CN110315670A - Ceramic material surfaces negative angle micron form multi-process transfer method - Google Patents

Abstract

The present invention relates to ceramic material surfaces processing technology fields, and disclose ceramic material surfaces negative angle micron form multi-process transfer method, the multi-process transfer method is the following steps are included: S1: 50-100 parts by weight of deionized water, 50-70 parts by weight ceramics micron particles, 10-20 part by weight of metal micron particles, 5-15 parts by weight alloy microparticles, 1-5 parts by weight semiconductor microactuator rice grain, 1-5 parts by weight binder are successively put into ultrasonic stirrer, it is mixed evenly through ultrasonic wave, obtains semi-finished product slurry；S2: sequentially adding 3-7 parts by weight lubricant, 5-9 parts per weight dispersing agent and 1-3 parts by weight of plasticizer in the semi-finished product slurry that S1 is obtained, and continues ultrasonic wave and is mixed evenly, obtains finished product even dispersion slurry；S3: the finished product even dispersion slurry that S2 is obtained is filtered by two layers of strainer.The ceramic material surfaces negative angle micron form multi-process transfer method effectively increases the quality of ceramic material surfaces negative angle micron form multi-process transfer.

Description

Ceramic material surfaces negative angle micron form multi-process transfer method

Technical field

The present invention relates to ceramic material surfaces processing technology fields, specially ceramic material surfaces negative angle micron form multiplexing Sequence transfer method.

Background technique

Micro nano transfer printing technology is simply and efficiently to carry out micro nano structure as a kind of non-traditional micro-nano processing technology Production with device improves an effective means, ceramics as novel engineering material with its unique compression strength, very High surface hardness and excellent wear-resisting property are used widely in engineering field, micro- to ceramic material surfaces negative angle at present Rice form multi-process transfers quality that is ineffective, and then influencing the transfer of ceramic material surfaces negative angle micron form multi-process.

Summary of the invention

(1) the technical issues of solving

In view of the deficiencies of the prior art, the present invention provides ceramic material surfaces negative angle micron form multi-process transfer sides Method has the good advantage of ceramic material surfaces negative angle micron form multi-process transfer quality, solves in the prior art, ceramic material Expect the ineffective problem of surface negative angle micron form multi-process transfer.

(2) technical solution

To realize that the good purpose of above-mentioned ceramic material surfaces negative angle micron form multi-process transfer quality, the present invention provide such as Lower technical solution: ceramic material surfaces negative angle micron form multi-process transfer method, which includes following step It is rapid:

S1: by 50-100 parts by weight of deionized water, 50-70 parts by weight ceramics micron particles, 10-20 part by weight of metal micron Particle, 5-15 parts by weight alloy microparticles, 1-5 parts by weight semiconductor microactuator rice grain, 1-5 parts by weight binder successively put into super It in Sound Wave Mixer, is mixed evenly through ultrasonic wave, obtains semi-finished product slurry；

S2: 3-7 parts by weight lubricant, 5-9 parts per weight dispersing agent and 1-3 are sequentially added in the semi-finished product slurry that S1 is obtained Parts by weight of plasticizer continues ultrasonic wave and is mixed evenly, obtains finished product even dispersion slurry；

S3: the finished product even dispersion slurry that S2 is obtained is filtered by two layers of strainer；

S4: the filtered finished product even dispersion slurry of S3 is added in casting machine, through the tape casting, obtains slurry film；

S5: based on the slurry film that S4 is obtained, it is cast macromolecule monofilm in upper and lower surface, more Material claddings are made Film；

S6: taking one piece of silicon mother matrix, carries out photoetching on silicon mother matrix by litho machine, obtains mold mother matrix, and pass through coating machine Surface coating processing is carried out to mold mother matrix；

S7: high molecular material slurry is added on the mold mother matrix after S6 coating film treatment, and is turned in vacuum environment Print can form mold after high molecular material solidification；

S8: photoetching is carried out on the mold that S7 is obtained by litho machine, obtains photoetching mold；

S9: the photoetching mold that S8 is obtained is placed on more Material cladding films that S5 is obtained, and enterprising in more Material cladding films Row plane coining rolls transfer, forms the micro-nano form for having negative angle.

Preferably, the ultrasonic wave mixing time in the step S1 is 25min.

Preferably, the ultrasonic wave mixing time in the step S2 is 5min.

Preferably, two layers of strainer is respectively 40um and 10um in the step S3.

Preferably, the mold formed after the step S7 solidification is plane mould or cylinder mold.

Preferably, litho machine makes the micro-nano shape that section is triangle or cuboid by lithography on mold in the step S8 State.

(3) beneficial effect

Compared with prior art, the present invention provides ceramic material surfaces negative angle micron form multi-process transfer method, tools It is standby following the utility model has the advantages that

1, the ceramic material surfaces negative angle micron form multi-process transfer method is cooperated viscous by various powder micron particles Agent, lubricant, dispersing agent and plasticizer are tied, is mixed evenly to form even dispersion slurry via ultrasonic wave, paddle body passes through stream More Material cladding films are made in the method for prolonging, and photoetching mold carries out plane coining on more Material cladding films or rolls transfer, and formation has The micro-nano form of negative angle, the synthesis of multiple material component and its proportion can be largely fixed the quality of paddle body, component and Not mutually coordinated, beneficial effect brought by single component is matched, can even be eliminated by other components abatement, when serious, Different component mutually contradicts, and does not have whole synthesis effect, turns to influence ceramic material surfaces negative angle micron form multi-process The quality of print.The present invention passes through the optimal component and proportion for constantly debugging a variety of materials, so that various ingredients combine, phase Mutually coordinate, effectively improves the quality of ceramic material surfaces negative angle micron form multi-process transfer.

Specific embodiment

Below in conjunction with the embodiment of the present invention, technical scheme in the embodiment of the invention is clearly and completely described, Obviously, described embodiments are only a part of the embodiments of the present invention, instead of all the embodiments.Based in the present invention Embodiment, every other embodiment obtained by those of ordinary skill in the art without making creative efforts, all Belong to the scope of protection of the invention.

Embodiment 1

Present embodiments provide ceramic material surfaces negative angle micron form multi-process transfer method, the multi-process transfer method The following steps are included:

S1: by 50 parts by weight of deionized water, 50 parts by weight ceramics micron particles, 10 part by weight of metal micron particles, 5 weight Part alloy microparticles, 1 parts by weight semiconductor microactuator rice grain, 2 parts by weight binder are successively put into ultrasonic stirrer, through super Sound wave is mixed evenly, and obtains semi-finished product slurry；

S2: 3 parts by weight lubricants, 5 parts per weight dispersing agents and 1 parts by weight are sequentially added in the semi-finished product slurry that S1 is obtained Plasticizer continues ultrasonic wave and is mixed evenly, obtains finished product even dispersion slurry；

S3: the finished product even dispersion slurry that S2 is obtained is filtered by two layers of strainer；

S4: the filtered finished product even dispersion slurry of S3 is added in casting machine, through the tape casting, obtains slurry film；

S5: based on the slurry film that S4 is obtained, it is cast macromolecule monofilm in upper and lower surface, more Material claddings are made Film；

S6: taking one piece of silicon mother matrix, carries out photoetching on silicon mother matrix by litho machine, obtains mold mother matrix, and pass through coating machine Surface coating processing is carried out to mold mother matrix；

S7: high molecular material slurry is added on the mold mother matrix after S6 coating film treatment, and is turned in vacuum environment Print can form mold after high molecular material solidification；

S8: photoetching is carried out on the mold that S7 is obtained by litho machine, obtains photoetching mold；

S9: the photoetching mold that S8 is obtained is placed on more Material cladding films that S5 is obtained, and enterprising in more Material cladding films Row plane coining rolls transfer, forms the micro-nano form for having negative angle.

Embodiment 2

Present embodiments provide ceramic material surfaces negative angle micron form multi-process transfer method, the multi-process transfer method The following steps are included:

S1: by 60 parts by weight of deionized water, 55 parts by weight ceramics micron particles, 15 part by weight of metal micron particles, 10 weights Amount part alloy microparticles, 5 parts by weight semiconductor microactuator rice grains, 3 parts by weight binder are successively put into ultrasonic stirrer, are passed through Ultrasonic wave is mixed evenly, and obtains semi-finished product slurry；

S2: 5 parts by weight lubricants, 7 parts per weight dispersing agents and 2 parts by weight are sequentially added in the semi-finished product slurry that S1 is obtained Plasticizer continues ultrasonic wave and is mixed evenly, obtains finished product even dispersion slurry；

S3: the finished product even dispersion slurry that S2 is obtained is filtered by two layers of strainer；

S4: the filtered finished product even dispersion slurry of S3 is added in casting machine, through the tape casting, obtains slurry film；

S5: based on the slurry film that S4 is obtained, it is cast macromolecule monofilm in upper and lower surface, more Material claddings are made Film；

S6: taking one piece of silicon mother matrix, carries out photoetching on silicon mother matrix by litho machine, obtains mold mother matrix, and pass through coating machine Surface coating processing is carried out to mold mother matrix；

S7: high molecular material slurry is added on the mold mother matrix after S6 coating film treatment, and is turned in vacuum environment Print can form mold after high molecular material solidification；

S8: photoetching is carried out on the mold that S7 is obtained by litho machine, obtains photoetching mold；

S9: the photoetching mold that S8 is obtained is placed on more Material cladding films that S5 is obtained, and enterprising in more Material cladding films Row plane coining rolls transfer, forms the micro-nano form for having negative angle.

Embodiment 3

Present embodiments provide ceramic material surfaces negative angle micron form multi-process transfer method, the multi-process transfer method The following steps are included:

S1: by 80 parts by weight of deionized water, 60 parts by weight ceramics micron particles, 20 part by weight of metal micron particles, 10 weights Amount part alloy microparticles, 5 parts by weight semiconductor microactuator rice grains, 3 parts by weight binder are successively put into ultrasonic stirrer, are passed through Ultrasonic wave is mixed evenly, and obtains semi-finished product slurry；

S2: 6 parts by weight lubricants, 7 parts per weight dispersing agents and 1 parts by weight are sequentially added in the semi-finished product slurry that S1 is obtained Plasticizer continues ultrasonic wave and is mixed evenly, obtains finished product even dispersion slurry；

S3: the finished product even dispersion slurry that S2 is obtained is filtered by two layers of strainer；

S4: the filtered finished product even dispersion slurry of S3 is added in casting machine, through the tape casting, obtains slurry film；

S5: based on the slurry film that S4 is obtained, it is cast macromolecule monofilm in upper and lower surface, more Material claddings are made Film；

S6: taking one piece of silicon mother matrix, carries out photoetching on silicon mother matrix by litho machine, obtains mold mother matrix, and pass through coating machine Surface coating processing is carried out to mold mother matrix；

S7: high molecular material slurry is added on the mold mother matrix after S6 coating film treatment, and is turned in vacuum environment Print can form mold after high molecular material solidification；

S8: photoetching is carried out on the mold that S7 is obtained by litho machine, obtains photoetching mold；

S9: the photoetching mold that S8 is obtained is placed on more Material cladding films that S5 is obtained, and enterprising in more Material cladding films Row plane coining rolls transfer, forms the micro-nano form for having negative angle.

Embodiment 4

Present embodiments provide ceramic material surfaces negative angle micron form multi-process transfer method, the multi-process transfer method The following steps are included:

S1: by 90 parts by weight of deionized water, 60 parts by weight ceramics micron particles, 20 part by weight of metal micron particles, 15 weights Amount part alloy microparticles, 2 parts by weight semiconductor microactuator rice grains, 4 parts by weight binder are successively put into ultrasonic stirrer, are passed through Ultrasonic wave is mixed evenly, and obtains semi-finished product slurry；

S2: 5 parts by weight lubricants, 8 parts per weight dispersing agents and 2 parts by weight are sequentially added in the semi-finished product slurry that S1 is obtained Plasticizer continues ultrasonic wave and is mixed evenly, obtains finished product even dispersion slurry；

S3: the finished product even dispersion slurry that S2 is obtained is filtered by two layers of strainer；

S4: the filtered finished product even dispersion slurry of S3 is added in casting machine, through the tape casting, obtains slurry film；

S5: based on the slurry film that S4 is obtained, it is cast macromolecule monofilm in upper and lower surface, more Material claddings are made Film；

S6: taking one piece of silicon mother matrix, carries out photoetching on silicon mother matrix by litho machine, obtains mold mother matrix, and pass through coating machine Surface coating processing is carried out to mold mother matrix；

S7: high molecular material slurry is added on the mold mother matrix after S6 coating film treatment, and is turned in vacuum environment Print can form mold after high molecular material solidification；

S8: photoetching is carried out on the mold that S7 is obtained by litho machine, obtains photoetching mold；

S9: the photoetching mold that S8 is obtained is placed on more Material cladding films that S5 is obtained, and enterprising in more Material cladding films Row plane coining rolls transfer, forms the micro-nano form for having negative angle.

Embodiment 5

Present embodiments provide ceramic material surfaces negative angle micron form multi-process transfer method, the multi-process transfer method The following steps are included:

S1: by 100 parts by weight of deionized water, 70 parts by weight ceramics micron particles, 20 part by weight of metal micron particles, 15 weights Amount part alloy microparticles, 5 parts by weight semiconductor microactuator rice grains, 5 parts by weight binder are successively put into ultrasonic stirrer, are passed through Ultrasonic wave is mixed evenly, and obtains semi-finished product slurry；

S2: 7 parts by weight lubricants, 9 parts per weight dispersing agents and 3 parts by weight are sequentially added in the semi-finished product slurry that S1 is obtained Plasticizer continues ultrasonic wave and is mixed evenly, obtains finished product even dispersion slurry；

S3: the finished product even dispersion slurry that S2 is obtained is filtered by two layers of strainer；

S4: the filtered finished product even dispersion slurry of S3 is added in casting machine, through the tape casting, obtains slurry film；

S5: based on the slurry film that S4 is obtained, it is cast macromolecule monofilm in upper and lower surface, more Material claddings are made Film；

S6: taking one piece of silicon mother matrix, carries out photoetching on silicon mother matrix by litho machine, obtains mold mother matrix, and pass through coating machine Surface coating processing is carried out to mold mother matrix；

S7: high molecular material slurry is added on the mold mother matrix after S6 coating film treatment, and is turned in vacuum environment Print can form mold after high molecular material solidification；

S8: photoetching is carried out on the mold that S7 is obtained by litho machine, obtains photoetching mold；

S9: the photoetching mold that S8 is obtained is placed on more Material cladding films that S5 is obtained, and enterprising in more Material cladding films Row plane coining rolls transfer, forms the micro-nano form for having negative angle.

In conclusion the ceramic material surfaces negative angle micron form multi-process transfer method, passes through various powder microns Grain cooperation binder, lubricant, dispersing agent and plasticizer, are mixed evenly to form even dispersion slurry, paddle via ultrasonic wave More Material cladding films are made by the tape casting in body, and photoetching mold carries out plane coining on more Material cladding films or rolls transfer, The micro-nano form for having negative angle is formed, the synthesis of multiple material component and its proportion can be largely fixed the matter of paddle body Amount, component and not mutually coordinated, the beneficial effect brought by single component of proportion can even be eliminated, sternly by other components abatement When weight, different component is mutually contradicted, and whole synthesis effect is not had, to influence ceramic material surfaces negative angle micron form The quality of multi-process transfer.The present invention passes through the optimal component and proportion for constantly debugging a variety of materials, so that various ingredients are comprehensive Together, mutually coordinated, effectively improve the quality of ceramic material surfaces negative angle micron form multi-process transfer.

It should be noted that the terms "include", "comprise" or its any other variant are intended to the packet of nonexcludability Contain, so that the process, method, article or equipment for including a series of elements not only includes those elements, but also including Other elements that are not explicitly listed, or further include for elements inherent to such a process, method, article, or device. In the absence of more restrictions, the element limited by sentence "including a ...", it is not excluded that including the element Process, method, article or equipment in there is also other identical elements.

It although an embodiment of the present invention has been shown and described, for the ordinary skill in the art, can be with A variety of variations, modification, replacement can be carried out to these embodiments without departing from the principles and spirit of the present invention by understanding And modification, the scope of the present invention is defined by the appended.

Claims (6)

1. ceramic material surfaces negative angle micron form multi-process transfer method, it is characterised in that: the multi-process transfer method includes Following steps:

S1: by 50-100 parts by weight of deionized water, 50-70 parts by weight ceramics micron particles, 10-20 part by weight of metal micron Grain, 5-15 parts by weight alloy microparticles, 1-5 parts by weight semiconductor microactuator rice grain, 1-5 parts by weight binder successively put into ultrasound It in wave blender, is mixed evenly through ultrasonic wave, obtains semi-finished product slurry；

S2: 3-7 parts by weight lubricant, 5-9 parts per weight dispersing agent and 1-3 weight are sequentially added in the semi-finished product slurry that S1 is obtained Part plasticizer continues ultrasonic wave and is mixed evenly, obtains finished product even dispersion slurry；

S3: the finished product even dispersion slurry that S2 is obtained is filtered by two layers of strainer；

S4: the filtered finished product even dispersion slurry of S3 is added in casting machine, through the tape casting, obtains slurry film；

S5: based on the slurry film that S4 is obtained, it is cast macromolecule monofilm in upper and lower surface, more Material cladding films are made；

S6: taking one piece of silicon mother matrix, and photoetching is carried out on silicon mother matrix by litho machine, obtains mold mother matrix, and by coating machine to mould Have mother matrix and carries out surface coating processing；

S7: high molecular material slurry being added on the mold mother matrix after S6 coating film treatment, and is transferred in vacuum environment, high Mold can be formed after molecular material solidification；

S8: photoetching is carried out on the mold that S7 is obtained by litho machine, obtains photoetching mold；

S9: the photoetching mold that S8 is obtained being placed on more Material cladding films that S5 is obtained, and is carried out on more Material cladding films flat Face pressure print rolls transfer, forms the micro-nano form for having negative angle.

2. ceramic material surfaces negative angle micron form multi-process transfer method according to claim 1, it is characterised in that: institute Stating the ultrasonic wave mixing time in step S1 is 25min.

3. ceramic material surfaces negative angle micron form multi-process transfer method according to claim 1, it is characterised in that: institute Stating the ultrasonic wave mixing time in step S2 is 5min.

4. ceramic material surfaces negative angle micron form multi-process transfer method according to claim 1, it is characterised in that: institute Stating two layers of strainer in step S3 is respectively 40um and 10um.

5. ceramic material surfaces negative angle micron form multi-process transfer method according to claim 1, it is characterised in that: institute Stating the mold formed after step S7 solidification is plane mould or cylinder mold.

6. ceramic material surfaces negative angle micron form multi-process transfer method according to claim 1, it is characterised in that: institute It states litho machine in step S8 and makes the micro-nano form that section is triangle or cuboid by lithography on mold.