Process of producing composite sheet and structure of the same
A process of producing composite sheet is presented, and the process comprises the steps of: (a) providing a plurality of metallic sheets; (b) bonding the metallic sheets with one another; and(c) finishing the bonded composite sheet that has a plurality of metallic layers. In comparison to conventional single type/solid piece of building material, the present invention results in a dramatic cost reduction in various building industry. With the up-to-date technology, the strength of metallic composite sheet remains within structural grade parameter and meets related specifications. Manufacturers are benefited from the cheaper metallic sheet in the composition while enjoying the same quality look of the outer layer. Furthermore, a structure of the composite sheet is also presented in the present invention.
1. Field of the Invention
The present invention relates to a kind of composite sheet that can be used as building and industrial material. In particular, it relates to a process of producing composite sheet and a structure of the same.
2. Description of the Related Art
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Because quantities of easily accessible natural resources (specifically metals) on Earth are decreasing, the cost of the composite sheet made of exotic metals will be more and more expensive. However, if we simply decrease the quantities of the more expensive metals for the metallic surface layers 2a and attempt to reduce the cost of the composite sheet in this simple fashion, the strength of the composite sheet would suffer and may not be enough to reach industry safety regulations.
SUMMARY OF THE INVENTIONOne particular aspect of the present invention is to provide a process of producing a composite sheet and the structure of the same, the strength of the composite sheet not only can satisfy the industry safety regulation, but also the weight of the composite sheet can be reduced compare to traditional composite sheet, and the cost of producing the composite sheet of the present invention can be effective reduced.
The process of producing a composite sheet, comprising the steps of: (a) providing a plurality of metallic sheets; (b) bonding the metallic sheets with one another; and (c) finishing the bonded composite sheet having a plurality of metallic layers.
The structure of the composite sheet comprises a core layer and two surface layers, wherein each surface layer has a plurality of metallic sheets, the metallic sheets bond with one another, the core layer and the surface layers bond with each other, and the core layer is sandwiched between the two surface layers.
This invention has several advantages: by carefully choosing the composite materials used to produce the surface layers, and coupled with the present invention, thereby reducing the quantity requirement for the more expensive metal on the surface layers and the core layer of the composite sheet, and due to the bonding method of the present invention the strength of the composite sheet will still satisfy industry safety regulation and the cost of producing the composite sheet can be effectively reduced. The weight of the composite sheet can be light (due to the fact that the more expensive metals are generally heavier), so that it is very convenient for fabricator and installer to assemble many of the composite sheets with each other.
For further understanding of the invention, reference is made to the following detailed description illustrating the embodiments and examples of the invention. The description is only for illustrating the invention and is not intended to be considered limiting of the scope of the claim.
The drawings included herein enable a further understanding of the invention.
Brief introduction of the drawings are as follows:
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(a) provide a plurality of metallic sheets 1 (top, middle, and bottom metallic sheets 1), wherein the metallic sheets 1 are coiled around a coiling roller group 21, and the metallic sheet 1 are made of aluminum, copper, steel, zinc, or titanium.
(b) Uncoil the metallic sheets 1 coiled around the coiling roller group 21 (uncoiling can be done by motor (not shown) or any other power generating equipment, which is beyond the scope of the present invention), then as the metallic sheets are uncoiling, the top and bottom metallic sheets 1 are passed through a stretching roller group 22, and the stretching roller group 22 extends, stretches, and flattens the top and bottom metallic sheets 1.
(c) the middle metallic sheets 1 have top and bottom surfaces (here on now referred as contact surfaces) respectively, place a plurality of adhesive on the contact surfaces of the middle metallic sheets 1, heat the adhesive films via a set of heating rollers 23 to form a plurality of bonding layers on the contact surfaces respectively.
(d) the metallic sheets 1 are passed through a forming roller group 24; the forming roller group 24 includes a pair of first forming rollers 241, a pair of second forming rollers 242, and a pair of third forming rollers 243. The metallic sheets 1 are pressed by the first forming rollers 241, the second forming rollers 242, and the third forming rollers 243 in sequence. The forming roller group 24 presses the metallic sheets 1 against the bonding layers in sequence, the metallic sheets 1 bond with each other via the bonding layers, and a composite sheet 3 having a plurality of metallic layers is finished. Though the metallic sheets 1 are not made of the more expensive metals, the strength of the composite sheet 3, due to the bonding process, would still satisfy industry safety regulation. In one embodiment, the top, middle, and bottom metallic sheets 1 in
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The kinds of the adhesives used are not restricted, as long as the adhesives can bond the metallic sheets 1 with one another securely. The temperature of the set of heating rollers 23 depends on the adhesive applying units 25, and only needs to be high enough for proper adhesive bonding.
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(a) Mix some foaming agents and blowing promoters with a substrate, and then put the substrate which is mixed with the foaming agents and the “blowing promoters” (A raw material for the manufacture of plastics, for example, urea-formaldehyde resin) into an extruder 41. The extruder 41 grinds, heats and extrudes the substrate to become an extruded liquid bar, and then the liquid bar are transported to a mold 42 to be flatten and become a core layer of the product, and then the core layer is cooled via a cooling apparatus (not shown). Wherein the kind of the substrate, the kinds of the foaming agents and the blowing promoters are not restricted. The substrate can be made of polyethylene, or polypropylene, or ethylene-vinyl acetate copolymer, the foaming agents can be made of diazenedicarboxamide, and the blowing promoter can be made of a zinc oxide or stearin cadmium.
(b) Apply adhesives (polymer film or liquid adhesive) onto the surfaces of the core layer by two adhesive applying units 43 with different feeding positions (top and bottom), the adhesives are the lamination agent of the product, and the kinds of the adhesives are not restricted.
(c) Provide two composite sheets 3, and the two composite sheets 3 are coiled around two coiling rollers 44 with different vertical positions (top and bottom). Uncoil the two composite sheets 3, and the composite sheets 3 are transported to a forming roller group 45. The forming roller group 45 presses the composite sheets 3 to contact with the bonding layers, the composite sheets 3 are laminated to the core layer, the core layer is sandwiched between the two composite sheets 3, and the two composite sheets 3 are two surface layers of the product respectively. Furthermore, the two surface layers can be coated with many colors.
(d) cool the product via a cooling unit 46.
(e) guide the product to leave the cooling unit 46 via a guiding unit 47.
(f) the guiding unit 47 guilds the product to move to a cutting unit 48, and the cutting unit 48 cut the product to length.
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The present invention has the following characteristics: Even the metallic sheets 1 are not generally made of more expensive metals, the strength of the composite sheet 3 should still satisfy industry safety regulation, the cost of producing the composite sheet 3 can be effectively reduced, the weight of the composite sheet 3 can be light when compared to using traditional method, so that it is very convenient for users to assemble many of the composite sheets 3.
The description above only illustrates specific embodiments and examples of the invention. The invention should therefore cover various modifications and variations made to the herein-described structures and applications of the invention provided if they fall within the scope of the invention as defined in the following appended claims.
Claims
1. A process of producing a composite sheet, comprising the steps of:
- (a) providing a plurality of metallic sheets;
- (b) bonding the metallic sheets with one another; and
- (c) finishing the bonded composite sheet having a plurality of metallic layers.
2. The process of producing the composite sheet as claimed in claim 1, wherein the metallic sheets are coiled or uncoiled around a coiling roller group before bonding the plurality of the metallic sheets with one another.
3. The process of producing the composite sheet as claimed in claim 1, wherein the metallic sheets are passed through a stretching roller group before bonding the metallic sheets, and the stretching roller group extends, stretches, and flattens the metallic sheets.
4. The process of producing the composite sheet as claimed in claim 1, wherein the metallic sheets have top and bottom contact surfaces, a plurality of adhesive films are placed on the contact surfaces of one of the metallic sheets before bonding the plurality of the metallic sheets with one another, and the adhesive films are heated by a set of heating rollers to become adhesives, and the adhesives are bonding layers of the composite sheet.
5. The process of producing the composite sheet as claimed in claim 1, wherein the metallic sheets have contact surfaces, a plurality of adhesives are coated on the contact surfaces of one of the metallic sheets by singular or multiple adhesive applying units before bonding the plurality of the metallic sheets with one another, and the adhesives are bonding layers of the composite sheet.
6. The process of producing the composite sheet as claimed in claim 1, wherein the plurality of the metallic sheets are passed through a forming roller group after one of the metallic sheets out of the plurality of metallic sheets has formed the bonding layers, the forming roller group presses the metallic sheets to contact with the bonding layers respectively, and the plurality of metallic sheets bond with each other via the bonding layers.
7. The process of producing the composite sheet as claimed in claim 6, wherein the forming roller group includes a pair of first forming rollers with different vertical positions, a pair of second forming rollers with different vertical positions, and a pair of third forming rollers with different vertical positions, therein the radius of each third forming rollers is longer than the radius of each second forming rollers, and the radius of each second forming roller is longer than the radius of each first forming roller, the metallic sheets are pressed by the first forming rollers, the second forming rollers, and the third forming rollers in sequence.
8. The process of producing the composite sheet as claimed in claim 1, wherein the metallic sheets are deformed by a beating tool, a punching tool, or a roller group to become flexuous sheets, and each flexuous sheet has a plurality of first base portions, a plurality of second base portions, and a plurality of bending portion, the bending portions are connected between the first base portions and the second base portions, the vertical position of each first base portion is different from the vertical position of each second base portion, forming a square wave shape.
9-21. (canceled)
Type: Application
Filed: May 23, 2008
Publication Date: Nov 26, 2009
Inventor: Chih-Lin Hsu (Taipei City)
Application Number: 12/153,740
International Classification: B32B 3/28 (20060101); B32B 15/08 (20060101); B29C 65/48 (20060101);