CN105921375B - Soaking size applicator - Google Patents

Abstract

The invention relates to a uniform heat gluing device, comprising: a heat radiation cylinder cover, and a heat uniform guide column coaxially arranged in the heat radiation cylinder cover, and a powder nozzle located outside one end of the heat uniform guide column , the heat radiation tube cover includes an inner tube cover and an outer tube cover with inner and outer layers, an electric heating wire is wound in the gap between the inner tube cover and the outer tube cover, and the circumference of the middle part of the heat equalizing column There is an inward concave arc structure. The electric heating wire surrounding the outer circumference of the heat-spreading column can heat the side of the heat-spreading column, and then transfer the heat to the bottom of the conduction tank through the good thermal conductivity of the heat-spreading column, which can form an indirect and uniform transfer of heat, and the heat The division is more even and soft. The polymer powder particles are sprayed out through the powder nozzle, and the substrate itself in the holding tank is melted by the high temperature polymer powder particles that can quickly contact the surface, so that the polymer powder particles adhere and adhere to the substrate. A film layer is formed on the surface.

Description

Uniform heat sizing device

technical field

The invention relates to glue sizing equipment, in particular to a uniform heat glue sizing device.

Background technique

When baking and sizing planar parts, a heat source plane with basically controllable temperature is required to ensure that the heat obtained by each area in the plane on the part is basically controlled within a certain range, so that the baking and sizing effect of the plane can be achieved. Meet distribution requirements.

Contents of the invention

The invention overcomes the disadvantages of the prior art and provides a uniform heat gluing device with a simple structure.

In order to achieve the above purpose, the technical solution adopted by the present invention is: a uniform heat gluing device, comprising: a heat radiation cover, and a heat equalization guide column coaxially arranged in the heat radiation cover, characterized in that, It also includes a powder nozzle located on the outside of one end of the heat-spreading guide post, and the heat radiation cover includes an inner cover and an outer cover with inner and outer layers, and the gap between the inner cover and the outer cover is An electric heating wire is wound, and an inward concave arc-shaped structure is provided in the circumferential direction of the middle part of the heat-spreading guide column.

In a preferred embodiment of the present invention, an accommodating groove is provided on the end surface of one end of the heat-spreading guide column, and the other end is connected with an adjusting rod.

In a preferred embodiment of the present invention, the adjusting rod is an adjusting screw, and the adjusting screw is arranged in a screw hole of an end cover of the heat radiation cylinder cover.

In a preferred embodiment of the present invention, the winding density of the heating wire at the middle of the heat-spreading pillar is greater than the winding density of the heating wire at the end of the heat-spreading pillar.

In a preferred embodiment of the present invention, the inner cylinder cover is made of transparent quartz material.

In a preferred embodiment of the present invention, the outer cylinder cover is made of opaque thermal insulation material.

In a preferred embodiment of the present invention, the heat spreader column is made of graphite or metal.

In a preferred embodiment of the present invention, the heat-spreading guide column is a rotator structure, and the heat radiation cover is a cylindrical structure.

The present invention solves the defects in the background technology. The present invention has the following beneficial effects: the electric heating wire surrounding the outer circumference of the heat-spreading pillar can heat the side circumference of the heat-spreading pillar, and then transfer the heat through the good thermal conductivity of the heat-spreading pillar. It is transmitted to the bottom surface of the conduction and storage tank, so that the indirect and uniform heat transfer can be formed, and the heat distribution is more uniform and soft.

The polymer powder particles are sprayed out through the powder nozzle, and the substrate itself in the holding tank is melted by the high temperature polymer powder particles that can quickly contact the surface, so that the polymer powder particles adhere and adhere to the substrate. A film layer is formed on the surface.

The inwardly concave arc-shaped structure of the heat-spreading column ensures that the heat-receiving ability of the heat-spreading column close to the axial center is improved, thereby reducing the temperature difference between the edge of the accommodating tank and the center of the bottom surface of the accommodating tank.

By adjusting the winding density of the heating wire along the axial direction of the heat-spreading guide column, the heating wire at the corresponding position of the inward concave arc structure of the heat-spreading guide column is denser, and the center part of the bottom surface of the accommodating tank is compensated as much as possible. The heat reduces the temperature difference between the edge of the accommodating tank and the center of the bottom surface of the accommodating tank.

Adjusting the screw can adjust the axial position of the heat-spreading guide column relative to the heat radiation tube cover, and can adjust the transformation of the density of the heating wire at the corresponding position of the inwardly concave arc structure of the heat-spreading guide post, so as to fine-tune the above-mentioned temperature difference.

Through the control of the adjusting rod, the base material in the holding tank can form a concentric temperature distribution. Due to the temperature difference distribution of this structure, it can form a circular distribution of polymer powder particles, that is, the middle adhesive film layer is thin, and the edge adhesive Substrate sizing structure with thick film layers.

Description of drawings

Below in conjunction with accompanying drawing and embodiment the present invention is further described;

Fig. 1 is the structural representation of the preferred embodiment of the present invention;

In the figure: 1. Inner cylinder cover, 2. Outer cylinder cover, 3. Heating guide column, 4. Arc structure, 5. Heating wire, 6. Adjusting screw, 7. End cover, 8. Accommodating tank, 9 , powder nozzle, 10, base material.

Detailed ways

The present invention will now be further described in detail in conjunction with the accompanying drawings and embodiments. These drawings are all simplified schematic diagrams, only illustrating the basic structure of the present invention in a schematic manner, so it only shows the composition related to the present invention.

As shown in Figure 1, a heat-spreading device includes: a heat-radiating tube cover, and a heat-spreading guide column coaxially arranged in the heat-radiating tube cover, and a powder nozzle located outside one end of the heat-spreading guide post, The heat radiation cylinder cover includes inner and outer two-layer inner cylinder cover and outer cylinder cover. The electric heating wire is wound in the gap between the inner cylinder cover and the outer cylinder cover. shaped structure.

The electric heating wire around the outer circumference of the heat-spreading column can heat the side of the heat-spreading column, and then transfer the heat to the bottom surface of the conduction tank through the good thermal conductivity of the heat-spreading column, which can form an indirect and uniform transfer of heat, and the heat The division is more even and soft.

The polymer powder particles are sprayed out through the powder nozzle, and the substrate itself in the holding tank is melted by the high temperature polymer powder particles that can quickly contact the surface, so that the polymer powder particles adhere and adhere to the substrate. A film layer is formed on the surface.

The inwardly concave arc-shaped structure of the heat-spreading column ensures that the heat-receiving ability of the heat-spreading column close to the axial center is improved, thereby reducing the temperature difference between the edge of the accommodating tank and the center of the bottom surface of the accommodating tank.

An accommodating groove is arranged on the end surface of one end of the heat-spreading guide column, and the other end is connected with an adjusting rod, which is an adjusting screw, and the adjusting screw is arranged in a screw hole of an end cover of the heat radiation tube cover. Adjusting the screw can adjust the axial position of the heat-spreading guide column relative to the heat radiation tube cover, and can adjust the transformation of the density of the heating wire at the corresponding position of the inwardly concave arc structure of the heat-spreading guide post, so as to fine-tune the above-mentioned temperature difference. Through the control of the adjusting rod, the base material in the holding tank can form a concentric temperature distribution. Due to the temperature difference distribution of this structure, it can form a circular distribution of polymer powder particles, that is, the middle adhesive film layer is thin, and the edge adhesive Substrate sizing structure with thick film layers.

The winding density of the electric heating wire in the middle of the heat-spreading pillar is greater than the winding density of the electric heating wire at the end of the heat-spreading pillar. By adjusting the winding density of the heating wire along the axial direction of the heat-spreading guide column, the heating wire at the corresponding position of the inward concave arc structure of the heat-spreading guide column is denser, and the center part of the bottom surface of the accommodating tank is compensated as much as possible. The heat reduces the temperature difference between the edge of the accommodating tank and the center of the bottom surface of the accommodating tank.

The inner cylinder cover is made of transparent quartz material, the outer cylinder cover is made of opaque thermal insulation material, and the heat-spreading column is made of graphite or metal.

The uniform heat guide column is a rotary structure, and the heat radiation tube cover is a cylindrical structure.

The above is inspired by the ideal embodiment of the present invention. Through the above description, relevant personnel can make various changes and modifications within the scope of not departing from the technical idea of the present invention. The technical scope of the present invention is not limited to the content in the specification, and must be determined according to the scope of the claims.

Claims (5)

1. a kind of soaking size applicator, including：Heat radiation barrel cover, and the equal thermal conductivity that is co-axially located in the heat radiation barrel cover Column, which is characterized in that further include the powder mouth being located on the outside of soaking guide post one end, the heat radiation barrel cover includes inside and outside two layers Interior barrel cover and outer barrel cover, be wound with heating wire, the soaking guide post in the gap between the interior barrel cover and the outer barrel cover Middle part is circumferentially provided with the arcuate structure inwardly concaved；Storage tank, the other end are set on the end face of soaking guide post one end Connect adjusting rod；Winding number of turns density of the heating wire in the middle part of soaking guide post is more than the heating wire in soaking guide post end Winding number of turns density；The adjusting rod is adjusting screw rod, and the spiral shell in one end cap of heat radiation barrel cover is arranged in the adjusting screw rod In hole.

2. soaking size applicator according to claim 1, it is characterised in that：The interior barrel cover is transparent quartz material.

3. soaking size applicator according to claim 1, it is characterised in that：The outer barrel cover is opaque thermal insulating material Material.

4. soaking size applicator according to claim 1, it is characterised in that：The soaking guide post is graphite material or metal Material.

5. soaking size applicator according to claim 1, it is characterised in that：The soaking guide post is rotary structure, institute It is cylindrical structure to state heat radiation barrel cover.