CN115466945B - Phosphating plating device for metal material processing - Google Patents

Abstract

The invention relates to the field of metal phosphating equipment, in particular to a metal material processing phosphating device, which comprises a phosphating pool, wherein the phosphating pool is provided with a containing cavity, a filter belt is arranged in the containing cavity, the length of the filter belt is larger than that of the phosphating pool, two ends of the filter belt in the length direction are connected with the edges of the containing cavity, a plurality of groups of conducting pieces are arranged and slide in the phosphating pool, the conducting pieces are connected with a first roller and a second roller which are arranged in the containing cavity, the first roller and the second roller are provided with a space, the filter belt sequentially bypasses the first roller and the second roller to form a stacked shape at two ends of the containing cavity.

Description

Phosphating plating device for metal material processing

Technical Field

The invention relates to the field of metal phosphating equipment, in particular to a phosphating plating device for metal material processing.

Background

The phosphating process of the metal material is to form a phosphate chemical conversion film on the surface of the metal material, the formed phosphate chemical conversion film is called as a phosphating film, and the phosphating treatment of the metal material has more advantages, so that the metal material is protected, and the metal is prevented from being corroded to a certain extent; the paint is used for priming before painting, and improves the adhesive force and the corrosion resistance of a paint film layer; the friction-reducing lubricating agent is used in the metal cold working process.

The existing phosphating mode has various modes, namely a dipping phosphating mode, a spraying phosphating mode and a brushing phosphating mode, wherein the dipping phosphating mode is most widely applied, and the metal material is put into a phosphating pool containing phosphating solution, so that the phosphating method has a comprehensive phosphating effect, has no limitation on the shape of the metal material, and can keep a stable phosphating temperature.

The dipping phosphating mode mainly adopts phosphating Chi Chengfang phosphating solution, metal materials are sequentially subjected to phosphating treatment in a phosphating tank, the concentration of phosphating slag generated in the phosphating solution is gradually increased along with the increase of phosphating treatment capacity, more phosphating slag influences the phosphating treatment of subsequent metal materials, if the phosphating solution is replaced, the cost investment is large, the processing efficiency is greatly reduced, a circulating slag removal method is also adopted, the phosphating solution is continuously circulated and conducted while the phosphating is performed, the phosphating slag in the phosphating solution is continuously removed outside the phosphating tank, the mode causes serious temperature loss of the phosphating solution, and the processing energy consumption is greatly improved.

Disclosure of Invention

The invention aims to solve the following problems in the prior art: along with the increase of the phosphating treatment capacity, the concentration of the generated phosphating slag in the phosphating solution is gradually increased, more phosphating slag influences the phosphating treatment of subsequent metal materials, if the phosphating solution is replaced, the cost investment is large, the processing efficiency is greatly reduced, the circulating slag removal method is also adopted, the phosphating solution is continuously circulated and conducted while the phosphating is performed, the phosphating slag in the phosphating solution is continuously removed outside a phosphating tank, the mode causes serious temperature loss of the phosphating solution, and the processing energy consumption is greatly improved.

In order to solve the problems in the prior art, the invention provides a metal material processing phosphating plating device, which comprises a phosphating pool, wherein the phosphating pool is provided with a containing cavity, a filter belt is arranged in the containing cavity, the length of the filter belt is larger than that of the phosphating pool, two ends of the length direction of the filter belt are connected with the edge of the containing cavity, a plurality of groups of conducting pieces are arranged and slide in the phosphating pool, the conducting pieces are connected with a first roller and a second roller which are arranged in the containing cavity, the first roller and the second roller are provided with a distance, the filter belt sequentially bypasses the first roller and the second roller to form a stacking shape at two ends of the containing cavity, the upper part between stacking parts of the filter belt is a phosphating area, and the conducting pieces slide from one end of the rectangular cavity to the other end of the rectangular cavity to filter impurities in the phosphating area into a stacking gap of the filter belt.

Preferably, the conducting piece comprises two groups of hanging frames, the two groups of hanging frames are arranged at two ends of the first roller and the second roller, the hanging frames are connected with the first roller and the second roller in a rotating mode, the first roller and the second roller are respectively arranged at the top and the bottom of the accommodating cavity, and the top of the hanging frames is connected with the driving device.

Preferably, the driving device comprises two groups of screw rods, the two groups of screw rods rotate on two sides of the phosphating pool, the two groups of screw rods are connected with a motor through chain transmission, the surfaces of the screw rods are connected with a plurality of locking assemblies, and the locking assemblies are connected with the hanging frames one by one.

Preferably, the locking assembly comprises a seat block, the seat block is fixedly connected with the hanging frame, a threaded cylinder is rotated in the seat block through a bearing, the threaded cylinder is in threaded connection with the screw rod, a plurality of blades are fixed on the outer wall of the threaded cylinder at equal angles, a limiting gap is formed between the blades, a limiting screw is arranged on the surface of the seat block in a threaded manner, and the end part of the limiting screw is inserted into the limiting gap to limit the rotation of the threaded cylinder.

Preferably, the filter belt comprises a filter layer, rubber strips are connected to two sides of the filter layer and in sliding contact with the side wall of the accommodating cavity, raised strips are arranged on the surface of the rubber strips and are provided with raised surfaces, annular grooves are formed in two ends of the first roller and the second roller, and the raised strips are adapted to be clamped into the annular grooves when the rubber strips bypass the first roller and the second roller.

Preferably, a soft magnetic strip is embedded and fixed in the rubber strip, and a magnetic metal layer is arranged in the side wall of the phosphating pool.

Preferably, the filter belt in the phosphating area is obliquely connected with the adjacent first roller and second roller, a belt pressing piece is arranged above the inclined top of the filter belt and used for pressing the inclined top of the filter belt to the lower part of the accommodating cavity, so that the inclined top of the filter belt descends to be flush with the inclined bottom, and the phosphating area space is enlarged.

Preferably, the belt pressing piece comprises a support, a swing frame is rotated at the top of the support, a swing arm is coaxially and parallelly fixed on the swing frame, a pressing roller is rotated at the other end of the swing frame, an electric push rod is rotated on the surface of the support, and the telescopic end of the electric push rod is rotationally connected with the swing arm.

Preferably, a stretching roller is arranged at the lower part of one end of the accommodating cavity, the filtering layer bypasses the stretching roller, sliding blocks are rotated at the two ends of the stretching roller, sliding grooves are formed in the side walls of the accommodating cavity, the sliding blocks can vertically slide along the sliding grooves, and springs connected with the sliding blocks are arranged in the sliding grooves.

Compared with the related art, the metal material processing phosphating plating device provided by the invention has the following beneficial effects:

1. according to the invention, the first rollers and the second rollers which are arranged in a multi-group manner are used for folding the conductive filter belt, so that a phosphating area limited by the filter belt is formed in the middle of the phosphating tank, each group of the first rollers and the second rollers are sequentially and linearly moved, the filter belt is folded to store phosphating slag in the phosphating area, the influence of the accumulated phosphating slag on phosphating processing of metal materials is avoided, the continuous bending of the filter belt can realize the purification of the phosphating slag for a plurality of times, the maintenance period is greatly improved, the process is automatically completed in the phosphating tank, external treatment of phosphating liquid is not needed, the phosphating liquid is kept at a stable temperature, and the energy consumption is reduced;

2. the invention can selectively adjust the positions of the hanging brackets while keeping the positioning of each group of hanging brackets through the locking component, thereby realizing the automatic and orderly execution of the filtering action of the filtering belt.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present invention;

FIG. 2 is a second schematic diagram of the overall structure of the present invention;

FIG. 3 is a schematic view of a stacked distribution structure of a filter belt according to the present invention;

FIG. 4 is a second schematic diagram of a stacked distribution structure of a filter belt according to the present invention;

FIG. 5 is a schematic view of the stretch roll mounting structure of the present invention;

FIG. 6 is a schematic diagram of a driving apparatus according to the present invention;

FIG. 7 is a schematic view of a locking assembly according to the present invention;

FIG. 8 is a second schematic diagram of the locking assembly of the present invention;

FIG. 9 is a schematic diagram of a conductive member according to the present invention;

fig. 10 is a schematic view of the structure of the filter belt of the present invention.

Reference numerals in the drawings: 1. a phosphating pool; 2. a filter belt; 21. a filter layer; 22. a rubber strip; 23. a convex strip; 24. a ring groove; 25. a soft magnetic stripe; 3. a conductive member; 31. a hanging bracket; 32. a first roller; 33. a second roller; 4. a motor; 41. a screw rod; 5. a locking assembly; 51. a seat block; 52. a thread cylinder; 53. a blade; 54. a limit screw; 6. a belt pressing member; 61. a bracket; 62. an electric push rod; 63. swing arms; 64. a swing frame; 65. a press roller; 7. a stretching roller; 71. a chute; 72. a slide block; 8. and (5) pressing plates.

Detailed Description

The present invention will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present invention more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the invention.

Specific implementations of the invention are described in detail below in connection with specific embodiments.

Example 1

As shown in fig. 1-2, a metal material processing phosphating plating device is formed by taking a phosphating tank 1 as a main body, wherein the phosphating tank 1 is provided with a containing cavity with a top opening open, the inner walls of the width sides of the containing cavity are parallel, one end of the phosphating tank 1 is provided with a pipeline for leading in and discharging phosphating solution, and a heating component is arranged in the wall of the phosphating tank 1 or is directly put into the containing cavity in the subsequent process;

as shown in fig. 1-4 and 9, a plurality of groups of conducting elements 3 are arranged in the accommodating cavity, the conducting elements 3 comprise two groups of hanging frames 31, the hanging frames 31 sink to the bottom from the top opening of the accommodating cavity, the top parts of the hanging frames 31 are in sliding fit with the edge of the accommodating cavity, a first roller 32 and a second roller 33 are rotatably arranged between each group of hanging frames 31, and the first roller 32 and the second roller 33 are respectively arranged at the top and the bottom of the accommodating cavity;

as shown in fig. 3-4, the hanging frame 31 is all arranged to one end of the accommodating cavity in a sliding way, the width of the filter belt 2 is adapted to the width of the accommodating cavity, one end of the filter belt 2 in the length direction is fixed at the top edge of the accommodating cavity in the length direction through the pressing plate 8, the filter belt 2 sequentially bypasses the first roller 32 and the second roller 33 to form a stacked shape, then the filter belt 2 is obliquely conducted to the other end of the accommodating cavity in the length direction and is fixed through the pressing plate 8, the filter belt 2 is straightened, and an oblique phosphating area is formed at the upper part of the filter belt 2 in the middle of the accommodating cavity;

introducing phosphating solution into a phosphating pond 1, wherein the height of the phosphating solution is always lower than that of a first roller 32, placing metal materials in a phosphating area for phosphating, limiting phosphating slag generated in the phosphating area by a filter belt 2, setting a slag removal period, for example, carrying out one slag removal process after phosphating a certain weight or a certain number of metal materials;

deslagging the phosphating solution: taking the hanger 31 arranged on the left side in advance as an example, the hanger 31 close to the phosphating area slides to the right side of the accommodating cavity, the filter belt 2 gradually approaches to the right side end of the accommodating cavity under the conduction of the first roller 32 and the second roller 33 to form a folding shape, because the height of phosphating solution is lower than that of the first roller 32, the phosphating residues in the original phosphating area are filtered and remained in the folding gap of the filter belt 2 by the filter belt 2, a new inclined phosphating area is formed between the next hanger 31 and the hanger 31 which is just moved to the right side, the metal phosphating treatment of the next period is carried out, and a plurality of groups of hangers 31, the first roller 32 and the second roller 33 can carry out continuous slag removal work for a plurality of times, so that the accumulation concentration of the phosphating residues in the phosphating solution is reduced;

as shown in fig. 10, the filter belt 2 is made of a filter layer 21 made of glass fiber, soft rubber strips 22 are fixedly connected to two ends of the filter layer 21, raised convex strips 23 are arranged on two side surfaces of the rubber strips 22, annular grooves 24 are formed at two ends of each group of first roller 32 and second roller 33, when the filter belt 2 is conducted around the first roller 32 and the second roller 33, the rubber strips 22 play a role in resisting stretching at edges, and the convex strips 23 are clamped with the annular grooves 24 at the end parts of the first roller 32 and the second roller 33 to enable the rubber strips 22 to conduct straight line along the first roller 32 and the second roller 33 stably so as to straighten the filter layer 21 to form a finished filter surface;

as shown in fig. 10, the rubber strip 22 is embedded and fixed with a soft magnetic strip 25, a magnetic metal layer, such as an iron plate, is arranged in the side wall of the phosphating tank 1, and the soft magnetic strip 25 and the magnetic metal layer generate adsorption force, so that the rubber strip 22 always adheres to the side wall of the phosphating tank 1, and a large amount of phosphating slag leakage at the edge of the filter belt 2 in the conduction process is avoided.

Example two

The driving device is used for automatically adjusting the position of the hanging frame 31 and is used for automatically removing the phosphorized slag, and the concrete steps are as follows:

as shown in fig. 6, the driving device comprises two groups of screw rods 41, the two groups of screw rods 41 rotate on two sides of the phosphating pool 1, a motor 4 is arranged at one end of the phosphating pool 1, and the ends of the two groups of screw rods 41 are in transmission connection with the motor 4 through a chain;

as shown in fig. 7-8, the top of the hanger 31 is fixed with a locking component 5, the locking component 5 comprises a seat block 51, the seat block 51 is fixedly connected with the hanger 31, a threaded cylinder 52 penetrates through the seat block 51 through bearing rotation, a lead screw 41 penetrates through the threaded cylinder 52 through threads, a plurality of blades 53 are fixed on the surface of the threaded cylinder 52 at equal angles, a limit gap is formed between the blades 53, a limit screw 54 penetrates through the inside of the surface of the seat block 51 through threads, and the end part of the limit screw 54 is aligned with a limit space;

when the position of the hanging frame 31 needs to be adjusted, the limiting screw 54 is retracted out of the limiting gap in a normal state, the corresponding limiting screw 54 is clamped into the limiting gap, the motor 4 is started to drive the two groups of screw rods 41 to synchronously rotate, the threaded cylinder 52 at the non-adjusting part is not limited to rotate along with the screw rods 41, so that the hanging frame 31 is not displaced, the threaded cylinder 52 at the adjusting part is limited by the limiting screw 54, the threaded cylinder 52 can not rotate along with the screw rods 41, and the seat block 51 drives the hanging frame 31 to linearly move under the pushing of threads, so that the position of the hanging frame 31 is automatically adjusted;

the limitation of the limit screw 54 on the threaded cylinder 52 is timely released after the hanging frame 31 is adjusted in place, so that the situation that the hanging frame 31 of the upper group synchronously moves against the end part of the accommodating cavity to cause clamping is avoided when the next hanging frame 31 is adjusted due to forgetting to release the limitation;

example III

As shown in fig. 1-4, a belt pressing member 6 is arranged to press down the filter belt 2 in the phosphating area, so that the top of the inclined filter belt 2 is sunk to the bottom of the accommodating cavity to form a flat bottom surface, and the phosphating area space is enlarged, and the concrete operation is as follows:

the belt pressing piece 6 comprises a bracket 61 fixed at the edge of the phosphating pool 1, a swinging frame 64 rotates at the top of the bracket 61, a pressing roller 65 is rotatably arranged at the other end of the swinging frame 64, a swinging arm 63 is coaxially and parallelly fixed on the swinging frame 64, an electric push rod 62 rotates on the surface of the bracket 61, and the telescopic end of the electric push rod 62 is rotatably connected with the swinging arm 63;

as shown in fig. 5, a stretching roller 7 is arranged at the lower part of one end of the accommodating cavity, the filter belt 2 bypasses the stretching roller 7 and then bypasses the first roller 32 and the second roller 33, two ends of the stretching roller 7 are rotated with sliding blocks 72, the side wall of the accommodating cavity is provided with sliding grooves 71, the sliding blocks 72 can vertically slide along the sliding grooves 71, and the sliding blocks 72 are elastically connected with the sliding grooves 71 through springs;

the slider 72 is made to slide downwards through the elasticity of the spring, stretch filter belt 2 to be in the state of stretching straightly, when drive gallows 31 drive filter belt 2 carries out the scarfing cinder, open electric putter 62 extension, make swing arm 63 drive swing frame 64 rotate and raise to the horizontality, swing frame 64 and compression roller 65 shift out the holding chamber and drive the removal of filter belt 2 for gallows 31 and give way, after the scarfing cinder is accomplished, open electric putter 62 shrink, make swing frame 64 rotate to vertical state downwards through the pulling of swing arm 63, compression roller 65 pushes down the slope top of filter belt 2 to parallel slope bottom, enlarge the space in phosphating region, filter belt 2 is pulled this moment, make stretch roller 7 drive slider 72 at both ends overcome the elasticity and slide up along spout 71 for balanced filter belt 2's guide.

Claims (6)

1. The utility model provides a metal material processing phosphating plating device, including phosphating pond (1), a serial communication port, phosphating pond (1) has the holding chamber, filter belt (2) are had in the holding chamber, the length of filter belt (2) is greater than the length of phosphating pond (1), the edge of holding chamber is connected at filter belt (2) length direction both ends, arrange and slide a plurality of groups of conductors (3) in phosphating pond (1), conductor (3) are connected with first roller (32) and second roller (33) of placing in the holding chamber, first roller (32) and second roller (33) have the interval, filter belt (2) are walked around first roller (32) and second roller (33) in proper order and are formed the stack form at the both ends of holding chamber, the upper portion between filter belt (2) stack position is the phosphating region, conductor (3) are by rectangle chamber one end to the other end filtration impurity in the phosphating region to filter belt (2) stack clearance.

The conducting piece (3) comprises two groups of hanging frames (31), the two groups of hanging frames (31) are arranged at two ends of a first roller (32) and a second roller (33), the first roller (32) and the second roller (33) are rotationally connected with the hanging frames (31), the first roller (32) and the second roller (33) are respectively arranged at the top and the bottom of the accommodating cavity, and the top of the hanging frames (31) is connected with a driving device;

the filter belt (2) comprises a filter layer (21), rubber strips (22) are connected to two sides of the filter layer (21), the rubber strips (22) are in sliding contact with the side wall of the accommodating cavity, raised strips (23) with protruding surfaces are arranged on the surfaces of the rubber strips (22), annular grooves (24) are formed in two ends of the first roller (32) and the second roller (33), and the raised strips (23) are adaptively clamped into the annular grooves (24) when the rubber strips (22) bypass the first roller (32) and the second roller (33);

the soft magnetic strips (25) are embedded and fixed in the rubber strips (22), and the magnetic metal layers are arranged in the side walls of the phosphating pool (1).

2. The metal material processing phosphating plating device according to claim 1, wherein the driving device comprises two groups of screw rods (41), the two groups of screw rods (41) rotate on two sides of the phosphating pool (1), the two groups of screw rods (41) are connected with motors (4) through chain transmission, the surfaces of the screw rods (41) are connected with a plurality of locking assemblies (5), and the locking assemblies (5) are connected with the hanging frames (31) one by one.

3. The metal material processing phosphating plating device according to claim 2, wherein the locking assembly (5) comprises a seat block (51), the seat block (51) is fixedly connected with the hanging bracket (31), a threaded cylinder (52) is rotated in the seat block (51) through a bearing, the threaded cylinder (52) is in threaded connection with the screw rod (41), a plurality of blades (53) are fixed on the outer wall of the threaded cylinder (52) at equal angles, a limiting gap is formed between the blades (53), a limiting screw (54) is arranged on the surface of the seat block (51) in a threaded manner, and the end part of the limiting screw (54) is inserted into the limiting gap to limit the rotation of the threaded cylinder (52).

4. The metal material processing phosphating plating apparatus according to claim 1, wherein the filter belt (2) in the phosphating zone is connected with the adjacent first roller (32) and second roller (33) in an inclined manner, a belt pressing member (6) is arranged above the inclined top of the filter belt (2), and the belt pressing member (6) is used for pressing the inclined top of the filter belt (2) to the lower part of the accommodating cavity, so that the inclined top of the filter belt (2) is lowered to be flush with the inclined bottom, and the phosphating zone space is enlarged.

5. The metal material processing phosphating plating apparatus according to claim 4, wherein the belt pressing member (6) includes a bracket (61), a swing frame (64) is rotated at the top of the bracket (61), a swing arm (63) is coaxially and parallelly fixed to the swing frame (64), a press roller (65) is rotated at the other end of the swing frame (64), an electric push rod (62) is rotated on the surface of the bracket (61), and a telescopic end of the electric push rod (62) is rotatably connected with the swing arm (63).

6. The metal material processing phosphating plating apparatus according to claim 5, wherein a stretching roller (7) is arranged at the lower part of one end of the accommodating cavity, the filtering layer (21) bypasses the stretching roller (7), sliding blocks (72) are rotated at two ends of the stretching roller (7), sliding grooves (71) are formed in the side walls of the accommodating cavity, the sliding blocks (72) can vertically slide along the sliding grooves (71), and springs connected with the sliding blocks (72) are arranged in the sliding grooves (71).