are driven by the lifting assembly to ascend simultaneously, the winding motor can rotate slowly all the time, after the winding drum and the rotating assembly move to the top end of the winding frame, the winding motor stops rotating, the winding drum and the rotating assembly are driven by the lifting assembly to descend slowly, and the shortening speed of the service life of the winding motor is reduced greatly;

2. when the winding drum and the rotating assembly are lifted, the rotating disc is lifted in the limiting groove, and when the rotating shaft rotates, the rotating disc rotates in the limiting groove; the rotating disc can limit the rotating shaft, so that the lifting stability of the winding shaft and the rotating assembly is improved;

3. the position that the isolating ring can twine the winding drum to the zinc silk is injectd, and the zinc silk passes earlier and fixes on the shielding plate after the perforation, and the space between isolating ring and the shielding plate can not twine the zinc silk, has consequently avoided the zinc silk to shelter from its fixed one end as far as possible, buries, has made things convenient for taking off of zinc silk.

Drawings

FIG. 1 is a schematic structural diagram of an embodiment of the present application;

FIG. 2 is a schematic view showing the structure of the shielding plate and the spacer ring;

fig. 3 is a partially enlarged view of a portion a in fig. 2 showing the placement block and the pressing block.

In the figure, 1, a winding frame; 11. a lifting hole; 111. a limiting groove; 12. a dovetail groove; 2. winding the roll; 21. a shielding plate; 22. placing the blocks; 221. a placement groove; 23. pressing into blocks; 24. a spring; 25. an isolating ring; 26. perforating; 27. a support block; 3. a rotating assembly; 31. a winding motor; 32. mounting a plate; 321. a dovetail block; 33. a rotating shaft; 331. rotating the disc; 4. a lifting assembly; 41. a lifting motor; 42. a gear; 43. a rack; 5. a lift cylinder; 51. and a supporting plate.

Detailed Description

The present application is described in further detail below with reference to figures 1-3.

The embodiment of the application discloses a zinc wire production process, which comprises the following steps:

s1, melting the zinc ingot through an electric furnace, and horizontally casting the zinc ingot into a zinc strip;

s2, introducing the zinc strips into a rolling mill through a tractor to be rolled to form semi-finished zinc wires;

s3, drawing the semi-finished zinc wire by a water tank wire drawing machine to form a finished zinc wire;

s4, referring to the figures 1 and 2, winding the finished zinc wire by a winding device; the winding device comprises a winding frame 1 and a winding drum 2 which is horizontally and rotatably connected in the winding frame 1; the winding frame 1 is provided with a rotating component 3 for driving the winding drum 2 to rotate and a lifting component 4 for driving the winding drum 2 and the rotating component 3 to lift; the zinc wire is downwards wound on the winding drum 2 from the upper part of the winding frame 1.

The rotating assembly 3 comprises a mounting plate 32 which is connected to the outer side wall of the winding frame 1 in a sliding mode, a rotating shaft 33 which is coaxially fixed with the winding drum 2 and is connected with the mounting plate 32 in a rotating mode, a winding motor 31 which is fixed on the mounting plate 32 and is coaxially fixed with the rotating shaft 33, a lifting hole 11 for the rotating shaft 33 to lift is vertically formed in the side wall of the winding frame 1, and the lifting assembly 4 is used for driving the mounting plate 32 to lift.

When the zinc wire is wound, the winding motor 31 and the lifting component 4 work simultaneously, so that the winding drum 2 rotates and rises, or the lifting component 4 is started first, then the winding motor 31 is started, and the zinc wire in a loose state is wound; after the winding drum 2 reaches the top of the winding frame 1, the winding motor 31 is closed, the lifting assembly 4 drives the winding drum 2 to move downwards, and the zinc wires are in a stretched state, so that the phenomenon that the wound zinc wires are loosened and fall off is avoided as much as possible; in the whole working process, the winding motor 31 can only slowly rotate at a constant speed for a long time or be closed for a long time, so that the shortening speed of the service life of the winding motor 31 is greatly reduced.

Referring to fig. 1 and 2, two dovetail grooves 12 are vertically formed in the outer side wall of the winding frame 1, the two dovetail grooves 12 are respectively located on two sides of the lifting hole 11, and two dovetail blocks 321 which respectively lift in the two dovetail grooves 12 are fixed on the mounting plate 32; the relative inside wall in lift hole 11 has all vertically seted up spacing groove 111, and coaxial fixed has rolling disc 331 on the pivot 33, and rolling disc 331 is located two spacing inslots 111 simultaneously. When the lifting component 4 drives the winding drum 2 to lift, the mounting plate 32 drives the dovetail block 321 to lift in the dovetail groove 12, and the rotating shaft 33 drives the rotating disc 331 to lift in the limiting groove 111, so that the lifting stability of the winding drum 2 and the rotating component 3 is improved.

Referring to fig. 1 and 2, the lifting assembly 4 includes a lifting motor 41 fixed on the mounting plate 32, two gears 42 rotatably connected to the mounting plate 32 and coaxially fixed with an output shaft of the lifting motor 41, and a rack 43 vertically fixed on an outer side wall of the winding frame 1 and engaged with the corresponding gear 42. After the lifting motor 41 is started to rotate the two gears 42, the mounting plate 32 can be lifted, and the lifting efficiency of the winding drum 2 and the rotating assembly 3 is improved.

Referring to fig. 1 and fig. 2, a lifting cylinder 5 is vertically fixed on the ground in the winding frame 1, the lifting cylinder 5 is located below one side of the winding drum 2 departing from the mounting plate 32, a supporting block 27 coaxially arranged is arranged on the end surface of the winding drum 2 departing from the mounting plate 32, the supporting block 27 and the winding drum 2 can be fixedly connected or rotatably connected, the lifting cylinder 5 can be an air cylinder or a hydraulic cylinder in the embodiment, an arc-shaped supporting plate 51 is fixed at the top end of a piston rod of the lifting cylinder 5, and the supporting plate 51 is used for supporting the supporting block 27. When the winding drum 2 goes up and down, the lifting cylinder 5 stretches along with the winding drum, and can support one end of the winding drum 2 departing from the mounting plate 32, so that the lifting stability of the winding drum 2 is improved.

Referring to fig. 2 and 3, one end of the winding drum 2 close to the mounting plate 32 is coaxially fixed with a shielding plate 21, the shielding plate 21 deviates from the side wall of the mounting plate 32 and is close to the position of the surface of the winding drum 2 to be fixed with a placing block 22 and a plurality of springs 24, the springs 24 are respectively located at the edges of the placing block 22, all the springs 24 are respectively fixed with a same pressing block 23, the pressing block 23 is just arranged on the placing block 22, and the springs 24 are in a natural state, the pressing block 23 is mutually attached to the placing block 22, the pressing block 23 and the surface of the placing block 22 which is mutually attached are all provided with a placing groove 221 which is just arranged and is circular arc-shaped. The end part of the zinc wire can be clamped between the placing block 22 and the pressing hole, so that the zinc wire can be conveniently fixed with zinc wires with different diameters.

Referring to fig. 2 and 3, a spacer ring 25 is coaxially fixed on the circumferential side wall of the winding drum 2, the spacer ring 25 is located at a position close to the shielding plate 21, a distance is reserved between the spacer ring 25 and the shielding plate 21, and a through hole 26 for passing a zinc wire is formed in the spacer ring 25 at a position close to the placing block 22. The tip of zinc silk is earlier fixed between placing piece 22 and briquetting 23 after through perforation 26, makes on the position that the isolating ring 25 that the zinc silk can twine on winding cylinder 2 deviates from shielding plate 21 direction, has avoided as far as possible to place piece 22 after the zinc silk winding and shelters from and cover, has improved the efficiency of taking off the zinc silk from winding cylinder 2.

The specific process of the step is as follows: firstly, one end of a zinc wire is pulled to a through hole 26 from the top of the winding frame 1, penetrates through the through hole 26 and then is clamped between the pressing block 23 and the placing block 22, the lifting motor 41 is started to lift the winding barrel 2, and meanwhile, the winding motor 31 is started to rotate slowly at a constant speed so as to wind the zinc wire of the winding barrel 2; after the winding drum 2 reaches the top of the lifting frame, the winding motor 31 is closed, the lifting motor 41 rotates reversely to enable the winding drum 2 to descend, meanwhile, the zinc wires are stretched to be straight as much as possible, the phenomenon that the wound zinc wires are loosened and fall off is avoided as much as possible, after the winding drum 2 descends to the bottom of the winding frame 1, the lifting motor 41 rotates forwards to enable the winding drum 2 to ascend, the winding motor 31 is started again, and therefore reciprocating is achieved, the winding motor 31 only can rotate slowly at a constant speed for a long time or is closed, and the speed of shortening the service life of the winding motor 31 is greatly reduced.

The embodiments of the present invention are preferred embodiments of the present application, and the scope of protection of the present application is not limited by the embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims

1. A zinc wire production process is characterized in that: the method comprises the following steps:

s2, rolling the zinc strip to form a semi-finished zinc wire;

s3, drawing the semi-finished zinc wire to form a finished zinc wire;

s4, winding the finished zinc wire through a winding device; the winding device comprises a winding frame (1), a winding drum (2) horizontally and rotatably connected to the winding frame (1), a rotating assembly (3) arranged on the winding frame (1) and used for driving the winding drum (2) to rotate, and a lifting assembly (4) arranged on the winding frame (1) and used for driving the winding drum (2) and the rotating assembly (3) to lift; the zinc wire is downwards wound on the winding drum (2) from the upper part of the winding frame (1); the power source of the rotating component (3) is a winding motor (31).

2. The process for producing zinc wire according to claim 1, wherein: in S4, the rotating assembly (3) comprises an installation plate (32) connected to the side wall of the winding frame (1) in a sliding mode and a rotating shaft (33) connected to the installation plate (32) in a rotating mode and coaxially fixed with an output shaft of the winding motor (31), the winding motor (31) is fixed on the installation plate (32), and the rotating shaft (33) and the winding drum (2) are coaxially fixed; the lifting component (4) is used for driving the mounting plate (32) to lift.

3. The zinc wire production process according to claim 2, characterized in that: the side wall of the winding frame (1) is vertically provided with a dovetail groove (12), and a dovetail block (321) which slides in the dovetail groove (12) is fixed on the mounting plate (32).

4. The process for producing zinc wire according to claim 2, wherein: the mounting plate (32) and the winding motor (31) are positioned on the outer side of the winding frame (1), and a lifting hole (11) for the rotating shaft (33) to lift up and down is vertically formed in the winding frame (1); limiting grooves (111) are vertically formed in the opposite inner walls of the lifting holes (11), a rotating disc (331) is coaxially fixed on the circumferential side wall of the rotating shaft (33), and the rotating disc (331) is located in the two limiting grooves (111) simultaneously.

5. The process for producing zinc wire according to claim 3 or 4, wherein: the lifting assembly (4) comprises a rack (43) vertically fixed on the side wall of the winding frame (1), a gear (42) rotatably connected to the mounting plate (32) and meshed with the rack (43), and a lifting motor (41) fixed on the mounting plate (32) and coaxially fixed with the gear (42).

6. The process for producing zinc wire according to claim 2, wherein: a shielding plate (21) is fixed at one end of the winding drum (2) close to the mounting plate (32).

7. The process for producing a zinc wire according to claim 6, wherein: a placing block (22) and a plurality of springs (24) are fixed on the side wall of the shielding plate (21) opposite to the winding drum (2), the springs (24) are respectively positioned on two opposite sides of the placing block (22), and the outer ends of all the springs (24) are respectively fixed with a same pressing block (23) opposite to the placing block (22); when the spring (24) is in a natural state, the pressing block (23) is attached to the placing block (22).

8. The process for producing zinc wire according to claim 7, wherein: arc-shaped placing grooves (221) are formed in the side walls, which are opposite to the placing blocks (22) and the pressing blocks (23).

9. The zinc wire production process according to claim 7, wherein: a spacer ring (25) is fixed on the circumferential side wall of the winding drum (2) at a position close to the shielding plate (21), a space is reserved between the spacer ring (25) and the shielding plate (21), and a through hole (26) for a zinc wire to pass through is formed in the spacer ring (25).

10. The process for producing zinc wire according to claim 2, wherein: the inboard subaerial lifting cylinder (5) that is fixed with of rolling frame (1), the terminal surface that the rolling axle deviates from mounting panel (32) is coaxial to be equipped with bracer (27), and the top of lifting cylinder (5) piston rod is fixed with fagging (51) that are used for supporting bracer (27).