CN221117561U - Novel equipment structure of hot dip coating alloy - Google Patents

Abstract

The utility model relates to the technical field of hot dip plating, and provides a novel hot dip plating alloy equipment structure which comprises a material taking table, wherein a material taking claw is arranged on the material taking table in a lifting and transverse moving manner, a rotary lifting member is arranged on the material taking table in a lifting and rotating manner, the rotary lifting member is provided with at least one material discharging part, the rotary lifting member is positioned on one side below the material taking claw, a rotary material receiving member is rotatably arranged on the material taking table and is positioned on one side of the rotary lifting member, the rotary material receiving member is provided with at least one material receiving part, the rotary material receiving member is positioned on the other side below the material taking claw, and the rotary material receiving member is further provided with a material poking part above the material receiving part. By the technical scheme, the technical problem of uneven hot plating between hot-dip materials or at the joint of the hot-dip materials and the clamping device in the hot-dip process in the prior art is solved.

Description

Novel equipment structure of hot dip coating alloy

Technical Field

The utility model relates to the technical field of hot dip coating, in particular to a novel equipment structure for hot dip coating alloy.

Background

The hot dip plating method is a method of immersing a metal in a molten corrosion-resistant molten metal for a short period of time, taking out and cooling the molten metal, and forming a coating on the surface of the metal. The hot dip coating can prevent the corrosion of atmospheric air and water, does not generate toxic salt, has firm combination between the hot dip coating and the metal surface, and has simple operation, high productivity and wide application.

Disclosure of utility model

The utility model provides a novel equipment structure for hot dip coating alloy, which solves the technical problem of uneven hot dip coating between hot dip coating materials or at the joint of the hot dip coating materials and a clamping device in the related technology.

The technical scheme of the utility model is as follows:

an equipment structure for hot dip coating alloy comprises

A material taking table is arranged on the material taking table,

The material taking claw is arranged on the material taking table in a lifting and moving manner and in a transverse moving manner,

The rotary lifting piece is lifted and moved and rotatably arranged on the material taking table, the rotary lifting piece is provided with at least one material discharging part, the rotary lifting piece is positioned at one side below the material taking claw,

The rotary material receiving piece is rotatably arranged on the material taking table and is positioned on one side of the rotary lifting piece, the rotary material receiving piece is provided with at least one material receiving portion, the rotary material receiving piece is positioned on the other side below the material taking claw, and the rotary material receiving piece is further provided with a material stirring portion above the material receiving portion.

As a further technical scheme, one side of the discharging part is a discharging inlet, the other side of the discharging part is a discharging baffle, and the discharging parts are at least two arranged up and down in sequence.

As a further technical scheme, one side of the material receiving part is a material receiving inlet, the other side of the material receiving part is a material receiving baffle part, and the material receiving parts are at least two of which are arranged up and down in sequence.

As a further technical scheme, the material taking claws are at least two and distributed on two sides of the rotary material receiving piece, the rotary lifting piece is located at the edge of the material taking table, and the rotary lifting piece penetrates through the material taking table.

As a further technical scheme, two rotary receiving pieces are arranged on the material taking table symmetrically and are positioned between the two rotary lifting pieces, the rotary receiving pieces are positioned beside the edge of the material taking table, and the rotary receiving pieces penetrate through the material taking table.

As a further technical scheme, the two material taking claws are in one group and are provided with a plurality of groups.

As a further technical solution, the material taking table has:

The device comprises two yielding notches, wherein the yielding notches are sequentially arranged on the material taking table, the material taking claw stretches into the yielding notches, the material taking claw passes through the yielding notches when moving up and down, the rotary material receiving piece is arranged between the two yielding notches, and the rotary lifting piece is arranged at two sides of the two yielding notches respectively.

As a further technical scheme, the method further comprises:

A first linear driving member for driving the material taking claw to vertically move,

The movable connecting piece is transversely arranged on the material taking table in a movable way, the first linear driving piece is arranged on the movable connecting piece,

The second linear driving piece is arranged on the material taking table and drives the movable connecting piece to move transversely.

As a further technical scheme, the method further comprises:

A third linear drive disposed on the take out table,

A first rack, which is arranged at the output end of the third linear driving piece,

The first gear is arranged on the material taking table, the first gear is meshed with the first rack, the rotary lifting piece is arranged on the first gear in a penetrating way, the first gear drives the rotary lifting piece to rotate,

And the rotary lifting piece is rotatably arranged at the output end of the fourth linear driving piece.

As a further technical scheme, the method further comprises:

A fifth linear drive disposed on the take out station,

The output end of the fifth linear driving piece is connected with the second rack,

The first gear is arranged on the material taking table, the second gear is meshed with the second rack, the first gear drives the rotary material receiving piece, and the top of the rotary material receiving piece is connected with the bottom of the second gear.

The working principle and the beneficial effects of the utility model are as follows:

The utility model provides a novel hot dip coating alloy equipment structure which comprises a material taking table, material taking claws, a rotary lifting piece and a rotary material receiving piece. The material taking claw is arranged on the material taking table, can move up and down and transversely, transversely moves to the chain conveying line to take materials, and transversely moves to the position above the alloy plating pool after taking the materials; the material taking claw moves to the upper part of the alloy plating pool and then descends to the bottom of the alloy plating pool, the rotary lifting piece is lifted in place, and the material taking claw transversely moves to the lower part of the rotary lifting piece; after the rotary lifting piece descends to the position that the discharging part of the rotary lifting piece is lower than the material taking claw, the rotary lifting piece rotates to the material receiving position, the material taking claw loosens and ascends to move, and the material falls onto the discharging part of the rotary lifting piece; when the material reaches the discharging part and is singly received for a set time, the rotary lifting part is lifted, and when the rotary lifting part is lifted to a material receiving part of which the top surface is higher than or equal to that of the rotary material receiving claw, the rotary material receiving part rotates firstly, after the rotary material receiving part is in place, the rotary lifting part rotates, and the material is placed on the material receiving part of the rotary material receiving claw; the rotary lifting piece is lifted or lowered to enable the top surface of one discharging part to be lower than or equal to the top surface of the receiving part where the material is located, and after the set time is reached, the rotary lifting piece rotates to the receiving position and then rotates to enable the material to fall to the discharging part; after the rotary material receiving piece and the rotary lifting piece are repeatedly operated for a plurality of times to meet the galvanization requirement, the material is positioned on the rotary lifting piece, the rotary lifting piece rises to the stirring position, the rotary material receiving piece rotates to drive the stirring part to rotate, and the stirring part stirs out the material to finish one-time galvanization process.

According to the utility model, through the matched use of the rotary lifting piece and the rotary receiving piece, the full hot plating of the materials can be ensured, uneven hot plating caused by the abutting of a certain part of the materials with the receiving part or the discharging part is avoided, uneven hot plating caused by the abutting of a plurality of materials can be avoided through the single material taking of the material taking claw, the automation of a hot plating process can be realized through the matching of the material taking claw, the rotary lifting piece and the rotary receiving piece, the labor intensity of operators is reduced, the production takt can be selected through the arrangement quantity of the receiving part and the discharging part, and the production takt can be accelerated if more receiving parts and discharging parts are arranged.

Drawings

The utility model will be described in further detail with reference to the drawings and the detailed description.

FIG. 1 is a schematic diagram of the structure of the present utility model;

In the figure: the device comprises a material taking table-1, a material taking claw-2, a rotary lifting piece-3, a material discharging part-301, a material discharging inlet-302, a material discharging blocking part-303, a rotary material receiving piece-4, a material receiving part-401, a material stirring part-402, a material receiving inlet-403, a material receiving blocking part-404, a yielding notch-5, a first linear driving piece-6, a movable connecting piece-7, a second linear driving piece-8, a third linear driving piece-9, a rack one-10, a gear one-11, a fourth linear driving piece-12, a fifth linear driving piece-13, a rack two-14 and a gear two-15.

Detailed Description

The technical solutions of the embodiments of the present utility model will be clearly and completely described below in conjunction with the embodiments of the present utility model, and it is apparent that the described embodiments are only some embodiments of the present utility model, not all embodiments. All other embodiments, which can be made by one of ordinary skill in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

As shown in fig. 1, the embodiment provides a novel hot dip coating alloy equipment structure, which comprises

The material taking table 1 is provided with a material taking device,

The material taking claw 2 is arranged on the material taking table 1 in a lifting and moving manner and in a transverse moving manner,

A rotary lifting member 3, the rotary lifting member 3 is arranged on the material taking table 1 in a lifting and lowering manner, the rotary lifting member 3 is provided with at least one material discharging part 301, the rotary lifting member 3 is positioned on one side below the material taking claw 2,

The rotary material receiving piece 4 is rotatably arranged on the material taking table 1 and is positioned on one side of the rotary lifting piece 3, the rotary material receiving piece 4 is provided with at least one material receiving portion 401, the rotary material receiving piece 4 is positioned on the other side below the material taking claw 2, and the rotary material receiving piece 4 is further provided with a material stirring portion 402 above the material receiving portion 401.

The embodiment provides a novel hot dip coating alloy equipment structure, which comprises a material taking table 1, material taking claws 2, a rotary lifting piece 3 and a rotary material receiving piece 4. The material taking claw 2 is arranged on the material taking table 1, the material taking claw 2 can move up and down and transversely, the material taking claw 2 transversely moves to a chain conveying line to take materials, and the material taking claw transversely moves to the upper part of the alloy plating pool; the material taking claw 2 moves to the upper part of the alloy plating pool and then descends to the bottom of the alloy plating pool, the rotary lifting piece 3 is lifted in place, and the material taking claw 2 transversely moves to the lower part of the rotary lifting piece 3; after the rotary lifting member 3 descends to the position that the discharging part 301 of the rotary lifting member 3 is lower than the material taking claw 2, the rotary lifting member 3 rotates to the material receiving position, the material taking claw 2 is loosened and ascended to move, and the material falls onto the discharging part 301 of the rotary lifting member 3; when the material reaches the discharging part 301 and is received for a set time for a single time, the rotary lifting part 3 is lifted, and when the rotary lifting part 3 is lifted to a position where the top surface of the discharging part 301 is higher than or equal to one receiving part 401 of the rotary receiving claw, the rotary receiving part 4 rotates first, after the rotary receiving part 4 is in place, the rotary lifting part 3 rotates, and the material is placed on the receiving part 401 of the rotary receiving claw; the rotary lifting piece 3 is lifted or lowered to enable the top surface of one discharging part 301 to be lower than or equal to the top surface of the receiving part 401 where the material is located, after the set time is reached, the rotary lifting piece 3 is rotated to the receiving position, and then the rotary material receiving piece 4 is rotated to enable the material to fall to the discharging part 301; after the rotary material receiving piece 4 and the rotary lifting piece 3 are repeatedly operated for a plurality of times to meet the galvanization requirement, the material is positioned on the rotary lifting piece 3, the rotary lifting piece 3 rises to the stirring position, the rotary material receiving piece 4 rotates to drive the stirring part 402 to rotate, and the stirring part 402 stirs out the material to finish one-time alloying process.

In this embodiment, through the cooperation of rotatory lifting member 3 and rotatory receiving member 4, can guarantee the abundant hot-dip of material, avoid a certain part of material to be because of with receiving portion 401 or blowing portion 301 butt and hot-dip uneven, get the butt between can avoid many materials to lead to hot-dip uneven through getting the single material of getting material claw 2, through getting material claw 2, rotatory lifting member 3 and rotatory receiving member 4's cooperation can realize the automation of hot-dip process, operating personnel's intensity of labour has been reduced, accessible receiving portion 401 and blowing portion 301 set up quantity select the takt, if set up more receiving portion 401 and blowing portion 301 and can accelerate the takt.

Further, one side of the discharging portion 301 is a discharging inlet 302, the other side of the discharging portion 301 is a discharging blocking portion 303, and the discharging portion 301 is at least two of the discharging portions which are arranged in sequence.

In this embodiment, one side of the discharging portion 301 is a discharging inlet 302, so that materials enter the discharging portion 301, and the other side is a discharging blocking portion 303, so that the materials are prevented from falling out of the discharging portion 301 when the receiving portion 401 rotates, and at least two discharging portions 301 should be arranged, so that the lifting range of the materials in the hot dip plating pool is increased, and the full hot dip plating of the materials is ensured.

Further, one side of the receiving portion 401 is a receiving inlet 403, the other side is a receiving blocking portion 404, and the receiving portion 401 is at least two of the receiving portions which are arranged in sequence from top to bottom. In this embodiment, one side of the discharging portion 301 is a receiving inlet 403, which is used for allowing materials to enter the receiving portion 401, and the other side is a receiving blocking portion 404, so that the materials are prevented from falling out of the receiving portion 401 when the receiving portion 401 rotates, and at least two receiving portions 401 are required to be arranged, so as to increase the lifting range of the materials in the hot dip plating pool, and ensure sufficient hot dip plating of the materials.

Further, the material taking claws 2 are at least two and are distributed on two sides of the rotary material receiving piece 4, the rotary lifting piece 3 is located at the edge of the material taking table 1, and the rotary lifting piece 3 penetrates through the material taking table 1. In this embodiment, get material claw 2 and just distribute and set up in the both sides of rotary joint material piece 4 at least, two get material claw 2 cooperation and use can guarantee that the material can not appear both sides and collapse and get the material steadily, have reduced the loss in the material course of working.

Further, two rotary receiving pieces 4 are a set of and symmetrically arranged on the material taking table 1 and located between the two rotary lifting pieces 3, the rotary receiving pieces 4 are located beside the edge of the material taking table 1, and the rotary receiving pieces 4 penetrate through the material taking table 1. In this embodiment, two rotary material receiving pieces 4 are a set of and symmetrically arranged on the material taking table 1, so that the material can not fall to the bottom of the plating tank when the material receiving portion 401 is arranged, the loss in the hot dipping process is reduced, the rotary material receiving pieces 4 and the rotary lifting pieces 3 are arranged at intervals, the uneven hot dipping of a certain part of the material due to the abutting connection with the material receiving portion 401 or the material discharging portion 301 can be reduced, and the rejection rate is reduced.

Further, the take-out claws 2 are two in one group and have several groups. In this embodiment, two get material and be a set of, the material that the multiunit set up is got the material and can be improved production beat, when snatching by the material of overlength, can be snatched by multiunit material taking claw 2 together to guarantee that the material middle part of snatching is not downwarping because of both sides overlength, guarantee that the material can put into blowing portion 301 smoothly, can not take place the interference phenomenon of material and blowing portion 301 in the rotatory in-process of rotatory lifting member 3 because of the elastic deformation of material, thereby reduce the rejection rate.

Further, the take-out table 1 has: the two yielding notches 5 are arranged on the material taking table 1 in sequence, the material taking claw 2 stretches into the yielding notches 5, the material taking claw 2 passes through the yielding notches 5 when moving up and down, the rotary material receiving piece 4 is arranged between the two yielding notches 5, and the rotary lifting piece 3 is arranged at two sides of the two yielding notches 5 respectively.

Further, the method further comprises the following steps: the first linear driving piece 6, the vertical removal of first linear driving piece 6 drive material taking claw 2, remove connecting piece 7 lateral shifting and set up on getting material platform 1, first linear driving piece 6 sets up on removing connecting piece 7, the second linear driving piece 8, the setting of second linear driving piece 8 is on getting material platform 1, drive remove connecting piece 7 lateral shifting.

In this embodiment, the material taking claw 2 is driven to move up and down by the first linear driving member 6, the first linear driving member 6 is connected to the moving connecting member 7, the first linear connecting member is driven by the second linear driving member 8 to move transversely, and the first linear connecting member and the second linear connecting member are both hydraulic cylinders, so that the reaction is rapid, the cost is low, and the accessory can be conveniently replaced.

Further, the method further comprises the following steps: the third linear driving member 9, the third linear driving member 9 is arranged on the material taking table 1, the first rack 10 is arranged at the output end of the third linear driving member 9, the first gear 11 is arranged on the material taking table 1, the first gear 11 and the first rack 10 are meshed, the rotary lifting member 3 is arranged on the first gear 11 in a penetrating mode, the first gear 11 drives the rotary lifting member 3 to rotate, the fourth linear driving member 12 is arranged at the output end of the fourth linear driving member 12 in a rotating mode, and the rotary lifting member 3 is arranged at the output end of the fourth linear driving member 12 in a rotating mode.

In this embodiment, the third linear driving member 9 drives the rack one 10 to perform translational movement, the rack one 10 drives the moving gear one 11 to rotate, the gear one 11 drives the rotating lifting member 3 to rotate, the fourth linear driving member 12 drives the rotating lifting member 3 to perform lifting movement, the third linear driving member 9 and the fourth linear driving member 12 are hydraulic cylinders, and the rack and pinion structure is long in service life, strong in universality, convenient to maintain, and convenient to maintain and long in service life.

Further, the method further comprises the following steps: the fifth linear driving piece 13, the fifth linear driving piece 13 sets up on getting material platform 1, rack two 14, and the output of fifth linear driving piece 13 is connected with rack two 14, and gear two 15, gear one 11 set up on getting material platform 1, and gear two 15 and rack two 14 meshing setting, gear one 11 drive rotation receiving piece 4, and rotation receiving piece 4 top is connected with gear two 15 bottom.

In this embodiment, the fifth linear driving member 13 drives the second rack 14 to perform translational movement, the second rack 14 drives the second movable gear 15 to rotate, the second gear 15 drives the rotary material receiving member 4 to rotate, the fifth linear driving member 13 is a hydraulic cylinder, the service life is long, the universality is strong, the maintenance is convenient, the gear-rack structure is convenient to maintain, and the service life is long.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the utility model.

Claims (10)

1. The novel equipment structure for hot dip coating alloy is characterized by comprising

A material taking table (1),

The material taking claw (2), the material taking claw (2) moves up and down and is arranged on the material taking table (1) in a transverse movement way,

The rotary lifting piece (3), the rotary lifting piece (3) moves up and down and is rotatably arranged on the material taking table (1), the rotary lifting piece (3) is provided with at least one material discharging part (301), the rotary lifting piece (3) is positioned at one side below the material taking claw (2),

The rotary material receiving piece (4), the rotary material receiving piece (4) rotates to be arranged on the material taking table (1) and is located on one side of the rotary lifting piece (3), the rotary material receiving piece (4) is provided with at least one material receiving part (401), the rotary material receiving piece (4) is located on the other side below the material taking claw (2), and the rotary material receiving piece (4) is further provided with a material stirring part (402) above the material receiving part (401).

2. The novel hot dip coating alloy equipment structure according to claim 1, wherein one side of the discharging part (301) is a discharging inlet (302), the other side of the discharging part is a discharging blocking part (303), and the discharging part (301) is at least two of the discharging parts which are sequentially arranged from top to bottom.

3. The novel hot dip coating alloy equipment structure according to claim 1, wherein one side of the receiving part (401) is a receiving inlet (403), the other side of the receiving part is a receiving baffle part (404), and the receiving part (401) is at least two of the receiving parts which are arranged in sequence from top to bottom.

4. The novel hot dip coating alloy equipment structure according to claim 1, wherein the number of the material taking claws (2) is at least two, the material taking claws are distributed on two sides of the rotary material receiving member (4), the rotary lifting member (3) is located at the edge of the material taking table (1), and the rotary lifting member (3) penetrates through the material taking table (1).

5. The novel hot dip coating alloy equipment structure according to claim 1, wherein two rotary receiving pieces (4) are arranged on the material taking table (1) symmetrically and are positioned between the two rotary lifting pieces (3), the rotary receiving pieces (4) are positioned beside the edge of the material taking table (1), and the rotary receiving pieces (4) penetrate through the material taking table (1).

6. The novel hot dip coating alloy equipment structure according to claim 1, wherein two of the material taking claws (2) are in one group and are provided with a plurality of groups.

7. The plant structure of a new hot dip coating alloy according to claim 1, characterized in that the reclaiming station (1) has:

The utility model discloses a material taking device, including material taking platform (1), material taking claw (2), gap (5) of stepping down, step down, gap (5) of stepping down is two, step down (5) are arranged in proper order on material taking platform (1), just material taking claw (2) stretches into step down gap (5), material taking claw (2) go through when going up and down to remove step down gap (5), rotatory receiving piece (4) set up two step down between gap (5), rotatory lifting part (3) are two to set up respectively in two step down gap (5) both sides.

8. An apparatus structure for hot dip coating a novel alloy according to claim 1, further comprising:

A first linear driving piece (6), wherein the first linear driving piece (6) drives the material taking claw (2) to move vertically,

A movable connecting piece (7), wherein the movable connecting piece (7) is transversely arranged on the material taking table (1) in a movable way, the first linear driving piece (6) is arranged on the movable connecting piece (7),

The second linear driving piece (8), the second linear driving piece (8) is arranged on the material taking table (1), and drives the movable connecting piece (7) to move transversely.

9. An apparatus structure for hot dip coating a novel alloy according to claim 1, further comprising:

A third linear drive (9), the third linear drive (9) being arranged on the take-off table (1),

A first rack (10), wherein the first rack (10) is arranged at the output end of the third linear driving piece (9),

The first gear (11), the first gear (11) is arranged on the material taking table (1), the first gear (11) is meshed with the first rack (10), the rotary lifting piece (3) is arranged on the first gear (11) in a penetrating way, the first gear (11) drives the rotary lifting piece (3) to rotate,

-A fourth linear drive (12), the rotary lifter (3) being rotatably arranged at the output of the fourth linear drive (12).

10. An apparatus structure for hot dip coating a novel alloy according to claim 1, further comprising:

a fifth linear driving member (13), the fifth linear driving member (13) being arranged on the material taking table (1),

A second rack (14), the output end of the fifth linear driving piece (13) is connected with the second rack (14),

The first gear (11) is arranged on the material taking table (1), the second gear (15) is meshed with the second rack (14), the first gear (11) drives the rotary material receiving piece (4), and the top of the rotary material receiving piece (4) is connected with the bottom of the second gear (15).