JP4340383B2 - Method and apparatus for manufacturing composite shaped body of metal and ceramics - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a method and apparatus for producing a composite body of metal and ceramics, and more specifically, a tape formed with ceramic fine powder and a tape formed with metal fine powder are alternately stacked while irradiating laser light, and the metal is formed by laser light. The present invention relates to a method and an apparatus for producing a composite body of metal and ceramic by melting fine powder.
[0002]
[Prior art]
Conventionally, composite moldings of metal and ceramics are molded and sintered by various methods such as mixing metal fine powder and ceramic fine powder with a lubricant, mixing the mixture, and molding the mixture into a mold. Is manufactured by.
In this method, it is necessary to uniformly mix the metal fine powder and the ceramic fine powder. However, since the specific gravity of the fine powder is different, it is necessary to stir for a long time, and a mold is required for molding. Since it takes cost and time to manufacture the mold, there is a drawback in that it is expensive to manufacture a small quantity or a prototype, and the time is long.
[0003]
Furthermore, as a method of modeling without using a mold, light energy required for curing by laser light is supplied to a photocurable fluid resin in which a photocurable fluid resin or silica powder is dispersed. Japanese Patent Application Laid-Open No. 60-247515 or Japanese Patent Application Laid-Open No. 8-25486 discloses a method of manufacturing a resin shaped body having a desired shape or a resin shaped body containing silica powder by selectively supplying the resin with a position control device or the like. ing.
[0004]
In addition, as a method of manufacturing a sintered body without using a mold, a photocurable fluid resin is mixed with a sinterable (sintered) inorganic material powder, and this inorganic material powder is mixed with photocuring. A light-cured layer is formed by irradiating a light-flowing resin layer with a light image, and the cured layers are sequentially stacked to form a three-dimensional structure, and the resin component that has been photocured by combustion or the like is removed. JP-A-8-252867 discloses that an inorganic material powder mixed shaped body from which a resin component has been removed is made into a sintered body by HIP treatment or the like.
[0005]
[Problems to be solved by the invention]
The method disclosed in the above publication is a method for producing a resin shaped body containing an inorganic material powder for producing a resin shaped body of a desired shape, a resin shaped body containing silica powder, or a sintered body without using a mold. However, both are not a method of manufacturing a composite manufactured using two types of tapes, but also a method of manufacturing a resin molded body containing inorganic material powder for manufacturing a sintered body, and modeling and sintering are separately performed. Therefore, it was necessary to sinter separately after modeling.
SUMMARY OF THE INVENTION It is an object of the present invention to provide a method and an apparatus for manufacturing a composite body of metal and ceramics, which can simultaneously perform modeling and sintering of a composite of metal and ceramics without using a mold. It is.
[0006]
In order to solve the above-mentioned problems, in the method for producing a composite body of metal and ceramic according to the present invention, a tape formed with ceramic fine powder, a so-called green tape is placed on a substrate, and the metal fine powder is formed thereon. The cross-sectional shape of the composite shaped body to be manufactured from now on (the surface cut in the horizontal direction) The laser beam is controlled so as to become, for example, the laser beam is controlled and irradiated by computer-aided design (CAD) data, so that the cross-sectional shape of the composite shaped body to be produced from the tape formed with the metal fine powder is obtained. The ceramic fine powder is melted and bonded with the ceramic fine powder of the tape formed with the ceramic fine powder. A composite shaped body in which ceramics are dispersed in a metal is formed by repeating the process more than once, and the metal fine powder and ceramic fine powder on the portion of the tape that has not been irradiated with laser light are removed to obtain a composite shaped body of metal and ceramics. It is to be.
[0007]
In order to solve the above-mentioned problems, in the method for producing a composite body of metal and ceramics according to the present invention, a ceramic fine powder is melted into a cross-sectional shape of a composite body to produce a tape formed by molding metal fine powder by the above method. When the metal fine powder is melted and the volume is reduced during the process, the ceramic fine powder or the metal fine powder is supplied and laser light is applied to the metal fine powder. It is to produce a composite shaped article in which metal fine powder is melted by irradiation under control, and ceramics are dispersed in the metal by repeating these.
[0008]
Furthermore, in the method for producing a composite shaped body of metal and ceramic according to the present invention, the tape formed with the ceramic fine powder is mixed with an organic binder such as an alkali salt of silicic acid in the ceramic fine powder, and paper or the like as required. A mixture in which an organic binder is mixed or the mixture and the reinforcing tape are rolled with a compression roll, and when the reinforcing tape is used, the reinforcing tape is peeled off, and the metal fine powder is used. The tape formed from the body is mixed with an organic binder such as an alkali salt of silicic acid in a metal fine powder, and a reinforcing tape such as paper is used if necessary. A mixture containing the organic binder or a compression roll of the mixture and the reinforcing tape. If a reinforcing tape is used, the reinforcing tape must be peeled off. .
[0009]
In the method for producing a composite body of metal and ceramic according to the present invention, the ceramic fine powder is made of Al. ₂ O _Three 1 type or 2 or more types selected from metal oxides such as cBN, metal nitrides such as cBN, metal carbides such as TiC, and carbon isotope fine powders such as diamond. One or more selected from the group VIII metals such as Fe in the periodic table and Group Ib metals such as Cu and fine powders of those metals alloyed with other metals as alloy components It is to do.
[0010]
Further, in the apparatus for producing a composite shaped body of metal and ceramics according to the present invention, a laser light irradiation apparatus electrically connected to a control unit controlled based on computer-aided design (CAD) data, and a laser light irradiation apparatus A laser light generator for supplying laser light to the substrate, a substrate driving device, and a tape supply device for intermittently supplying both a tape formed with ceramic fine powder and a tape formed with metal fine powder. It is.
[0011]
Moreover, in the apparatus for producing a composite body of metal and ceramic according to the present invention, a tape formed with ceramic fine powder and a substrate 7 that supports the tape formed with metal fine powder and can move up and down, A tape supply device 9 for intermittently supplying a tape formed with the ceramic fine powder and a tape formed with the metal fine powder on the substrate 7, and the tape 1 or metal fine powder formed with the ceramic fine powder on the substrate 7 A cross section of a composite model that manufactures a movable table 8 that can be lowered and raised according to the thickness of the molded tape 2, and a tape that is formed from metal fine powder placed on the substrate 7. A laser beam irradiation device 11 such as a carbano mirror that melts into a shape, and a laser beam for supplying the laser beam to the laser beam irradiation device. -Light generators 10a, 10b, a computer 12 for controlling at least the laser light irradiation device by computer-aided design (CAD) data, etc., and an atmosphere adjusting device 26, a level roller 19, ceramic fine powder or metal fine powder as required A body supply device is provided.
[0012]
[Action]
According to the method and apparatus for producing a composite shaped body of metal and ceramics of the present invention, the metal fine powder is melted so that the tape formed with the metal fine powder has a cross-sectional shape of the composite shaped body to be produced. The shape can be maintained even when the metal fine powder is melted, and the molten metal in which the metal fine powder is melted penetrates into the ceramic, and unlike FIG. As shown, a high-density ceramic composite shaped body without voids can be produced.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the manufacturing method of the composite modeling body of the metal and ceramics of this invention is demonstrated in detail with reference to FIGS.
FIG. 2 is a conceptual view showing a composite molded body of a metal and ceramic as-manufactured by the manufacturing method of the present invention, a tape formed with ceramic fine powder not sintered, and a tape formed with metal fine powder. FIG. 3 is a schematic front view of an embodiment of an apparatus for producing a composite body of metal and ceramic according to the present invention, and FIG. 4 is a tape and metal formed with ceramic fine powder used in the production method of the present invention. It is a conceptual diagram of the apparatus used in order to manufacture the tape which shape | molded the fine powder.
[0014]
In the method for producing a composite body of metal and ceramic according to the present invention, a tape formed with a ceramic fine powder is placed on a substrate (see reference numeral 7 in FIG. 3), and a tape formed with the metal fine powder is stacked thereon. If necessary, press and hold both of them with a level roller or the like, and irradiate the top surface of the tape on which the metal fine powder has been formed with a laser beam controlled so as to have a cross-sectional shape of the composite body to be manufactured. When the tape formed with metal fine powder is melted by the above and these are repeated once or twice or more to produce a thick composite model, the ceramic fine powder is melted when the metal fine powder melts and the volume decreases. Alternatively, a metal fine powder is supplied, and the metal fine powder is melted by controlling and irradiating laser light to compensate for the reduced volume. While La mix is a method of making a composite shaped body in which is dispersed, ceramics for use in a tape obtained by forming a ceramic fine powder, Al ₂ O _Three TiO ₂ , ZrO ₂ Metal oxide such as cBN, Si _Three N _Four , TiN, a metal nitride such as TiC, WC, TaC, (W, Ti) C, and a carbon isotope such as diamond. The size of these ceramic fine powders is preferably 40 μm or less. This is because if it is larger than 40 μm, it is difficult to tape.
[0015]
Furthermore, the metal of the fine metal powder used in the present invention is one or two of the group VIII metals such as Fe, Co, Ni and the like, and the group Ib metals such as Cu and Ag, and alloys based on these metals. That's it. When two or more metals are used, it is preferable to use an alloy having a low melting point such as a Ni-B alloy as one of the metals. The size of the fine powder of these metals or alloys is preferably 40 μm or less. This is because, if it is larger than 40 μm, the metal fine powder is not sufficiently melted and the structure of the composite shaped body is not uniform.
[0016]
A tape formed with ceramic fine powder or metal fine powder used in the present invention, so-called green tape (see reference numeral 1 or 2 in the figure), has a thickness of usually 200 to 600 μm, and is ceramic fine powder 3 or metal fine powder 4. About 10 to 30% by volume of the organic binder 5 is mixed and put into the hopper 13, and the mixed material is fed from the hopper 13 to two opposing compression rolls provided under the hopper 13 and rolled. It is manufactured by.
[0017]
In addition, when there is a possibility that the tape formed with ceramic fine powder or metal fine powder may be damaged during winding or feeding, the reinforcing tape 14 such as paper, cloth or plastic tape is used as shown in FIG. A ceramic fine powder or a metal fine powder mixed with an organic binder is placed on the top and rolled by two opposing compression rolls 15 at the same time, and then the reinforcing tape 14 is peeled off. is there. These ceramic fine powders or metal fine powder tapes can be wound around a roll, or cut to the required size according to the size of the composite body to be produced. it can.
When this reinforcing tape is used, if there is a risk that the tape formed with ceramic fine powder or metal fine powder may adhere to each other if the reinforcing tape is peeled off, store the reinforcing tape in close contact with the ceramic tape on the substrate or the substrate. When supplying the fine powder or the metal fine powder onto the molded tape, the reinforcing tape may be peeled off and supplied.
Reference numeral 16 in FIG. 2 denotes a reinforcing tape guide roll, and reference numerals 17 and 18 denote tape take-up rolls that take up a tape formed of ceramic fine powder or metal fine powder.
[0018]
The method for producing a composite shaped body of metal and ceramic according to the present invention includes a ceramic fine powder or a metal fine powder, ie, a ceramic fine powder only, a metal fine powder only, a ceramic fine powder, when the metal fine powder is melted and the volume is reduced. The metal fine powder is supplied from a fine powder supply nozzle (see 20, 21 in FIG. 3), and the metal fine powder is melted by irradiating with laser light to compensate for the volume reduction. It can be performed every time after the metal fine powder is melted by irradiating with laser light, or it can be performed after the metal fine powder is melted by irradiating with laser light a plurality of times. The ceramic fine powder and metal fine powder to be supplied are supplied in a layered form so as to have the same composition as that of the composite molded body to be manufactured. The amount is preferably set to an amount that is substantially horizontal when the metal fine powder is melted.
[0019]
Examples of the organic binder used for forming a tape formed with the ceramic fine powder or metal fine powder include alkali salt of silicic acid, talc boric acid, sodium salt of alginic acid, glycerin and the like.
[0020]
In the method for manufacturing a composite body of metal and ceramic according to the present invention, the tape 1 formed with the ceramic fine powder and the tape 2 formed with the metal fine powder are placed (supplied) on the substrate 7 placed on the substrate. As shown in FIG. 3, the method is a method of unwinding the tape 1 formed with the ceramic fine powder from the tape take-up rolls 17 and 18 and cutting it with the cutter 25 and placing it on the substrate 7, and forming the ceramic fine powder. There is a method of cutting the tape 1 or the like that has been cut into a predetermined length and placing the tape 1 and extruding it or transporting it by a method such as suction. In that case, the tape 1 formed with the ceramic fine powder and the tape 2 formed with the metal fine powder can be separately supplied and placed, or the metal fine powder is placed on the tape 1 formed with the ceramic fine powder. The molded tape 2 can also be supplied and placed in a stacked manner.
[0021]
In the method for producing a composite shaped body of metal and ceramics according to the present invention, a tape formed with ceramic fine powder is placed on a substrate, and a tape formed with metal fine powder is overlaid on the substrate. When placing a new ceramic fine powder or metal fine powder-molded tape on a ceramic fine powder or metal fine powder-molded tape, it is necessary to adhere to the lower one. Therefore, it is preferable to press and adhere with a level roller (see 19 in FIG. 3) or the like.
[0022]
A substrate 7 (see FIG. 3) on which a tape tape formed with the ceramic or metal fine powder is placed is made of metal or ceramic. When the substrate is made of metal, steel is preferable because of its strength, heat resistance, and low cost. However, care should be taken because it may be joined to the composite body to be formed. When the substrate is made of ceramics, it can be easily separated because it is not joined to the composite body to be formed.
[0023]
The method for producing a composite body of metal and ceramics according to the present invention is produced by placing a tape formed with metal fine powder on a tape formed with ceramic fine powder and then pressing the two in close contact as necessary. By controlling and irradiating the laser beam so that it has the cross-sectional shape of the composite model, the tape formed with the metal fine powder is melted to disperse the ceramic in the metal. In order to irradiate with laser light, a drawing of a three-dimensional composite model to be manufactured is input to a three-dimensional CAD, and a fixed thickness (ceramic fine powder is formed on the three-dimensional composite model Create a slice graphic data group in the horizontal direction (tape thickness + tape thickness formed of metal fine powder) and input this data to the computer. After irradiating laser light according to shape data, and further placing a tape formed with ceramic fine powder and tape formed with metal fine powder on it, laser light is irradiated with slice graphic data next to the above slice graphic data, This can be done by repeating this sequentially.
[0024]
Further, in the method for producing a composite shaped body of metal and ceramic according to the present invention, a method of irradiating laser light so as to have a cross-sectional shape of a composite shaped body to be produced includes a tape formed with ceramic fine powder and a metal fine powder. A method of moving the above-described substrate on which the tape formed with the tape is moved to the cross-sectional shape (XY axis direction) of the composite body to be produced (in this case, the thickness of the tape on which the ceramic fine powder is usually formed + the fine metal powder) And the method of moving the laser light to the cross-sectional shape (XY axis direction) of the composite body to be manufactured (in this case, usually the above substrate is molded with ceramic fine powder). There are two methods: the thickness of the tape and the thickness of the tape on which the metal fine powder is formed).
[0025]
In the method for producing a composite molded body of metal and ceramic according to the present invention, it is necessary to continuously supply a tape formed with ceramic fine powder and a tape formed with metal fine powder, and press with a level roller or the like so as to be in close contact with each other. Therefore, it is preferable that the height of the surface for supplying the tape formed with the metal fine powder is constant, so that the thickness of the tape formed with the ceramic fine powder on the substrate + the thickness of the tape formed with the metal fine powder. A method of moving the laser beam down to the sectional shape (XY axis direction) of the composite modeled body for manufacturing the laser beam is appropriate.
In addition, a drawing of a three-dimensional composite model to be manufactured is input to the three-dimensional CAD, and the three-dimensional composite model is formed with a certain thickness (thickness of the tape formed with ceramic fine powder + metal fine powder). A method of creating a horizontal slice graphic data group (thickness of the tape) and irradiating a laser beam with the slice graphic data is a known method as disclosed in the above-mentioned JP-A-8-252867. is there.
[0026]
The method for producing a composite shaped body of metal and ceramics according to the present invention is a composite molding in which a tape formed with ceramic fine powder and a tape formed with metal fine powder are continuously supplied and laser light irradiation is produced from now on. When it is repeated until the body height (thickness) is reached, it is molded and sintered in a tape formed from unsintered ceramic fine powder and a tape formed from metal fine powder (green tape). A composite shaped body is formed. Since it becomes such a state, it acts as a support for the composite shaped body in which the tape formed with the unsintered ceramic fine powder and the tape formed with the metal fine powder (green tape) is formed. A composite shaped body with little deformation and high accuracy is formed.
[0027]
In addition, the tape formed with the unsintered ceramic fine powder and the tape formed with the metal fine powder (green tape), which are the support for the formed composite body, can be easily removed by human hands. Can do. Furthermore, by heating to a temperature of 200 to 300 ° C. at which the organic binder volatilizes, the tape formed with the ceramic fine powder and the tape formed with the metal fine powder (green tape) become sandy and fluidized, and more easily. Can be removed.
[0028]
Next, an embodiment of an apparatus for producing a composite shaped body of metal and ceramic according to the present invention will be described.
[0029]
An apparatus 6 for producing a composite body of metal and ceramics according to the present invention includes a control unit (computer 12 or the like) that is controlled based on computer-aided design (CAD) data. An electrically connected laser beam irradiation apparatus 11 (carabano mirror, XY drive device for laser light), laser light generators 10a and 10b for supplying laser light to the laser light irradiation device 11, a substrate drive device (moving table 8 etc.) and a fine powder mix of metal powder. The tape supply device 9 supplies both of the tapes intermittently.
[0030]
More specifically, the tape 1 formed of the ceramic fine powder or the tape 2 formed of the metal fine powder manufactured by the above method and the apparatus shown in FIG. A substrate 7 capable of moving up and down, a tape supply device 9 for intermittently supplying a tape formed with the ceramic fine powder and a tape formed with a metal fine powder on the substrate 7, and the substrate 7 as the ceramic The moving base 8 that can be lowered and raised according to the thickness of the tape 1 formed with fine powder or the tape 2 formed with metal fine powder, and the metal fine powder placed on the substrate 7 are Laser light irradiation device 11 such as a carbano mirror and laser light generation devices 10a and 10b for melting the molded tape so as to have a cross-sectional shape of the composite shaped body 31 to be manufactured. The computer 12 includes at least a computer 12 that controls the laser beam irradiation device 11 based on computer-aided design (CAD) data. Further, an atmosphere forming device 26 is provided if necessary, and in the vicinity of the laser beam irradiation device 11 if necessary. A ceramic fine powder supply device (the whole is not shown but the nozzle 20 is shown) and a metal fine powder supply device (the whole is not shown but the nozzle 21 is shown) are provided and necessary Depending on the level, a level roller 19 is provided so that the molded composite molded body can be taken out from the side, and the tape formed from the ceramic fine powder supplied or the tape formed from the metal fine powder is supported and held. The substrate 7 that can move up and down in the frame 20 is made of a metal such as steel or ceramic, and a shaft 19 for connecting to the movable table 8 is provided. It is fixed at the bottom.
[0031]
The moving table 8 moves the substrate 7 up and down by a signal from the computer 12 or the like. The moving table 8 corresponds to the thickness of the tape formed of the ceramic fine powder or the metal fine powder formed on the substrate 7. It is designed to rise when the distance is lowered and the operation is started.
The tape supply device 9 unwinds from the tape take-up roll 17 formed with ceramic fine powder and the tape take-up roll 18 formed with metal fine powder, and intermittently supplies these tapes via the guide roll 24. The tape that has been cut by the cutter 25, the tape that is formed from the cut ceramic fine powder, and the tape that is formed from the metal fine powder are cut and stored in a storage container, sucked and transported to the substrate 7. Or the substrate 7 is pushed out from the bottom by a cylinder or the like.
[0032]
The laser beam generators 10a and 10b are devices for supplying a laser beam 32 to a laser beam irradiation device 11 for melting a tape formed of laminated metal fine powders. The laser beam generators 10a and 10b include a laser beam power source 10a and a laser beam emitting device 10b. It is the same as that normally used.
[0033]
The laser beam irradiation device 11 irradiates the laser beam generated by the laser beam generator so as to have a cross-sectional shape of the composite body to be produced from now on, and is controlled by the computer 12 according to computer-aided design (CAD) data. The carbano mirror 11 controlled by the NC device, the lens or the like being moved by the XY driving device, and the like.
[0034]
The computer 12 for controlling the movement of the laser beam irradiation device 11 (carbano mirror), the moving table 8 and the like is such that the thickness of the tape 1 formed with the ceramic fine powder and the thickness of the tape 2 formed with the metal fine powder. The thickness of the tape on which the ceramic fine powder was formed was created for the three-dimensional composite structure formed by inputting the data of the length and the drawing of the three-dimensional composite structure to be produced in the three-dimensional CAD. + Slice graphic data group in the horizontal direction (the thickness of the tape formed with the metal fine powder) is input, and the moving table 7 and the laser beam irradiation device 11 (carbanomirror) are controlled by these.
[0035]
As shown in FIG. 4, the tape winding roll 17 and the tape winding roll 18 formed with the metal fine powder are ceramic fine powder 3 or metal fine powder as shown in FIG. 4 is mixed with the organic binder 5 from the hopper 13 onto the reinforcing tape 14, compressed by a rolling roll 15, formed, and the formed ceramic powder is removed from the reinforcing tape and wound up. It can be manufactured by winding on a roll.
[0036]
As shown in FIG. ₂ Covers the melted surface of the laser beam 35 with an inert gas such as gas or Ar gas. For the inert gas in the cover 27 surrounding the periphery of the quartz glass 32 where the upper laser beam is transmitted N from cylinder 28 etc. ₂ Gas, Ar gas, or the like is introduced from the valve 30 and exited from the valve 31. Although not shown, an inert gas is injected from the nozzle onto the surface melted by the laser beam. .
[0037]
Further, the ceramic fine powder supply device or the metal fine powder supply device ejects the ceramic fine powder or the metal fine powder from the ceramic fine powder supply nozzle 20 or the metal fine powder supply nozzle 21 by an inert gas from a not-shown bopper. It is something that was made.
Further, the level roller 19 is a roller that can roll on a tape formed with ceramic fine powder by a hydraulic cylinder or the like.
[0038]
Examples of the present invention will be described below.
【Example】
Example of polishing tip manufacture
6 ~ 12μm cBN which is a ceramic fine powder and becomes an abrasive grain. 10 Capacity%, # 1000 Al ₂ O _Three 10 volume%, organic binder acrylic binder is mixed with 30 volume%, put into a bopper 13 as shown in FIG. 2, placed on a polyethylene sheet reinforcing tape 14 and rolled with two compression rolls 15 Thus, a tape was prepared and a tape take-up roll formed with ceramic fine powder was obtained.
[0039]
Next, 80% by volume of 99.99% Cu with an average particle size of 40 μm, 10% by volume of Cu / Ni—B (BNi2) with an average particle size of 40 μm, and 10% of an organic binder acrylic binder is used as a metal fine powder. The volume% is mixed and placed in a bopper 13 as shown in FIG. 2, placed on a polyethylene sheet reinforcing tape 14, rolled with two compression rolls 15 to create a tape, and a metal fine powder molded tape It was a winding roll.
[0040]
On the other hand, a drawing (30 mm long × 60 mm wide × 10 mm thick) of the three-dimensional polishing tip 32 of the polishing tool to be produced (composite shaped body, see FIGS. 5 to 7) 33 is input to the three-dimensional CAD, and the tertiary polishing tip A slice pattern data group in the horizontal direction is created for each 0.4 mm thickness (the thickness of the tape formed with ceramic fine powder + the thickness of the tape formed with metal fine powder), and this is input to the computer 12 did.
[0041]
Using a device for producing a composite body of metal and ceramics as shown in FIG. 3, the moving table 8 is operated to raise the substrate (S20C low carbon steel) 7 to a predetermined reference plane, and the ceramic fine powder on the substrate 2 The tape 1 formed with the ceramic fine powder unwound from the tape take-up roll 17 formed with the body is cut, placed thereon, manually pressed using the level roller 19, and the movable table 3 is operated by a computer to operate the substrate 2. Was lowered by 200 μm, and the tape formed with the metal fine powder was similarly placed on the tape 20 formed with the pressed ceramic fine powder, and manually pressed using a level roller.
[0042]
In this state, the laser light generators 10a and 10b and the atmosphere forming device 26 are operated, and the laser light irradiation device 11 is operated under the control of the computer 12, and a polishing chip is formed on the tape 2 formed with the pressed metal fine powder. Laser light having a shape corresponding to a cross-sectional shape of 0.4 mm was irradiated from below 33. The laser light irradiation conditions were a beam output of 28 W, a beam diameter of 0.25 mm, a scanning speed of mm / min, a beam scanning interval of 0.2 mm, and a defocus of 0.
[0043]
The above process 5 times After repeating the above steps, the ceramic fine powder and metal fine powder corresponding to the decrease in volume were supplemented, and these steps were repeated repeatedly to overlap the tape formed with the ceramic fine powder and the tape formed with the metal fine powder. Open the door on the side, remove it from the substrate 7, break the tape formed with ceramic fine powder and the metal fine powder around the manufactured polishing chip 32, and take out the polishing chip It was. The size of this polishing tip was 30 mm long × 60 mm wide × 10 mm thick.
[0044]
Moreover, when the dimensional accuracy was measured about the manufactured said polishing chip, the dimension was a dimension as planned.
Further, when the surface of the polishing tip was observed with a microscope, the ceramic fine powder was covered with a molten metal fine powder.
[0045]
Further, the above-prepared polishing tip 33 was brazed to a holding table for the polishing tool 34 to prepare the polishing tool 34 as shown in FIGS. Using this tool, polishing was performed under the following conditions as shown in FIG. As a result, the polished surface was as smooth as requested.
[0046]
In addition, ceramic fine powder and metal fine powder are mixed at a predetermined ratio, and further an organic binder is mixed. This is molded into a tape, and the metal fine powder is melted with laser light to produce a composite shaped body of metal and ceramics. However, it is difficult to uniformly mix the ceramic fine powder and the metal fine powder as much as necessary, and it is difficult to manufacture a composite shaped body in which the metal and the ceramic are sufficiently mixed.
[0047]
【The invention's effect】
The method and apparatus for producing a composite body of metal and ceramics according to the present invention has the following excellent effects due to the above configuration.
(1) A composite shaped body of metal and ceramics can be manufactured without using a mold.
(2) Since a mold is not used, it can be used for small-scale production, and even complex shapes can be manufactured at a relatively low cost. can do.
(3) Since the metal / ceramic composite shaped body to be manufactured is obtained by melting metal fine powder, the ceramics are covered with metal, so that the density is high without voids.
(4) Since the difference in specific gravity between the metal and the ceramic is large, the mixing time becomes longer when mixed, but this mixing time can be omitted.
(5) Functionally gradient materials can be easily manufactured.
[Brief description of the drawings]
FIG. 1A is a conceptual cross-sectional view of a conventional metal-ceramic composite shaped body, and FIG. 1B is a conceptual cross-sectional view of a metal-ceramic composite shaped body manufactured by the manufacturing method of the present invention.
FIG. 2 is a conceptual diagram showing the state of a composite molded body of metal and ceramics as manufactured by the manufacturing method of the present invention, a tape formed of ceramic fine powder that has not been sintered, and a tape formed of metal fine powder. FIG.
FIG. 3 is a schematic front view of an embodiment of an apparatus for producing a composite body of metal and ceramic according to the present invention.
FIG. 4 is a conceptual diagram of an apparatus used for producing a tape formed with ceramic fine powder and a tape formed with metal fine powder used in the production method of the present invention.
FIG. 5 is a front view of a polishing tool in which a polishing tip manufactured by the manufacturing method of the present invention is brazed.
6 is a side view of that of FIG. 5. FIG.
7 is an explanatory view showing a method of using the polishing tool shown in FIGS. 4 and 5. FIG.
[Explanation of symbols]
1 Tape formed from ceramic fine powder
2 Tape formed from metal fine powder
3 Ceramic fine powder
4 Metal fine powder
5 Organic binder
6 Metal / ceramic composite body manufacturing equipment
7 Substrate
8 Moving platform
9 Tape feeder
10 Laser beam generator (a laser beam power supply, b laser beam generator)
11 Laser beam irradiation device, carbano mirror
12 computers
13 Hopper
14 Reinforcing tape
15 Compression roll
16 Roll for reinforcing tape
17 Tape take-up roll formed of ceramic fine powder
18 Tape take-up roll formed of metal fine powder
19 Level roller
20 Ceramic fine powder supply nozzle
21 Metal fine powder supply nozzle
22 Shaft
23 Retaining frame
24 Tape guide roll
25 cutter
26 Atmosphere adjusting device
27 Cover
28 Inert gas cylinder
29 30 Valve
31 Composite body
32 quartz glass
33 Polishing tips
34 Abrasive tools
35 Laser light

Claims (8)

Place the tape on which the ceramic fine powder is molded on the substrate, put the tape on which the metal fine powder is molded on it, and control the laser beam so that the cross-sectional shape of the composite body to be manufactured is on the upper surface. A composite of metal and ceramics characterized by producing a composite shaped body in which ceramics are dispersed in metal by melting a tape formed with metal fine powder by irradiation and repeating these once or twice or more A method for manufacturing a shaped body. Place the tape on which the ceramic fine powder is molded on the substrate, put the tape on which the metal fine powder is molded on it, and control the laser beam so that the cross-sectional shape of the composite body to be manufactured is on the upper surface. When the tape formed with the metal fine powder is melted by irradiation and the metal fine powder is melted and the volume is reduced during the process, the ceramic fine powder or the metal fine powder is supplied to the metal fine powder. A metal-ceramic composite structure characterized by producing a composite structure in which ceramic fine particles are dispersed by melting a metal fine powder by controlling and irradiating laser light, and repeating these steps. Manufacturing method. By mixing the organic binder with the ceramic fine powder, placing the mixture on the reinforcing tape, simultaneously rolling the mixture and the reinforcing tape with a compression roll, and then peeling the reinforcing tape. After the tape is formed and the metal fine powder is molded, the organic fine powder is mixed with the organic binder, the mixture is placed on the reinforcing tape, and the mixture and the reinforcing tape are simultaneously rolled with a compression roll. 3. The method for producing a composite shaped body of metal and ceramics according to claim 1 or 2, wherein the method is produced by peeling a reinforcing tape. The ceramic fine powder is one or more selected from metal oxide, metal nitride, metal carbide and carbon isotope fine powder, and the metal fine powder is of the periodic table. 3. The method for producing a composite shaped body of metal and ceramic according to claim 1 or 2, wherein the metal of Group VIII and Group Ib and the metal are alloyed with another metal as an alloy component. 3. The laser beam is controlled by computer-aided design (CAD) data so that the laser beam is controlled so as to have a cross-sectional shape of the composite model to be manufactured. Method for producing a composite body of metal and ceramics. A laser light irradiation device electrically connected to a control unit controlled based on computer-aided design (CAD) data, a laser light generation device for supplying laser light to the laser light irradiation device, a substrate driving device, and ceramic fine powder An apparatus for manufacturing a composite body of metal and ceramics, comprising: a tape supply device that intermittently supplies both a body and a tape formed with metal fine powder. A tape that supports a tape formed of ceramic fine powder and a tape formed of metal fine powder and can move up and down, a tape formed of the ceramic fine powder on the substrate, and a tape formed of metal fine powder A tape supply device for intermittently supplying the substrate, a moving base that can lower and raise the substrate according to the thickness of the tape formed with the ceramic fine powder or the tape formed with the metal fine powder, and the above Laser light irradiation device that melts so as to have a cross-sectional shape of a composite modeling body that manufactures a tape formed of metal fine powder laminated on a substrate, and a laser light generation device that sends laser light to the laser light irradiation device And a computer that controls at least the laser beam irradiation device by computer-aided design (CAD) data. Apparatus for producing a composite shaped body of metal and the ceramic, characterized in that. 8. The apparatus for manufacturing a composite body of metal and ceramics according to claim 6, wherein a device for supplying metal fine powder or ceramic fine powder is provided in the vicinity of the laser light irradiation device.

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