CN219037488U - Drying equipment is used in flux cored wire production - Google Patents

Abstract

The utility model discloses drying equipment for flux-cored wire production, which comprises a drying cylinder, a heating pipeline, an adjusting structure, a support seat and a support plate, wherein the drying cylinder is composed of an inner cylinder and an outer cylinder, a cavity structure is formed by surrounding the inner cylinder and the outer cylinder, a left-right through channel is arranged in the inner cylinder, the left end of the inner cylinder channel is an inlet end, the right end of the inner cylinder channel is an outlet end, and the inner diameters of the inlet end and the outlet end are smaller than the inner diameter of the inner cylinder; the drying cylinder is arranged on the support plate through the support seat, the adjusting structure is arranged below the support plate, and the height of the drying cylinder can be adjusted through the adjusting structure. The height of the drying cylinder can be adjusted through the adjusting structure so as to meet the requirement of the cooperation use of different cleaning equipment. The drying cylinder adopts a cylindrical structure formed by the inner cylinder and the outer cylinder, and compared with a drying box body commonly adopted in the prior art, the drying cylinder has the advantages of much smaller volume and less unnecessary waste of heat.

Description

Drying equipment is used in flux cored wire production

Technical Field

The utility model relates to the technical field of drying equipment for flux-cored wire production, in particular to drying equipment for flux-cored wire production.

Background

The flux-cored wire is divided into a seamed flux-cored wire and a seamless flux-cored wire according to the production characteristics, and the manufacturing method of the flux-cored wire is that a steel belt is generally adopted in the seamed flux-cored wire internationally to prepare the flux-cored wire.

The drying equipment currently used is mainly as follows: the utility model discloses a flux cored wire steel band drying device as disclosed in patent CN201720306508.3, it includes stoving case, steel band advance pipe, steel band exit tube, leading wheel and heater, the steel band advance the pipe with the steel band exit tube corresponds set up in the same altitude department of stoving case left and right sides lateral wall. Although the drying equipment can finish the drying of the steel belt, the utilization rate of heat generated by the heater is easy to be low due to the large volume of the drying box. In addition, the drying box is large in size, the positions of the steel belt inlet and the steel belt outlet are fixed, and the heights of the steel belt inlet and the steel belt outlet cannot be adjusted according to the heights of different cleaning equipment.

Therefore, in order to solve the above problems, there is a need for a drying apparatus for flux-cored wire production.

Disclosure of Invention

In view of the above, the present utility model discloses a drying apparatus for flux-cored wire production, which can effectively solve the above problems in the prior art.

In order to achieve the aim, the technical proposal of the utility model is to provide a drying device for flux-cored wire production, which comprises a drying cylinder, a heating pipeline, an adjusting structure, a bracket seat and a bracket plate,

the drying cylinder consists of an inner cylinder and an outer cylinder, a cavity structure is formed by surrounding the inner cylinder and the outer cylinder, a left-right through channel is arranged in the inner cylinder, the left end of the inner cylinder channel is an inlet end, the right end of the inner cylinder channel is an outlet end, and the inner diameters of the inlet end and the outlet end are smaller than the inner diameter of the inner cylinder;

the heating pipeline is arranged in the cavity structure, two ends of the heating pipeline penetrate through the outer cylinder, and a plurality of holes are formed in the side wall of the inner cylinder;

the drying cylinder is arranged on the support plate through the support seat, the adjusting structure is arranged below the support plate, and the height of the drying cylinder can be adjusted through the adjusting structure.

Further, the adjusting structure comprises a lifting cylinder, a driving rod, a supporting plate, a buffer assembly and a sliding component, wherein the two lifting cylinders are arranged on the supporting plate, the driving rod on the lifting cylinder is connected with a supporting plate, the buffer assembly is arranged between the supporting plate and arranged between two groups of lifting cylinders, the two groups of sliding components are arranged at two ends of the supporting plate, and the supporting plate are in sliding connection through the sliding component.

Further, the sliding assembly comprises lifting blocks and connecting blocks, the four connecting blocks are arranged at four end corners of the supporting plate, a sliding groove is formed in each connecting block, one end of each lifting block is in sliding connection with the corresponding sliding groove, the other end of each lifting block is arranged on the supporting plate, and the lifting blocks can move up and down freely along the corresponding sliding grooves.

Further, the lifting block is of an L-shaped structure.

Further, the buffer assembly comprises a spring, an upper connecting column and a lower connecting column, wherein the upper end and the lower end of the spring are respectively arranged on the support plate and the support plate through the upper connecting column and the lower connecting column.

Further, the drying machine further comprises guide assemblies, wherein two groups of guide assemblies are arranged on the support plate, and the two groups of guide assemblies are symmetrically arranged on two sides of the drying cylinder.

Further, the guide assembly comprises a guide seat and a guide wheel, wherein the guide wheel is rotatably arranged on the guide seat, and the guide seat is arranged on the support plate.

Further, it still includes air exhauster, exhaust duct, fan and air inlet pipeline, the air exhauster passes through exhaust duct and cavity structure left end intercommunication, the fan passes through air inlet pipeline and cavity structure right-hand member intercommunication.

Further, the heating pipeline is internally provided with hot water or steam.

Further, an insulating layer is arranged on the outer wall of the outer cylinder.

The utility model has the advantages and beneficial effects that: the height of the drying cylinder can be adjusted through the adjusting structure so as to meet the requirement of the cooperation use of different cleaning equipment. The drying cylinder adopts a cylindrical structure formed by the inner cylinder and the outer cylinder, and compared with a drying box body commonly adopted in the prior art, the drying cylinder has the advantages of much smaller volume and less unnecessary waste of heat.

Drawings

FIG. 1 is a schematic diagram of a drying apparatus for flux-cored wire production according to the present utility model;

FIG. 2 is another angular schematic view of FIG. 1;

FIG. 3 is a rear view of FIG. 1;

FIG. 4 is an enlarged view of a portion of FIG. 3A;

FIG. 5 is a use state diagram of FIG. 1;

FIG. 6 is another angular schematic view of FIG. 5;

FIG. 7 is a schematic illustration of the disassembled structure of FIG. 5;

FIG. 8 is another angular schematic view of FIG. 7;

the support comprises a support seat 1, a support plate 2, an inner cylinder 3, an outer cylinder 4, an inlet end 5, an outlet end 6, a heating pipeline 7, a hole 8, a lifting cylinder 9, a driving rod 10, a support plate 11, a lifting block 12, a connecting block 13, a sliding chute 14, a spring 15, an upper connecting column 16, a lower connecting column 17, a guide seat 18, a guide wheel 19, an exhaust fan 20, an exhaust pipeline 21, a fan 22, an air inlet pipeline 23, heating equipment 24 and a steel belt 25.

Detailed Description

The following describes the embodiments of the present utility model further with reference to the drawings and examples. The following examples are only for more clearly illustrating the technical aspects of the present utility model, and are not intended to limit the scope of the present utility model.

As shown in fig. 1-8, a drying device for flux-cored wire production comprises a drying cylinder, a heating pipeline 7, an adjusting structure, a bracket seat 1 and a bracket plate 2,

the drying cylinder consists of an inner cylinder 3 and an outer cylinder 4, a cavity structure is formed by surrounding the inner cylinder 3 and the outer cylinder 4, a left-right through channel is arranged in the inner cylinder 3, the left end of the inner cylinder 3 channel is an inlet end 5, the right end of the inner cylinder 3 channel is an outlet end 6, and the inner diameters of the inlet end 5 and the outlet end 6 are smaller than the inner diameter of the inner cylinder 3;

the heating pipeline 7 is arranged in the cavity structure, two ends of the heating pipeline 7 penetrate through the outer cylinder 4, and a plurality of holes 8 are formed in the side wall of the inner cylinder 3;

the drying cylinder is arranged on the support plate 2 through the support seat 1, the adjusting structure is arranged below the support plate 2, and the height of the drying cylinder can be adjusted through the adjusting structure.

In the technical scheme, the height of the drying cylinder can be adjusted through the adjusting structure so as to meet the requirement of different cleaning equipment for cooperation. The drying cylinder adopts a cylindrical structure formed by the inner cylinder and the outer cylinder, and compared with a drying box body commonly adopted in the prior art, the drying cylinder has a much smaller volume, and unnecessary waste of heat is reduced; in addition, the left end of the inner cylinder 3 channel is an inlet end 5, the right end of the inner cylinder 3 channel is an outlet end 6, the inner diameters of the inlet end 5 and the outlet end 6 are smaller than the inner diameter of the inner cylinder 3, and heat dissipation from the inlet end and the outlet end can be reduced.

In addition, to further reduce heat dissipation, the inlet and outlet openings may be configured to be the same shape as the strip and sized slightly larger than the strip cross section.

The heating pipeline is arranged between the inner cylinder and the outer cylinder, flowing hot water or steam is arranged in the heating pipeline, and heat emitted by the heating pipeline is discharged into the inner cylinder through the holes, so that the steel belt is dried. In addition, the heating pipeline is coiled between the inner cylinder and the outer cylinder so as to increase the heating area.

As the preference of above-mentioned technical scheme, the regulation structure includes lift cylinder 9, actuating lever 10, backup pad 11, buffer assembly and slip subassembly, two lift cylinder 9 is installed in backup pad 11, actuating lever 10 on the lift cylinder 9 is connected with mounting plate 2, buffer assembly installs between backup pad 11 and mounting plate 2 and locates between two sets of lift cylinders, two sets of slip subassembly are installed in backup pad 11 both ends, just backup pad 11 passes through slip subassembly sliding connection with mounting plate 2.

In the technical scheme, the lifting cylinder drives the driving rod to drive the support plate above the driving rod to move up and down, so that the height of the drying cylinder is adjusted.

As a preferable mode of the above technical solution, the sliding assembly includes a lifting block 12 and a connecting block 13, four connecting blocks 13 are mounted at four end corners of the supporting plate 11, a sliding slot 14 is formed on the connecting block 13, one end of the lifting block 12 is slidingly connected in the sliding slot 14, the other end of the lifting block 12 is mounted on the supporting plate 2, and the lifting block 12 can move freely up and down along the sliding slot 14.

Preferably, the lifting block 12 has an L-shaped structure.

In the technical scheme, the lifting block can move up and down freely along the sliding groove.

As a preferable aspect of the foregoing disclosure, the buffer assembly includes a spring 15, an upper connecting post 16 and a lower connecting post 17, where the upper and lower ends of the spring 15 are respectively mounted on the support plate 2 and the support plate 11 through the upper connecting post 16 and the lower connecting post 17.

As the optimization of the technical scheme, the dryer further comprises two groups of guide assemblies which are arranged on the support plate 2, and the two groups of guide assemblies are symmetrically arranged on two sides of the dryer cylinder.

As a preferable mode of the above technical solution, the guide assembly includes a guide seat 18 and a guide wheel 19, the guide wheel 19 is rotatably mounted on the guide seat 18, and the guide seat 18 is mounted on the support plate 2.

As a preferable mode of the above technical solution, the air extractor further comprises an air extractor 20, an air extracting pipeline 21, a fan 22 and an air inlet pipeline 23, wherein the air extractor 20 is communicated with the left end of the cavity structure through the air extracting pipeline 21, and the fan 22 is communicated with the right end of the cavity structure through the air inlet pipeline 23.

A heating device 24 is arranged between the fan and the air inlet pipeline, and heaters with different powers can be selected according to practical application conditions.

In the technical scheme, the fan discharges hot air into the cavity structure between the inner cylinder and the outer cylinder through the heating equipment and the air inlet pipeline, and the hot air moves from one side close to the fan along the drying cylinder to one side close to the exhaust fan under the action of the exhaust fan, so that the drying of the steel belt is completed.

In actual use, the exhaust fan 20, the exhaust pipe 21, the fan 22, the air inlet pipe 23 and the heating device can dry the steel belt, and can also finish the drying of the steel belt together with the heating pipe. In addition, a partition plate can be arranged between the inner cylinder and the outer cylinder, the cavity structure is divided into a front part and a rear part, the front cavity structure is communicated with the air inlet pipeline, the rear cavity structure is communicated with the air exhaust pipeline, and heat passes through the hole in the inner cylinder from the front cavity structure and then flows to the rear cavity structure through the inner cylinder channel.

Preferably, the heating pipe 7 is internally provided with hot water or steam, and the hot water or steam enters from one end of the heating pipe and is discharged from the other end of the heating pipe. In the last process flow of drying, the steel belt is cleaned by water vapor, and in the drying process, the water vapor in the cleaning flow can be connected into a heating pipeline, so that the full utilization of energy sources is realized.

As a preferable mode of the above technical scheme, an insulating layer is provided on the outer wall of the outer cylinder 4.

The foregoing is merely a preferred embodiment of the present utility model, and it should be noted that it will be apparent to those skilled in the art that several modifications and variations can be made without departing from the technical principle of the present utility model, and these modifications and variations should also be regarded as the scope of the utility model.

Claims (10)

1. The drying equipment for the production of the flux-cored wire is characterized by comprising a drying cylinder, a heating pipeline (7), an adjusting structure, a bracket seat (1) and a bracket plate (2),

the drying cylinder consists of an inner cylinder (3) and an outer cylinder (4), a cavity structure is formed by surrounding the inner cylinder (3) and the outer cylinder (4), a left-right through channel is arranged in the inner cylinder (3), the left end of the inner cylinder (3) channel is an inlet end (5), the right end of the inner cylinder (3) channel is an outlet end (6), and the inner diameters of the inlet end (5) and the outlet end (6) are smaller than the inner diameter of the inner cylinder (3);

the heating pipeline (7) is arranged in the cavity structure, two ends of the heating pipeline (7) penetrate through the outer cylinder (4), and a plurality of holes (8) are formed in the side wall of the inner cylinder (3);

the drying cylinder is arranged on the support plate (2) through the support seat (1), the adjusting structure is arranged below the support plate (2), and the height of the drying cylinder can be adjusted through the adjusting structure.

2. The drying equipment for flux-cored wire production according to claim 1, wherein the adjusting structure comprises a lifting cylinder (9), a driving rod (10), a supporting plate (11), a buffer assembly and a sliding assembly, wherein two lifting cylinders (9) are installed on the supporting plate (11), the driving rod (10) on the lifting cylinder (9) is connected with a supporting plate (2), the buffer assembly is installed between the supporting plate (11) and the supporting plate (2) and arranged between two groups of lifting cylinders, two groups of sliding assemblies are installed at two ends of the supporting plate (11), and the supporting plate (11) and the supporting plate (2) are in sliding connection through the sliding assembly.

3. The drying equipment for flux-cored wire production according to claim 2, wherein the sliding component comprises a lifting block (12) and a connecting block (13), the four connecting blocks (13) are arranged at four end corners of the supporting plate (11), a sliding groove (14) is formed in the connecting block (13), one end of the lifting block (12) is in sliding connection with the sliding groove (14), the other end of the lifting block (12) is arranged on the supporting plate (2), and the lifting block (12) can move up and down freely along the sliding groove (14).

4. A drying apparatus for flux-cored wire production according to claim 3, wherein the lifting block (12) has an L-shaped structure.

5. The drying equipment for flux-cored wire production according to claim 2, wherein the buffer assembly comprises a spring (15), an upper connecting column (16) and a lower connecting column (17), and the upper end and the lower end of the spring (15) are respectively arranged on the support plate (2) and the support plate (11) through the upper connecting column (16) and the lower connecting column (17).

6. The drying equipment for flux-cored wire production according to claim 1, further comprising guide assemblies, wherein two groups of the guide assemblies are mounted on a support plate (2), and the two groups of the guide assemblies are symmetrically mounted on two sides of the drying cylinder.

7. The drying equipment for flux-cored wire production according to claim 6, wherein the guide assembly comprises a guide seat (18) and a guide wheel (19), the guide wheel (19) is rotatably mounted on the guide seat (18), and the guide seat (18) is mounted on the support plate (2).

8. The drying equipment for flux-cored wire production according to claim 1, further comprising an exhaust fan (20), an exhaust pipe (21), a fan (22) and an air inlet pipe (23), wherein the exhaust fan (20) is communicated with the left end of the cavity structure through the exhaust pipe (21), and the fan (22) is communicated with the right end of the cavity structure through the air inlet pipe (23).

9. The drying equipment for flux-cored wire production according to claim 1, characterized in that the heating pipeline (7) is internally provided with hot water or steam.

10. The drying equipment for flux-cored wire production according to claim 1, wherein an insulating layer is arranged on the outer wall of the outer cylinder (4).

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