US20110287281A1

US20110287281A1 - Composite component of clad material and synthetic resin part and manufacturing method of the same

Info

Publication number: US20110287281A1
Application number: US13/147,516
Authority: US
Inventors: Masao Yamaguchi; Yasuo Hashimoto; Yasuhiro Watanabe
Original assignee: Corona Kogyo Corp
Current assignee: CHERRY CHIEF MAF CORP
Priority date: 2009-02-02
Filing date: 2010-01-29
Publication date: 2011-11-24
Also published as: JP5396662B2; WO2010087439A1; JP2010173298A

Abstract

A Clad material superimposed aluminum materials on stainless steel materials forms coating film by the electrodeposition coating on each whole surface of stainless steel material and aluminum material. A film of the aluminum material is removed by the irradiation of the laser beam, and the aluminum material of this region is exposed. Aluminum material is introduced into an injection molding machine after forming anodizing film. The synthetic resin part is formed with invading a synthetic resin to aperture of anodizing film. Then the composite component of clad material and synthetic resin part is produced.

Description

BACKGROUND OF THE INVENTION

The present invention relates to a composite component of clad material and synthetic resin part and manufacturing method of the same.
The method to join a synthetic resin part to metal materials is known to use an insert molding die. Specifically, a part of the metal part made by iron or steel is inserted in the cavity of the die. At this stage, the molten synthetic resin is injected into a cavity. A portion of the metal part is inserted into and is molded in the synthetic resin part of the predetermined shape.
Moreover, the method to join the synthetic resin part to aluminum materials is known to form an anodizing film having a lot of apertures with more than 25 nm in diameter on the surface of the aluminum material, and a part of the synthetic resin is inserted into apertures of the anodizing film by injection molding.

SUMMARY OF THE INVENTION

An aspect of the present invention provides a manufacturing method for a composite component of clad material and synthetic resin part comprising the steps of: forming a film by the electrodeposition coating for the whole surface of a clad material having a aluminum material in at least one aspect; removing a portion of the film formed on the surface of the aluminum material; forming an anodizing film on the surface of the aluminum material which exposed by removing a film; and joining a synthetic resin part to the clad material by pouring a part of the synthetic resin part into a lot of apertures of the anodizing film to form a composition component.
Other aspect of the present invention provides a composite component of clad material and synthetic resin part comprising: a clad material superimposed the stainless steel material on the aluminum material; an anodizing film formed in a portion of the aluminum material; a synthetic resin part joined to the clad material by pouring into apertures of the anodizing film.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a flowchart of a manufacturing method for a composite component of a clad material and a synthetic resin part with the first embodiment of this invention;

FIG. 2 is a sectional view of a clad material;

FIG. 3 is a sectional view for the step of forming the painting layer on the whole surface of the clad material;

FIG. 4 is a sectional view for the step of removing a part of the painting layer by irradiating laser;

FIG. 5 is a plan view of the clad material which removed a part of the painting layer by irradiating a laser;

FIG. 6 is a sectional view for the step of forming an anodizing film in the region where the painting layer was removed;

FIG. 7 is a plan view of a clad material which formed an anodizing film;

FIG. 8 is a sectional view for the step of molding a synthetic resin part on the anodizing film.

FIG. 9 is a plan view of a composite component of the clad material and the synthetic resin part;

FIG. 10 is a schematic view of the trace of the laser irradiation;

FIG. 11 is a sectional view of the injection molding machine;

FIG. 12 is a plan view of the cover which is an example of the composite component;

FIG. 13 is a sectional view take along the line I-I;

FIG. 14 is a flowchart of a manufacturing method for a composite component of a clad material and a synthetic resin part with the second embodiment of this invention;

FIG. 15 is a plane of the clad material formed a partial mask;

FIG. 16 is a sectional view take along the line II-II;

FIG. 17 is a sectional view for the step of forming a coating film by the electrodeposition coating on the whole surface of the clad material including over a partial mask;

FIG. 18 is a plane view of the composite component which is molded the synthetic resin part on the region that removed a partial mask; and

FIG. 19 is a sectional view of the device which joins the synthetic resin to the clad material by a heating crimp method.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Preferred embodiments of the present invention will be explained below in detail with reference to the accompanying drawings.

First Embodiment

The manufacturing method of the compound component of a clad material and a synthetic resin part is explained with reference to FIG. 1, firstly.
At first, In step S101, a pretreatment is carried out for a clad material as a processing object. As shown in FIG. 2, a clad metal 1 is superimposed an aluminum material 3 on a stainless steel material 2 and combined them. For example, the thickness of the stainless steel material 2 is approximately 0.2 mm to 0.4 mm, The thickness of the aluminum material 3 is approximately 0.1 mm to 0.2 mm.
In the pretreatment, a surface treatment is carried out for the stainless steel material 2 mainly. The surface treatment of the stainless steel material 2 forms, for example, a pattern by etching on the surface of the stainless steel material 2 and forms a pattern by machine work like the hairline processing. In this case, the surface treatment is carried out for the aluminum material 3 as substitute for the stainless steel material 2, or in addition to the stainless steel material 2.
Then, In step S102, the clad metal 1 is molded as a predetermined shape by press working. In other case, step S101 may be carried out after step S102, and two steps are carried out at the same time. Moreover, only one of step S101 and step S102 may be carried out.
Moreover, In step S103, the whole surface of the clad metal 1 is coated electrodeposition. As shown in FIG. 3, a homogeneous coating film 4 is formed on the surface of the clad material 1 by the electrodeposition coating. The coating film 4 is used as a mask in a later process.
After this, in step S 104, a portion of the coating film 4 formed on the surface of the aluminum material 3 of the clad material 1 is removed. As shown in FIG. 4 and FIG. 5, a opening 4A is formed to the coating film 4, and the aluminum material 3 is exposed through opening 4A. As Shown in FIG. 5, the coating film 4 of the penumbra of the clad material 1 is removed partially. However, a place and size, the number which remove the coating film 4 are not limited to this.
Moreover, in step S105, A film for the joining is formed on the clad metal 1. As shown in FIG. 6 and FIG. 7, a porous anodizing film 5 is formed as a film for joining in the region on the surface of the aluminum material 3 which was exposed by removing the coating film 4, where is not masked by the coating film 4. Here, the anodizing film 5 has porous layer 5A with elongated apertures 6 densely on the surface, and a thin dense insulating layer 5B formed from the bottom of the porous layer 5A to a metal surface. Moreover, the region where the anodizing film 5 is formed is the region that removed the coating film 4.
Then, in step S106, a synthetic resin part is joined in the region that formed the anodizing film 5. As shown in FIG. 8 and FIG. 9, the synthetic resin part 7 is joined to the clad metal 1 by burying into apertures 6 of the anodizing film 5. Hereby, the compound component 8 is formed of the clad metal 1 and the synthetic resin part 7. In this case, the synthetic resin part 7 may be joined to the clad material 1 at the region that is smaller than an region of the anodizing film 5. Also, in other case, the synthetic resin part 7 may be joined to the clad material 1 at an area same as an anodizing film 5, or a portion of the synthetic resin part 7 may covers across anodizing film 5.
Moreover, in step S107, a postprocessing is carried out for the compound component 8. An example of the postprocessing includes the coating of the stainless steel material 2. Moreover, after removing all of the coating film 4 used as a mask, an exposed surface may be coated again. Moreover, after removing the coating film 4 of the stainless material 2 without removing the coating film 4 of the aluminum material 3, an exposed surface may be coated again. In this case, the coating film 4 may be left as decoration.
In this case, this process may finish without Step S107. Moreover, Step S107 may be carried out with processing like step S101.
Then, The details of each process from step S103 to step S106 of FIG. 1 are explained below.
The details of a electrodeposition coating process of step S103 are explained first.
At first, the clad metal 1 is washed with approximately 5% of sodium hydroxide water solutions which heated to 60° C. to remove fat. Also, the clad material 1 is washed with strong alkali liquid to remove fat electrically. After removal of fat, the clad material 1 is washed with water. Then, the clad material 1 is immersed in 5% to 10% of water solution of sulfuric acid and is neutralized. After that, the clad material 1 is washed with water.
In the electrodeposited coating process, the clad metal 1 is immersed in the coating tank that dissolved water-soluble paint. And, the voltage is applied to the water-soluble paint in the coating tank, when an anode is used for the clad material 1 and the cathode is used an aluminum plate or the stainless steel board. Accordingly, coating film 4 consisting of the water-soluble paint is formed on the surface of the clad material 1 by electrodeposition. As shown in FIG. 3, the coating film 4 is formed approximately uniformly in each of the exposed surface of the stainless steel material 2 and the exposed surface of the aluminum material 3.
Here, the coating film 4 is used as a mask in a later process. In addition, the coating film 4 is used as a facing of the decoration. For example, water-soluble paint to form the coating film 4 includes the electrodeposition paint of the anionic type.
Moreover, conditions of the electrodeposition coating include for example, the voltage of 50V to 200V for 1 minute to 3 minutes. In this case, the coating film 4 is formed in the thickness of 10 μm to 20 μm.
Then, the details of the process to remove a portion of the coating film 4 of step S104 are explained.
When removing the coating film 4 partly, the laser processing machine may be used. In this process, for example, the laser beam includes a CO2 laser or YAG laser. The laser beam is irradiated on the predetermined surface of the aluminum materials 3 of the clad material 1.
As shown in a schematic view of FIG. 10, the laser irradiation is carried out for a region joining the synthetic resin part 7 later. At first, the laser processing machine moves the irradiation position of the laser beam to the predefined first direction d1 on the coating film 4. Accordingly, the coating film 4 is removed in the shape of a rectilinear figure.
Moreover, the laser processing machine moves the irradiation position with predetermined pitch P1 in the second direction d2 from the position that irradiated a laser beam. Here, the second direction d2 is a direction at right angles to the first direction d1. And after moved the potion with predetermined pitch P1, the laser beam is irradiated to the anodized film along the first direction d1 again.
For example, when the laser beam is irradiated sequentially on the coating film 4 from the left of FIG. 10 and removed the coating film 4, the next irradiation position becomes on the line BL2 which moved pitch P1 to the right.
After that, these processes are repeated, and the coating film 4 is removed to the position for example, in line L1. Accordingly, A opening 4A showing in FIG. 7 is formed in the coating film 4, and the aluminum material 3 of this region is exposed.
For example, the laser processing machine irradiates a CO2 laser at pulse frequency 20 Hz and moves an irradiation position at the speed of 800 mm/m to 1,200 mm/m. When the irradiation width (length in second direction d2) of the laser beam on the surface of the clad material 1 is 0.1 mm, it is preferable for the pitch P1 to be 0.01 mm to 0.2 mm. If pitch P1 is smaller than this range, it will be not effective because the removal of the coating film 4 take time. If the pitch P1 is bigger than this range, bond strength of the synthetic resin part 7 decreases.
Here, the bond strength between the clad material 1 and the synthetic resin examined by the pulling testing machine using the specimen which joined the synthetic resin to the clad material 1. In this case, the size for the junction of the clad material 1 and the synthetic resin assumes 5 mm in a pulling direction, and 10 mm in the direction at right angles to the pulling direction.
Pulling strength of 120 kgf was obtained when the pitch is 0.01 mm. Pulling strength of 100 kgf was obtained when the pitch is 0.1 mm. Pulling strength of 90 kgf was obtained when the pitch is 0.2 mm. In fact, when the pitch P1 is less than twice the irradiation width of the CO2 laser, pulling strength more than 90 kgf is obtained. Moreover, when the pitch P1 is less than the irradiation width of the CO2 laser, pulling strength more than 100 kgf is obtained. When a YAG laser is used in substitution for a CO2 laser, the pulling strength becomes small.
Then, the details of the formation process of a film for joining of step S105 are explained.
At first, removal of fat process and the neutralization process of the clad material 1 are carried out if needed. Then, a phosphoric acid bath is formed using a phosphoric acid water solution of approximately 30% of density and 18° C. to 20° C. The clad material 1 is immersed into the phosphoric acid bath, and the clad material 1 is used as an anode. A cathode is used an aluminum plate or a stainless steel board. Then, for example, the electrolysis by the direct current method is carried out in the range of voltage 35V to 55V for 1 minute to 5 minutes.
Accordingly, as shown in FIG. 6, the porous anodizing film 5 which has a lot of apertures of approximately 1 μm to 1.5 82 m in depth is formed in the region where removed a mask of the coating film 4 on the surface of the aluminum material 3 of the clad material 1. The diameter of apertures 6 formed on the surface of the anodizing film 5 was approximately 40 nm to 100 nm.
In this case, a sodium hydroxide bath may be used in substitution for the phosphoric acid bath. In this case, electro bath of approximately 18° C. to 20° C. that reserved a water solution of the sodium hydroxide of 0.2 mol is used. The processing condition is the same as the phosphoric acid water solution. Accordingly, the porous anodizing film 5 which has apertures of approximately 0.5 μm to 1 μm in depth is formed in the region where removed a mask of the coating film 4 on the surface of the aluminum material 3 of the clad material 1. The diameter of apertures 6 formed on the surface of the anodizing film 5 was approximately 30 nm to 50 nm.
In this way, the clad material 1 is washed with the nitric acid water solution after forming the anodizing film 5 by electrobath using the phosphoric acid bath or the sodium hydroxide. And the clad material 1 is dried by a hot wind.
Here, the phosphoric acid bath may form a large aperture in a short time as compared to the sodium hydroxide bath. Moreover, In the case of using the phosphoric acid bath, the anodizing film 5 obtained apertures 6 in 25 nm to 30 nm diameter when shortened time for electrolysis. In this case, it is desirable to carry out the electrolysis on a condition to form diameter of apertures 25 becomes more than 25 nm, and obtain the depth with more than 500 nm of porous layer 5A. If diameter and depth of the apertures 6 in the anodizing film 5 are smaller than this, bond strength of the synthetic resin part 7 may decrease.
Then, step s106, a process to join the synthetic resin part to region formed a film for the joining to the clad material 1 is explained.
An example of the injection molding machine to be used in this process is shown in FIG. 11. The injection molding machine 20 has a die 21 opening up and down, and has a space 22 to set the clad material 1 in between a lower model 21A and a upper model 21B. Moreover, the upper model 21B has a cavity 23 to a shape of the synthetic resin part 7, and a gate 25 which the synthetic resin 24 flows through to fill the cavity 23 with. In this case, although illustration is omitted, the gate 25 is connected to a source of supply of synthetic resin 24.
The synthetic resin 24 may use various resin such as PP (polypropylene), PE (polyethylene), PBT(polybutylene terephthalate), the ABS (acrylonitrile/butadiene/styrene resin), PPS(polyphenylene sulfide). In this case, in consideration of difference in linear expansion of the aluminum materials 3 and the synthetic resin 24, it is desirable for synthetic resin materials for forming the synthetic resin molding body by injection molding to choose resin having a coefficient of elasticity that can absorb a difference of the linear expansion, preferably less than 10000 Mpa, and having hot water resistance and medicine resistance. Suitable synthetic resin 24 includes olefin-based resin such as PBT and PE, the PP.
When the synthetic resin part 7 is molded, the clad material 1 is placed in space 22 formed by opening the die 21. The clad material 1 is placed in the die 21 so that the anodizing films 5 face to the gate 25. After closed the die 21, molten synthetic resin 24 is injected into the cavity 23 through the gate 25. Accordingly, the molten synthetic resin 24 pressurizes into the cavity 23 and is filled. The molten synthetic resin 24 is poured into a lot of apertures 6 of the anodizing film 5.
The synthetic resin 24 solidifies by cooling the die 21 using a coolant. Thereafter, as shown in FIG. 8 and FIG. 9, the compound component 8 is obtained by opening the die 21. The compound component 8 has the constitution that a portion of the synthetic resin of the synthetic resin part 7 joined by poured into a lot of apertures 6 of the anodizing film 5.
Here, it is preferable for the molding pressure of the injection molding to be more than approximately 700 kg. For example, the temperature of the die 21 set at 80° C. to 150° C., and the molding pressure set at 700 kg to 1,200 kg. In this case, by heating with a heater attached to the die 21, it may become easier to joining with molten synthetic resin 24 and a heated the clad material 1.
Manufacturing the compound component 8 in this way, bond strength was measured as pulling strength using the pulling testing equipment. In the case of forming the anodizing film 5 using the phosphoric acid bath, tensile strength of 30 kgf obtained with the minimum. Moreover, In the case of forming the anodizing film 5 using the sodium hydroxide bath, tensile strength of 20 kgf obtained with the minimum.
The compound component 8 manufactured in this way obtained a texture of the material of stainless steel on the surface, and enough strength. Moreover, the compound component 8 is lighter by compounding the aluminum materials 3.
As explained in the above, according to the present embodiment, by masking a region which is not joined to the synthetic resin part 7 with the coating film 4, the anodizing film 5 may be formed while protecting the stainless steel material 3. With the case which exposed the stainless steel material 3, a current density becomes higher, and the stainless steel material 3 may receive damage, but the stainless steel material 3 is protected with the painting film 4 by this manufacturing method. Moreover, work efficiency is improved by masking only a desired region of the painting film 4 to form the anodizing film 5.
Furthermore, a desired region is easily processed by using a laser beam to remove a portion of the coating film 4. It may accept easily for changing the size and the shape of a region removing the coating film 4. In here, the coating film 4 is removed well by irradiating the laser beam in a pitch of 0.01 mm to 0.2 mm. Therefore, the synthetic resin part 7 is joined strongly.
And, the compound component 8 is easily manufactured using usual process by joining the synthetic resin part 7 to the clad metal 1 using the anodizing film 5.
Here, the compound component 8 may use for a cell-phone and an information terminal, the case of the camera, e.g., a removable cover. The example of the compound component 8 manufactured as a cover of the case of the cell-phone is shown in FIG. 12 and FIG. 13. A cover 30 as the composition component 8 has the external form bended three penumbras 31, 32 of the elongated clad material 1 to the aluminum materials 3. And a inside portion of penumbras 31, 32, is joined to the synthetic resin part 33. The synthetic resin part 33 forms nails 33A projecting to inward together. Moreover, two resin materials 35 are joined to one remaining penumbra 34 which is not bended. Two resin materials 35 project to outside of the cover 30, and approximately parallel to the plane that is not bending in the cover 30.
The Synthetic resin part 33, 35 are joined to the aluminum materials 3 of the clad material 1 by a method same as the synthetic resin part 7 according to flow chart shown in FIG. 1. The cover 30 may be attached to a case body 36 as other parts, by fitting the resin material 33, 35 in a reentrant or a trench formed on the case body 36.
As the cover 30 shown in FIG. 12 and FIG. 13, a portion for attaching to main body of the case 36 is made in the synthetic resin part 33, 35. Therefore, rigidity is lowered in comparison with the case of using metal materials. Thus, it becomes easy to put on and take off the cover 30 to the case body 36.
Moreover, the rigidity for the mount portion of cover 30 is lowered by using the synthetic resin part 33, 35. Accordingly, Even if the cover 30 put to and take off the case body 36 many times, durability for the mount portion may improve. Here, in the case that mount potion manufactured with the stainless steel material 2 together, plural dies are necessary to press the complicated shape for the mount portion. Therefore, production cost rises.
Moreover, the mount portion forms together with the clad material 1 using press working, stress may concentrate on the clad metal 1 connecting the mount portion and be deform the clad metal 1. In this embodiment, a problem is solved because synthetic resin part 33, 35 is used for the mount portion.
In this case, the clad material 1 may has the structure that superimposed different metal materials other than the stainless steel material 2 on the aluminum material 3. Moreover, the clad material 1 may have a stricture that superimposed a duralumin material on other aluminum material, and put a duralumin material between aluminum materials.

The Second Embodiment)

The second embodiment of the manufacturing method of the compound component of a clad material and the synthetic resin part will be concretely described with referent to FIG. 14.
In step S201, a clad material 1 is preprocessed first. This process is similar to the first enforcement. Then, in step S202, a partial mask is formed on the surface of the clad material 1 by print. As shown in FIG. 15 and FIG. 16, the partial mask 41 is formed on a portion joining a resin part on the surface of aluminum materials 3 of clad material 1. For example, the partial mask 41 may use the ink of the UV (ultraviolet ray) hardening type. In this case, after applying ink to the surface of aluminum materials 3 with print, UV light irradiates the ink with. Accordingly, the partial mask 41 is formed by ink curing. In this case, the partial mask 41 may be formed before preprocessing.
Then, in step S203, the clad material 1 is pressed in a similar process of the first embodiment. Moreover, in step S204, masking is carried out by the electrodeposition coating. The electrodeposition coating is carried out for the whole surface of the clad material 1, and homogeneous coating film 4 is formed. This process is carried out in a similar process of the first embodiment. In this case, as shown in FIG. 17, because the coating film 4 is not formed on the partial mask 41, the partial mask 41 is exposed in this region.
After this, in step S205, the partial mask 41 is removed with an ink remover. The ink remover is used, for example, a non-chlorine-based solvent, which dissolve the partial mask 41, but does not dissolve the coating film 4.
When only the partial mask 41 removed the surface of the aluminum material 3, the aluminum material 3 of the region where the partial mask 41 was formed is exposed. As a result, the opening 4A that is similar to FIG. 4 is formed.
Then, in step 206, the anodizing film 5 is formed in the region where the aluminum material 3 was exposed to by removing the partial mask 41 as a film for joining. Moreover, in step S207, the Synthetic resin part 7 is joined on the anodizing film 5. These processes are carried out in a similar process of the first embodiment.
Accordingly, as shown in FIG. 18, the compound component 8 is obtained by the synthetic resin part 7 being joined on region of a portion of the aluminum material 3 of the clad material 1.
As explained in the above, according to the present embodiment, by removing painting film 4 partially by forming the partial mask 41, the region joining the synthetic resin part 7 is defined only by medicinal solution process.

The Third Embodiment

According to the present embodiment, in step S106 or step S207, the clad material 1 and the synthetic resin part 7 are made separately, and the compound component 8 is made by joining both materials by a heating crimp method.
FIG. 19 shows an example of the processing apparatus which produces the compound component by a heating crimp method. The processing apparatus 51 has a induction heating device 52 and a press head 53 controlling going up and down. The Press head 53 is connected to a cylinder for pressurization, which is not shown in FIG. 19.
The induction heating device 52 has a bottom portion 55A of a holder 55 containing the clad material 1, and a coil 56 for plane heating is buried in a bottom portion 55A. The coil 56 is connected to a high frequency oscillator 57 provided outward.
When joining the synthetic resin part 7, the clad material 1 is contained in holder 55 at first. The clad metal 1 is placed in holder 55 so that a surface of the anodizing film faces the top. Furthermore, the synthetic resin part 7 is put on the joining position of the anodizing film 5.
Then, going down the press head 53, the Synthetic resin part 7 is pressurized from the upper portion and is pushed to the anodizing film 5. From this point, applying current to the coil 56 by operation of the high frequency oscillator 57, the clad material 1 is heated by induction heating.
Accordingly, the synthetic resin part 7 is heated through contact with the clad material 1, and the potion of the synthetic resin which is pushed to an anodizing film 5 melts and pours into apertures 6 of the anodizing film 5. After cooling the clad material 1 and the synthetic resin part 7, going up the press head 53. The compound component 8 is obtained from the synthetic resin part 7 joined to the clad material 1 through the anodizing film 5.
Here, with this production apparatus 51, the compound component 8 of enough bond strength is provided by the high frequency output of high frequency oscillator 57 at 500 W to 50 kW, frequency 50 kHz to 3 MHz for 10 seconds to 12 seconds, for example.
In this case, the characteristic of the embodiments is added below.
According to the clad material and the manufacturing method of the compound component of the synthetic resin part, the anodizing film is formed only in a part of the aluminum material side of the clad material. The part consisting of the material except the aluminum material is protected with a film. By medicinal solution and an electric current for forming the anodizing film, the portion of the materials except the aluminum material does not catch the damage.
Moreover, a CO2 laser removes only a irradiated portion of the film. The film is removed more precisely by making smaller the pitch of irradiating a laser beam. The anodizing film may be formed reliably.
Moreover, According to the clad material and the manufacturing method of the compound component of the synthetic resin part, a portion of the film may be removed only by medicinal solution processing. Other domains covered by a film are protected reliably by dissolving only a partial mask.
As the aperture diameter of the anodizing film becomes big, joint strength of the synthetic resin part may increases.
A molten synthetic resin may join the synthetic resin part which poured into the apertures of the anodizing film by using injection molding. A synthetic resin part melts partially and pours into the apertures of the anodizing film at the contact surface between the anodizing film and the synthetic resin part. Accordingly, the synthetic resin part is joined to the clad material. While having texture of the material and the strength of stainless steel material, the synthetic resin part may obtain lighter body using the aluminum material.
According to the clad material and the compound component of the synthetic resin part, texture of the material and the strength of stainless steel material are provided by using the stainless steel material for outer surface. By using the aluminum material for the inner surface to obtain lighter body and may join the synthetic resin part using the aluminum material. The synthetic resin part may engage to other parts and use for a spacer.
According to the clad material and the compound component of the synthetic resin part, the synthetic resin part is attached to other parts by engaging the synthetic resin part to other parts.
In this case, the compound part of embodiments may be apply to the clad material and the composition product having various kinds of size and shapes such as the personal ornaments such as an outside device product, the number plate among the electric apparatuses such as a personal computer or the cell-phone, parts such as the electronic equipment, building materials, the indoor of the building, an outside device product, a ship, a plane, a railroad carriage and cars with the synthetic resin part.
This invention is interpreted without being limited to an example and the condition of embodiments.
As for this invention, various kinds of changes and transformation are possible in the range that does not deviate from the spirit and scope.

Claims

1. A manufacturing method for a composite component of clad material and synthetic resin part comprising the steps of:

forming a film by the electrodeposition coating for the whole surface of a clad material having a aluminum material in at least one aspect;

removing a portion of the film formed on the surface of the aluminum material;

forming an anodizing film on the surface of the aluminum material which exposed by removing a film; and

joining a synthetic resin part to the clad material by pouring a part of the synthetic resin part into a lot of apertures of the anodizing film to form a composition component.

2. A manufacturing method according to claim 1, wherein the removing a part of the film is to removing a film by the irradiation of the CO2 laser.

3. A manufacturing method according to claim 1, further comprising the step of irradiating a laser beam to the first direction and removing the film in the shape of a rectilinear figure on the aluminum material, and moving the laser beam to the second direction which is approximately at right angles to the first course with the pitch of 0.01 mm to 0.2 mm.

4. A manufacturing method according to claim 1, wherein the step of forming a film by the electrodeposition coating comprises forming a partial mask on a portion of the surface of the aluminum material, and forming a film on the whole surface of the clad material including on the partial mask;

the step of removing a portion of the film comprises removing a portion of the film by dissolving the partial mask.

5. A manufacturing method according to claim 1, wherein the anodizing film has a lot of apertures of 40 nm to 100 nm in diameter.

6. A manufacturing method according to claim 1, wherein the synthetic resin part is formed by injection molding.

7. A manufacturing method according to claim 1, further comprising:

jointing the synthetic resin part and the anodizing film with pushing the synthetic resin part to the anodizing film while heating.

8. A manufacturing method according to claim 1, wherein the clad material is superimposed the stainless steel material on the aluminum material.

9. A composite component of clad material and synthetic resin part comprising:

a clad material superimposed the stainless steel material on the aluminum material;

an anodizing film formed in a portion of the aluminum material;

a synthetic resin part joined to the clad material by pouring into apertures of the anodizing film.

10. A composite component to claim 9, wherein the anodizing film is formed in the penumbra of the clad material; and the resin material is the nail to engage the clad material to other parts.