Negative pressure driven sucking disc for annular wedge-shaped microstructure and preparation method of negative pressure driven sucking disc

Abstract

Disclosed are a negative pressure driven sucking apparatus and a preparation method thereof. The sucking apparatus comprises a sucking disc body, wherein a negative pressure cavity is formed in the middle of the sucking disc body, and the negative pressure cavity is connected with a vacuum line, and the bottom of the negative pressure cavity having a flexible section, and an annular wedge-shaped microstructure is formed at the bottom of the body surrounding the flexible section. Stable loading and release processes of the annular wedge-shaped microstructure are realized.

Claims

1. A negative pressure driven sucking apparatus, comprising: a sucking disc body including a cavity being connected with a vacuum line for generating a negative pressure in the cavity, a floor of the cavity forming a part of a bottom of the sucking disc body, the floor of the cavity having a flexible section and the floor having a sealing and fixed connection with an inner wall of the sucking disc body while the negative pressure is generated in the cavity; and an annular wedge-shaped microstructure formed on the bottom of the sucking disc body surrounding the flexible section.

2. The negative pressure driven sucking apparatus according to claim 1, wherein the sucking disc body is cylindrical, the bottom has a circular ring surface, and the cavity is a cylindrical cavity.

3. The negative pressure driven sucking apparatus according to claim 1, wherein the annular wedge-shaped microstructure comprises multiple circles of micro wedge-shaped structures, the multiple circles of micro wedge-shaped structures are distributed in an annular array mode, and each circle of micro wedge-shaped structures is provided with multiple micro wedge-shaped structures.

4. The negative pressure driven sucking apparatus according to claim 3, wherein the micro wedge-shaped structure comprises a first inclined plane and a second inclined plane, and the bottom of the first inclined plane is connected with the bottom of the second inclined plane to form a protruding tip; the included angle between the first inclined plane and the vertical plane ranges from 50° to 80°, the included angle between the second inclined plane and the vertical plane ranges from 20° to 60°, and the height of the single micro wedge-shaped structure in the vertical direction ranges from 40 to 200 microns.

5. The negative pressure driven sucking apparatus according to claim 4, wherein a groove is formed between every two adjacent circles of micro wedge-shaped structures, the adjacent circles of micro wedge-shaped structures are sequentially connected, or a spacing of 30-100 microns between every two adjacent circles of micro wedge-shaped structures.

6. The negative pressure driven sucking apparatus according to claim 1, wherein the flexible section is of a hemispherical or arc-shaped arch structure.

7. The negative pressure driven sucking apparatus according to claim 1, wherein the sucking disc body and the annular wedge-shaped microstructure are made of a liquid silicone rubber.

8. The negative pressure driven sucking apparatus according to claim 7, wherein the sucking disc body is formed through a mold casting process or a 3D printing process; and the annular wedge-shaped microstructure and the bottom of the sucking disc body are bonded by a glue, or the liquid silicone rubber is poured on the mold with the annular micro wedge-shaped structures, and the annular wedge-shaped microstructure and the bottom of the sucking disc body are integrated into a whole.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) To more clearly illustrate the embodiment of the present disclosure or the technical scheme in the prior art, the following briefly introduces the attached figures to be used in the embodiment. Apparently, the attached figures in the following description show merely some embodiments of the present disclosure, and those skilled in the art may still derive other drawings from these attached figures without creative efforts.

(2) FIG. 1 is a structural schematic diagram of a negative pressure driven sucking disc with an annular wedge-shaped microstructure in the present disclosure;

(3) FIG. 2 is a schematic diagram of the negative pressure driven sucking disc with an annular wedge-shaped microstructure in a loading state in the present disclosure; and

(4) FIG. 3 is an integration process of the sucking disc body and the annular wedge-shaped microstructure into a whole.

(5) Reference signs in the drawings: 1, negative pressure cavity; 2, flexible section; 3, annular wedge-shaped microstructure; 4, adhered target object; and 5, sucking disc body.

DETAILED DESCRIPTION OF THE EMBODIMENTS

(6) The following clearly and completely describes the technical scheme in the embodiments of the present disclosure with reference to the attached figures in the embodiments of the present disclosure. Apparently, the described embodiments are merely a part rather than all of the embodiments of the present disclosure. All other embodiments obtained by those skilled in the art based on the embodiments of the present disclosure without creative efforts shall fall within the protection scope of the present disclosure.

(7) To make the foregoing objective, features and advantages of the present disclosure clearer and more comprehensible, the present disclosure is further described in detail below with reference to the attached figures and specific embodiments.

Embodiment I

(8) As shown in FIG. 1 to FIG. 3, the embodiment provides a negative pressure driven sucking disc with an annular wedge-shaped microstructure, comprising a sucking disc body 5, wherein an axial penetrating negative pressure cavity 1 is formed in the middle of the sucking disc body 5, specifically, the sucking disc body 5 is cylindrical, the bottom surface of the sucking disc body 5 is a flat circular ring surface, and the negative pressure cavity 1 is a cylindrical cavity; the top of the negative pressure cavity 1 is connected with a vacuum gas circuit through a pneumatic connector, and the cylindrical negative pressure cavity 1 can generate uniform shrinkage deformation along the center in a negative pressure state to provide uniform centripetal load for the annular wedge-shaped microstructure 3. A flexible section 2 is arranged at the bottom of the negative pressure cavity 1, the annular wedge-shaped microstructure 3 is arranged on the bottom surface of the sucking disc body 5, and the flexible section 2 is located at the bottom of the negative pressure cavity 1 and in the middle of the annular wedge-shaped microstructure 3 and used for enabling the sucking disc to generate centripetal shrinkage deformation during negative pressure driving; and the flexible section 2 is of a hemispherical or arc-shaped arch structure, so that the side wall of the sucking disc can generate a axis contraction effect under the driving of negative pressure, and stable loading and unloading of the annular wedge-shaped microstructure are realized.

(9) In the embodiment, the annular wedge-shaped microstructure 3 comprises multiple circles of micro wedge-shaped structures, the multiple circles of micro wedge-shaped structures are distributed in an annular array mode, and each circle of micro wedge-shaped structures is provided with multiple micro wedge-shaped structures. Specifically, the micro wedge-shaped structure comprises a first inclined plane and a second inclined plane, and the bottom of the first inclined plane is connected with the bottom of the second inclined plane to form a protruding tip; the included angle between the first inclined plane and the vertical plane ranges from 50° to 80°, the included angle between the second inclined plane and the vertical plane ranges from 20° to 60°, and the height of the single micro wedge-shaped structure in the vertical direction ranges from 40 to 200 microns.

(10) In the embodiment, a groove is formed between every two adjacent circles of micro wedge-shaped structures, the adjacent circles of micro wedge-shaped structures are sequentially connected, the protruding tips and the groove are tightly and alternately arranged in sequence, or a spacing of 30-100 microns between every two adjacent circles of micro wedge-shaped structures.

(11) In the embodiment, the sucking disc body 5 and the annular wedge-shaped microstructure 3 are made of a liquid silicone rubber.

(12) In the embodiment, the sucking disc body 5 is formed through a mold casting process or a 3D printing technology; and the annular wedge-shaped microstructure 3 and the bottom of the sucking disc body 5 are bonded into a whole through glue, or the liquid silicone rubber is poured on the mold with the annular micro wedge-shaped structures, and the annular wedge-shaped microstructure 3 and the bottom of the sucking disc body 5 are integrated into a whole; and the latter is preferably adopted in the embodiment, the annular wedge-shaped microstructure 3 and the bottom of the sucking disc body 5 are integrated into a whole.

(13) Also disclosed is a preparation method of the negative pressure driven sucking disc with an annular wedge-shaped microstructure, comprising the following steps:

(14) S1, selecting a mold material, preferably made of wax, resin or metal material;

(15) S2, machining and preparing a mold with micro wedge-shaped structures, and machining an annular micro wedge-shaped structure array distributed in an annular array on the surface of the mold;

(16) S3, pouring a liquid silicone rubber material into the area with the annular micro wedge-shaped structures of the mold, and after vacuum degassing treatment, covering the surface of the mold with the bottom of the sucking disc body 5; and

(17) S4, removing the sucking disc body 5 from the surface of the mold after the liquid silicone rubber is completely cured at room temperature, namely completing integration of the sucking disc body 5 and the annular wedge-shaped microstructure 3;

(18) or bonding the annular wedge-shaped microstructure 3 and the bottom of the sucking disc body 5 into a whole through glue.

(19) In the embodiment, in the step S2, a tool used for machining is a diamond tool with a micro wedge-shaped tip.

(20) In the embodiment, when the negative pressure driven sucking disc with an annular wedge-shaped microstructure works, the working process is divided into a loading process and a release process. The adhesion mechanism of the annular wedge-shaped microstructure 3 is the Van der Waals force effect, when unloaded, the annular wedge-shaped microstructure 3 is slightly inclined, only the tip of the annular wedge-shaped microstructure 3 is in contact with the surface of the adhered target object 4, in this situation, the Van der Waals force can be neglected; and when the side wall of the sucking disc body 5 is driven by negative pressure to shrink and deform to provide load for the annular wedge-shaped microstructure 3, the annular wedge-shaped microstructure 3 is stressed and bent, the contact area is remarkably increased, normal adhesive force is generated at the moment. When the negative pressure in the negative pressure cavity 1 disappears, the sucking disc body 5 recovers an initial non-deformed state, so that the annular wedge-shaped microstructure 3 recovers an initial shape, only the tip of the annular wedge-shaped microstructure 3 is in contact with the adhered target object 4, reducing the contact area and turning the adhesive off. The negative pressure driven sucking disc with an annular wedge-shaped microstructure is of a cylindrical cavity structure and has the function that the side wall of the sucking disc body 5 shrinks through negative pressure to provide centripetal load for the annular wedge-shaped microstructure 3.

(21) As shown in FIG. 1, when the sucking disc body 5 is close to the surface of the adhered target object 4, only the tip of the annular wedge-shaped microstructure 3 is in contact with the surface of the adhered target object 4, no obvious Van der Waals force exists, the sucking disc body is in a natural state, and the adhesive force generated by the annular wedge-shaped microstructure 3 is small and can be neglected.

(22) As shown in FIG. 2, the motion process when the negative pressure driven sucking disc with an annular wedge-shaped microstructure to be loaded is as follows: firstly, the sucking disc body 5 is close to the surface of the adhered target object 4, the annular wedge-shaped microstructure 3 is in contact with the surface of the adhered target object 4, then loading is started, and the side wall of the sucker body 5 is driven by the negative pressure to shrink, so that centripetal load is provided for the annular wedge-shaped microstructure 3 at the bottom of the sucking disc body 5, the annular wedge-shaped microstructure 3 is bent under stress, the contact area is remarkably increased, producing adhesion, and the loading process is achieved. Conversely, when the negative pressure disappears, the side wall of the sucking disc body 5 recovers the initial non-deformed state, centripetal load removed allow the annular wedge-shaped microstructure 3 recovers an initial shape, reducing the contact area and turning the adhesive off, and the release process is achieved.

(23) As shown in FIG. 3, after the liquid silicone rubber and curing are uniformly stirred according to a fixed proportion, vacuum degassing treatment is carried out, the mixture is uniformly poured on the mold with the annular micro wedge-shaped structures, and after the liquid silicone rubber is completely cured, the annular wedge-shaped microstructure 3 is removed from the mold, so that integration of the sucking disc body 5 and the annular wedge-shaped microstructure 3 can be completed.

(24) According to the negative pressure driven sucking disc with an annular wedge-shaped microstructure provided by the present disclosure, stable loading and unloading of the annular wedge-shaped microstructure are achieved through the axis contraction effect of the side wall of the sucking disc body under negative pressure driving, the requirement that traditional suction disc cannot achieve pickup operation of porous objects can be meet, and the sucking disc has wide application prospects in the field of stable carrying operation of smooth plane objects such as ultrathin wafers, ultrathin glass, flexible circuit boards.

(25) For those skilled in the art, obviously the present disclosure is not limited to the details of the exemplary embodiment, and the present disclosure can be achieved in other specific forms without departing from the spirit or essential characteristics of the present disclosure. Therefore, for every point, the embodiments should be regarded as exemplary embodiments and are unrestrictive, the scope of the present disclosure is restricted by the claims appended hereto, therefore, all changes, including the meanings and scopes of equivalent elements, of the claims are aimed to be included in the present disclosure, and any mark of attached figures in the claims should not be regarded as limitation to the involved claims.

(26) Several examples are used for illustration of the principles and implementation methods of the present disclosure. The description of the embodiments is used to help illustrate the method and its core principles of the present disclosure. In addition, those skilled in the art can make various modifications in terms of specific embodiments and scope of application in accordance with the teachings of the present disclosure. In conclusion, the content of this specification shall not be construed as a limitation to the present disclosure.