CN110832595B - Anti-skid foot pad, terminal and method for manufacturing anti-skid foot pad on terminal - Google Patents

Abstract

An anti-skid foot pad (200), a terminal and a method for manufacturing the anti-skid foot pad (200) on the terminal are provided, wherein the anti-skid foot pad (200) comprises a base layer (1), a texture layer (2) is formed on the first surface of the base layer (1), and a rubber ink layer (3) covers one side, far away from the base layer (1), of the texture layer (2); the terminal comprises a terminal shell, wherein the terminal shell comprises a placing surface (100), and an anti-skid foot pad (200) is arranged on the placing surface (100).

Description

Anti-skid foot pad, terminal and method for manufacturing anti-skid foot pad on terminal

The present application claims priority from the chinese patent application filed on 14/05/2018 under the name of "an anti-slip foot pad and method for making the same", by the chinese patent office, application No. 201810457658.3, the entire contents of which are incorporated herein by reference.

Technical Field

The application relates to the technical field of terminals, in particular to an anti-skidding foot pad, a terminal and a method for manufacturing the anti-skidding foot pad on the terminal.

Background

With the rapid development of internet and smart phone applications in recent years, desktop electronic terminal products represented by wireless routers are becoming more and more popular. Desktop electronic terminal products are usually placed on a desktop for use, so in order to prevent the desktop electronic terminal products from slipping off, anti-slip foot pads are usually arranged on the bottom surface of the terminal products, so that the friction force between the terminal products and the desktop is increased, and an anti-slip effect is achieved.

A desktop router product of prior art is shown in fig. 1, is equipped with callus on the sole mounting groove 02 on the shell bottom surface 01 of router, and it has silica gel callus on the sole 03 to bond in callus on the sole mounting groove 02, through the contact of silica gel callus on the sole 03 with the desktop to increase the frictional force between router and the desktop, reach skid-proof effect.

However, because the silica gel callus on the sole 03 bonds in callus on the sole mounting groove 02, this technology adopts manual work usually, and production efficiency is lower, is unfavorable for mass production, uses a period of time after moreover, and the adhesion between silica gel callus on the sole 03 and the mounting groove 02 can weaken gradually, and the silica gel callus on the sole 03 drops easily under the effect of frictional force. And the cost of the desktop electronic terminal product is increased due to the higher cost of the raw material of the silica gel.

Disclosure of Invention

The embodiment of the application provides an anti-skidding callus on sole, terminal and method of making anti-skidding callus on sole on terminal, when reaching anti-skidding effect, has solved the unstable, lower, the with high costs problem of production efficiency of current silica gel callus on sole installation.

In order to achieve the above purpose, the embodiment of the present application adopts the following technical solutions:

in a first aspect, the present application provides an anti-skidding foot mat, including the basic unit, the first surface of basic unit is formed with the texture layer, the texture layer is kept away from one side of basic unit covers there is the rubber ink layer.

The anti-skidding callus on sole that this application embodiment provided because keep away from on the texture layer one side of basic unit is equipped with rubber printing ink layer, and rubber printing ink layer has certain elasticity, and coefficient of friction is great, consequently can increase the frictional force between terminal product and the desktop, reaches skid-proof effect. And because the initial state of the rubber paint ink is liquid, the rubber paint ink is directly printed or sprayed on the texture layer, the production efficiency is high, the cost is low, the rubber paint ink is not easy to fall off, the texture layer can increase the adhesive force of the rubber ink layer, and the rubber ink layer is prevented from falling off, and the rubber ink layer also has the characteristics of strong adhesive force, good leveling property, good glossiness, soft ink layer, high drying speed, good rebound resilience, no crack and the like.

In a possible implementation manner, one side of the texture layer, which is far away from the base layer, is covered with multiple rubber ink layers, and the thicknesses of the multiple rubber ink layers are approximately the same. Therefore, bubbles can be prevented from being generated to the maximum extent and ink can be prevented from being accumulated locally.

In a possible implementation mode, the texture layer is far away from one side of the base layer is sequentially covered with a first rubber ink layer, a second rubber ink layer and a third rubber ink layer, and the sum of the thicknesses of the first rubber ink layer, the second rubber ink layer and the third rubber ink layer is 10-15 micrometers.

In a possible implementation, the material of the base layer is plastic. Therefore, the plastic shell can be integrally formed with the plastic shell of the terminal product, and the manufacturing process is simplified.

In a possible implementation, the rubber ink layer is formed on the texture layer by a screen printing process. The screen printing has the advantages of low cost, high efficiency, strong ink layer adhesion, convenience in controlling the covering thickness of the rubber ink layer and the like.

In a possible implementation, the texture layer is formed by an electric spark process or a chemical etching process.

In a second aspect, the present application further provides a terminal, which includes a terminal housing, wherein the terminal housing includes a placement surface, and the placement surface is provided with the anti-slip foot pad of the first aspect.

The terminal that this application embodiment provided, because the texture layer of anti-skidding callus on the sole is kept away from one side of basic unit is equipped with the rubber printing ink layer, and the rubber printing ink layer has certain elasticity, and coefficient of friction is great, consequently when the face of placing at terminal places on the desktop, the frictional force between anti-skidding callus on the sole can increase terminal product and the desktop reaches skid-proof effect. And because the initial state of the rubber paint ink is liquid, the rubber paint ink is directly printed or sprayed on the texture layer, the production efficiency is high, the cost is low, the rubber paint ink is not easy to fall off, the texture layer can increase the adhesive force of the rubber ink layer, and the rubber ink layer is prevented from falling off, and the rubber ink layer also has the characteristics of strong adhesive force, good leveling property, good glossiness, soft ink layer, high drying speed, good rebound resilience, no crack and the like.

In a possible implementation manner of the second aspect, the base layer of the anti-slip foot pad is integrally formed with the terminal housing. This manufacturing process is simple, and the anti-skidding callus on the sole can not drop.

In a possible implementation manner of the second aspect, a plurality of the anti-skid foot pads are arranged on the placing surface. This increases the anti-skid friction force.

In a third aspect, the present application further provides a method for manufacturing an anti-slip foot pad on a terminal, including the following steps:

forming a bulge on the placing surface of the terminal shell, wherein the bulge is a base layer of the anti-skidding foot pad;

forming a texture layer on the surface of the base layer;

and covering a rubber ink layer on the texture layer.

According to the method for manufacturing the anti-skidding foot pad on the terminal, the rubber ink layer has certain elasticity, and the friction coefficient is large, so that the friction force between a terminal product and a desktop can be increased, and the anti-skidding effect is achieved. The method has high production efficiency and low cost, and the formed rubber ink layer is not easy to fall off.

In a possible implementation manner of the third aspect, the forming of the base layer of the anti-slip foot pad on the placing surface of the terminal housing includes: and integrally forming the terminal shell and the base layer of the anti-skidding foot pad through an injection molding process.

In a possible implementation manner of the third aspect, the forming of the texture layer on the surface of the base layer includes: the texture layer is formed by performing an electric spark or chemical etching process on the surface of the base layer.

In a possible implementation manner of the third aspect, the covering of the rubber ink layer on the texture layer includes: and sequentially printing a plurality of rubber ink layers on the texture layer by a printing process. The layered printing can facilitate the whole rubber ink layer to be dried completely, so that the rubber ink layer is not easy to fall off.

In a possible implementation manner of the third aspect, printing a plurality of rubber ink layers on the texture layer includes: printing a first rubber ink layer on the texture layer; printing a second rubber ink layer on the first rubber ink layer, wherein the thickness of the second rubber ink layer is equal to that of the first rubber ink layer; and printing a third rubber ink layer on the second rubber ink layer, wherein the thickness of the third rubber ink layer is equal to that of the second rubber ink layer. The method can avoid bubble generation and ink accumulation to the maximum extent.

In a possible implementation manner of the third aspect, the sum of the thicknesses of the first rubber ink layer, the second rubber ink layer and the third rubber ink layer is 10-15 micrometers.

In a possible implementation of the third aspect, the printing process is a screen printing process. The screen printing process has low manufacturing cost, high efficiency, strong adhesive force of the ink layer and convenient control of the covering thickness of the rubber ink layer.

Drawings

FIG. 1 is a schematic diagram of a desktop router product according to the prior art;

FIG. 2 is a schematic structural view of an anti-slip footpad in an embodiment of the present application;

fig. 3 is a schematic structural diagram of a terminal according to an embodiment of the present application.

Detailed Description

In a first aspect, as shown in fig. 2, an embodiment of the present application provides an anti-slip foot pad, which includes a base layer 1, a texture layer 2 is formed on a first surface of the base layer 1, and a rubber ink layer 3 covers a side of the texture layer 2 away from the base layer 1.

The anti-skidding callus on sole that this application embodiment provided because keep away from at texture layer 2 one side of basic unit 1 is equipped with rubber printing ink layer 3, and rubber printing ink layer 3 has certain elasticity, and coefficient of friction is great, consequently can increase the frictional force between terminal product and the desktop, reaches skid-proof effect. And because the initial state of the rubber paint ink is liquid, the rubber paint ink is directly printed or sprayed on the texture layer 2, the production efficiency is high, the cost is low, and the rubber paint ink is not easy to fall off, the texture layer 2 can increase the adhesive force of the rubber ink layer 3, and the falling off of the rubber ink layer 3 is prevented. And the rubber ink layer 3 also has the characteristics of strong adhesive force, good leveling property, good glossiness, soft ink layer, high drying speed, good rebound resilience, no crack and the like.

The rubber ink is a printing ink prepared from resin with excellent hydrophobicity and high-quality pigment and filler. The rubber ink layer 3 may be formed on the texture layer 2 by a screen printing process. The silk screen printing refers to that a silk screen is used as a plate base, and a silk screen printing plate with pictures and texts is manufactured by a photosensitive plate making method. The screen printing utilizes the basic principle that the meshes of the image-text part and the non-image-text part of the screen printing plate can be permeable to ink and can not be permeable to ink to carry out printing. When printing, ink is poured into one end of the screen printing plate, a scraper plate is used for applying a certain pressure to the ink position on the screen printing plate, meanwhile, the scraper plate moves towards the other end of the screen printing plate at a constant speed, and the ink is extruded onto a printing stock from meshes of the image-text part by the scraper plate in the moving process. The screen printing has the advantages of low cost, high efficiency, strong ink layer adhesive force, convenience in controlling the covering thickness of the rubber ink layer 3 and the like. When screen printing is carried out, the mesh of the screen printing plate can be selected to be 39 meshes, and the rubber ink layer 3 formed by printing with the 39-mesh screen printing plate has better adhesion. In addition, the rubber ink layer 3 may be manufactured by a pad printing process, a spraying process, or the like.

In fabricating the texture layer 2, the texture layer 2 may be formed by an electric spark process or a chemical etching process. The texture layer 2 can increase the roughness of the surface of the base layer 1, thereby increasing the adhesion of the rubber ink layer 3.

Wherein, rubber ink layer 3 can print one deck or multilayer, and the number of piles is more, and the antiskid effect is better, and under the same circumstances of gross thickness, once prints thick rubber ink layer 3 and compares with the scheme of layering printing, and the layering printing can be convenient for 3 whole quick dryings on rubber ink layer, makes rubber ink layer 3 be difficult for droing.

If the thick rubber ink layer 3 is printed at a time, bubbles are likely to occur in the rubber ink layer 3, and ink may be locally accumulated, resulting in uneven foot pad. Therefore, the thicknesses of the plurality of rubber ink layers 3 can be set to be substantially the same, thereby preventing the generation of bubbles and the local accumulation of ink to the maximum.

In a possible implementation manner, as shown in fig. 2, a first rubber ink layer 31, a second rubber ink layer 32 and a third rubber ink layer 33 may be sequentially printed on one side of the texture layer 2 away from the base layer 1, the thicknesses of the first rubber ink layer 31, the second rubber ink layer 32 and the third rubber ink layer 33 are all approximately 3 to 5 micrometers, and the sum of the thicknesses of the first rubber ink layer 31, the second rubber ink layer 32 and the third rubber ink layer 33 is approximately 10 to 15 micrometers. If the number of piles of rubber ink layer 3 is too few then the antiskid effect is relatively poor, if the number of piles of rubber ink layer 3 is too many then can lead to with high costs, can influence appearance quality moreover, consequently, when the above-mentioned scope is selected respectively to the thickness of selecting three-layer and three-layer as rubber ink layer 3, both can guarantee the antiskid effect, again can reasonable control cost, guarantee appearance quality.

In order to further explain the anti-skidding effect of the anti-skidding foot pad, the anti-skidding effect of the anti-skidding foot pad is compared with that of the silica gel foot pad and the plastic foot pad respectively through a thrust test, specifically, three terminal products with the same weight can be placed on a desktop made of the same material, the terminal products are pushed horizontally slowly by a thrust meter, the maximum thrust in the pushing process is recorded, each product is pushed three times, and the average value is taken. The thrust test results are shown in table 1:

TABLE 1

As can be seen from table 1, the plastics callus on the sole does not have anti-skidding effect basically, and the silica gel callus on the sole can satisfy basic anti-skidding requirement, and the anti-skidding effect of the anti-skidding callus on the sole that this application embodiment provided is best.

The material of the base layer 1 can be the same as that of the shell of the terminal product, and the shell of the terminal product is usually made of plastic, so that the material of the base layer 1 can be plastic, and the base layer and the plastic shell of the terminal product can be integrally formed, so that the manufacturing process is simplified.

In a second aspect, the present application further provides a terminal, which includes a terminal housing, as shown in fig. 3, the terminal housing includes a placing surface 100, the terminal is placed on a carrying object (such as a desktop, a table top, etc.) through the placing surface 100, and the placing surface 100 is provided with the anti-skid foot pad 200 according to any one of the above embodiments.

The terminal that this application embodiment provided, because texture layer 2 of anti-skidding callus on sole 200 keeps away from one side of basic unit 1 is equipped with rubber printing ink layer 3, and rubber printing ink layer 3 has certain elasticity, and coefficient of friction is great, consequently when the face of placing at terminal places on the desktop, the frictional force between anti-skidding callus on the sole can increase terminal product and the desktop reaches skid-proof effect. And because the initial state of the rubber paint ink is liquid, the rubber paint ink is directly printed or sprayed on the texture layer 2, the production efficiency is high, the cost is low, the rubber paint ink is not easy to fall off, the texture layer 2 can increase the adhesive force of the rubber ink layer 3, the rubber ink layer 3 is prevented from falling off, and the rubber ink layer 3 also has the characteristics of strong adhesive force, good leveling property, good glossiness, soft ink layer, high drying speed, good rebound resilience, no crack and the like.

Wherein, the base layer 1 of the anti-skid foot pad and the terminal shell are integrally formed. From this, the basic unit 1 of anti-skidding callus on the sole is equivalent to the arch that forms on the face of placing of terminal shell, only needs to form texture layer 2 in the arch to the preparation of anti-skidding callus on the sole can be accomplished to printing rubber ink layer 3 on texture layer 2, and the preparation process is simple, and the anti-skidding callus on the sole can not drop.

In order to increase the anti-slip friction force, a plurality of anti-slip mats may be disposed on the placing surface, and in addition, in order to make the anti-slip friction force uniformly distributed on the placing surface, the plurality of anti-slip mats may be uniformly distributed in a dispersed manner, for example, as shown in fig. 3, the anti-slip mats may be respectively disposed at four corners of the placing surface.

It should be noted that: the terminal in the embodiment of the present application may be a router, a computer, a Point of sale (POS) terminal, and other terminal products that can be placed on a desktop, which is not limited herein.

In a third aspect, the present application further provides a method for manufacturing an anti-slip foot pad on a terminal, including the following steps:

forming a bulge on the placing surface of the terminal shell, wherein the bulge is a base layer 1 of the anti-skidding foot pad;

forming a texture layer 2 on the surface of the base layer 1;

a layer of rubber ink 3 is provided on the textured layer 2.

According to the method for manufacturing the anti-skidding foot pad on the terminal, the bulge is formed on the placing surface, the texture layer 2 is formed on the bulge, and finally the rubber ink layer 3 is printed on the texture layer 2. Because rubber ink layer 3 has certain elasticity, and coefficient of friction is great, consequently can increase the frictional force between terminal product and the desktop, reaches skid-proof effect. The method has high production efficiency and low cost, and the formed rubber ink layer 3 is not easy to fall off.

After the printing of the rubber ink layer 3 is completed, the rubber ink layer 3 can be quickly dried by a drying device such as an oven in order to quickly dry and solidify the rubber ink layer 3. Or dried in the sun or air in the natural state, which is not limited herein.

Specifically, the protrusion may be formed on the placing surface of the terminal housing through an injection molding process.

There are various options for forming the texture layer 2 on the surface of the base layer 1, for example, the texture layer 2 may be formed on the surface of the base layer 1 by an electric spark or chemical etching process.

The rubber ink layer 3 can be manufactured through a printing process or a spraying process, when the printing process is adopted, a plurality of layers of the rubber ink layers 3 can be sequentially printed on the texture layer 2, and compared with a method for printing the thicker rubber ink layer 3 at one time, the rubber ink layer 3 can be conveniently and integrally and quickly dried through layered printing, so that the rubber ink layer 3 is not easy to fall off.

For example, three rubber ink layers 3 may be printed on the texture layer 2 in sequence, including the following steps:

printing a first rubber ink layer 31 on the texture layer 2;

printing a second rubber ink layer 32 on the first rubber ink layer 31, wherein the thickness of the second rubber ink layer 32 is equal to that of the first rubber ink layer 31;

and printing a third rubber ink layer 33 on the second rubber ink layer 32, wherein the thickness of the third rubber ink layer 33 is equal to that of the second rubber ink layer 32.

The three rubber ink layers are sequentially printed on the texture layer 2 by the method, and the three rubber ink layers are the same in thickness, so that bubbles and ink accumulation can be avoided to the maximum extent.

In a possible implementation manner, the thicknesses of the first rubber ink layer 31, the second rubber ink layer 32 and the third rubber ink layer 33 are all approximately 3 to 5 micrometers, and the sum of the thicknesses of the first rubber ink layer 31, the second rubber ink layer 32 and the third rubber ink layer 33 is about 10 to 15 micrometers.

The process for printing the rubber ink layer can be a screen printing process or a transfer printing process and the like, and when the screen printing process is adopted for printing the rubber ink layer, the manufacturing cost is low, the efficiency is high, the adhesive force of the ink layer is strong, and the coverage thickness of the rubber ink layer can be conveniently controlled.

The above description is only for the specific embodiments of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can easily conceive of the changes or substitutions within the technical scope of the present invention, and all the changes or substitutions should be covered within the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the appended claims.

Claims (11)

1. The anti-skidding foot pad is characterized by comprising a base layer, wherein a texture layer is formed on the first surface of the base layer, and a rubber ink layer covers one side, far away from the base layer, of the texture layer;

the texture layer is used for increasing the adhesive force of the rubber ink layer;

the rubber ink layer at least comprises three layers, and the rubber ink layer is formed on the texture layer through layered printing;

at least three rubber ink layers are covered on one side of the texture layer, which is far away from the base layer, and the thicknesses of the at least three rubber ink layers are the same;

the texture layer is kept away from one side of the base layer is sequentially covered with a first rubber ink layer, a second rubber ink layer and a third rubber ink layer, and the sum of the thicknesses of the first rubber ink layer, the second rubber ink layer and the third rubber ink layer is 10-15 micrometers.

2. The anti-slip footpad of claim 1, wherein the base layer is formed of plastic.

3. The anti-slip foot pad according to any one of claims 1 to 2, wherein the rubber ink layer is formed on the texture layer by a screen printing process.

4. The non-slip footpad of any one of claims 1 to 2, wherein the texture layer is formed by an electric spark process or a chemical etching process.

5. A terminal, characterized by comprising a terminal shell, wherein the terminal shell comprises a placing surface, and the placing surface is provided with the anti-skid foot pad of any one of claims 1-4.

6. A terminal as claimed in claim 5, wherein the base layer of the anti-slip foot pad is integrally formed with the terminal housing.

7. A terminal according to claim 5 or 6, wherein a plurality of said anti-slip footpads are provided on said resting surface.

8. A method for manufacturing an anti-skidding foot pad on a terminal is characterized by comprising the following steps:

forming a bulge on the placing surface of the terminal shell, wherein the bulge is a base layer of the anti-skidding foot pad;

forming a texture layer on the surface of the base layer;

covering a rubber ink layer on the texture layer;

the texture layer is used for increasing the adhesive force of the rubber ink layer;

the rubber ink layer at least comprises three layers, and the rubber ink layer is formed on the texture layer through layered printing;

the covering of the rubber ink layer on the texture layer comprises the following steps:

sequentially printing at least three rubber ink layers on the texture layer by a printing process, wherein the at least three rubber ink layers have the same thickness;

printing at least three rubber ink layers on the texture layer, wherein the at least three rubber ink layers comprise:

printing a first rubber ink layer on the texture layer; printing a second rubber ink layer on the first rubber ink layer; printing a third rubber ink layer on the second rubber ink layer; the sum of the thicknesses of the first rubber ink layer, the second rubber ink layer and the third rubber ink layer is 10-15 microns.

9. The method of forming an anti-slip footpad in a terminal according to claim 8, wherein the forming of the projection on the mounting surface of the terminal housing comprises:

the projection is formed on the placing face of the terminal housing by an injection molding process.

10. The method of making a slip-resistant footbed on a terminal end of claim 8, wherein forming a textured layer on a surface of the base layer comprises:

the texture layer is formed by performing an electric spark or chemical etching process on the surface of the base layer.

11. The method for manufacturing an anti-slip foot pad on a terminal according to any one of claims 9 to 10, wherein the printing process is a screen printing process.

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