Surface protecting material

A surface protecting material is prepared by having a soft aluminum foil having a thickness of 15 to 50.mu. superposed on the surface of a substrate of plastic film such as polyethylene, polyvinyl chloride, or polyester and further having a layer of resin containing at least 10% fluorine resin or silicone resin and having not more than 1.mu. in surface coarseness superposed directly on the surface of the aluminum foil or indirectly thereon through the medium of a colored layer formed thereon. This surface protecting material is useful for decorating and repairing various kinds of goods and to obtain a flat surface thereon.

BACKGROUND OF THE INVENTION 
The present invention relates to a surface protecting material. The surface 
protecting material is suitable for decoration and repair of room 
interiors, furniture, kitchen articles, signboards, bulletin boards, 
bridges, swimming pools, and inner and outer surfaces of water storage 
tanks. It is also suitable for decoration and repair of roofs and inner 
and outer surfaces of plants, houses, automobiles, refrigerator cars, 
ships and boats, and surfaces of multi-story buildings, sashes, smoke 
stacks and towers. Additionally, it is suitable for decoration and repair 
of sliding surfaces such as surfaces of skis, sleds, and slides; surfaces 
which are liable to gather dirt and require cleaning for removal of 
adhering matter, and other surfaces which are required to maintain a 
sliding property. Finally, it is suitable for protection of eaves and 
roofs against damage from heavy or fallen snow. 
Previously, processed papers and plastic sheets have been used for the 
decoration of room interiors, furniture, and other similar articles. 
Because of their poor resistance to water and weather conditions, however, 
they have proved unsuitable for use on kitchen articles, bathroom 
interiors, cooking tables, as well as roofs of houses and automobiles 
which by their nature are exposed to moisture. Colored resin-coated iron 
sheets, for example, have been available in the market as roofing 
materials. Such roofing materials, however, are disadvantageous in that 
they are neither readily used by laymen nor easily conformable to varying 
contours and they inevitably require the use of special skill. 
Metallic roofs such as roofs of galvanized iron sheets often have their 
surfaces painted for protection from the elements. In the course of 
prolonged exposure, however, the coatings peel, gather rust, and lose 
surface smoothness. Such adverse developments have been previously 
overcome by the application of paint. This process, however, requires 
repeated application of paint. Moreover, when the metallic roofs become so 
deteriorated that holes develop and rainwater leaks through the roof they 
cannot be repaired by laymen. This problem has previously not been solved. 
In the case of swimming pools, tanks for storing hot or cold water, 
air-conditioners for use in buildings, tanks for waste water disposal, and 
pipes which collect fur or slime and algae on their wall surfaces, and 
ships which attract marine algae and shells on their external surfaces, a 
method has been adopted involving coating such wall surfaces with 
rustproofing paints, algicides and anti-shell agents. The paints and other 
agents applied to surfaces according to this method, however, present a 
problem in that they are poisonous. Also, in the case of swimming pools, 
since chlorine-based reagents are used for sterilization purposes, a 
problem arises in that ordinary materials yield to the action of such 
reagents. 
In the case of refrigerator cars and cold storage containers their inner 
wall surface gather moisture from the ambient air so that they must be 
periodically cleaned to remove sheets of ice. An additional problem arises 
in that such moisture adhered to the contacting portions of doors of the 
refrigerator cars and cold storage containers is frozen, thereby 
preventing the doors from opening smoothly. To counteract ice formation, 
antifrost agents have been used, but this method, however, has not been 
very effective. 
In locations experiencing heavy snowfall, inhabitants are burdened with the 
task of removing snow from the roofs of their houses several times during 
the winter. This work demands much time and labor. 
SUMMARY OF THE INVENTION 
This invention is directed to solving the various problems mentioned above 
by providing a surface protecting material which can be easily used even 
by laymen for decorating and repairing articles of furniture and other 
items. 
An object of this invention is to provide a surface protecting material 
which readily forms a surface capable of peventing adhesion of muddy 
water, ink, paint, oils and fats, dirt, dust, snow, ice, water, and water 
drops and enables such adhesive matter to fall off naturally or to be 
easily swept or wiped off. 
Another object of this invention is to provide a surface protecting 
material which forms a surface capable of preventing adhesion of fur, 
slime, algae, marine algae, and other living organisms such as shells and 
enables such adhesive matter to be easily removed. 
Yet another object of this invention is to provide a surface protecting 
material which readily forms a surface resistant to corrosion. 
Still another object of this is to provide a surface protecting material 
which readily forms a slippery surface. 
A further object of this invention is to provide, with a surface that 
requires no maintenance for walls of smoke stacks, towers, and multi-story 
buildings which, because of great height, do not allow easy access to 
cleaning.

DETAILED DESCRIPTION OF THE INVENTION 
The surface protecting material of the present invention is characterized 
by having a layer of soft aluminum foil having a thickness of 15 to 50.mu. 
superposed on the surface of a substrate of plastic film such as 
polyethylene, polyvinyl chloride, or polyester and further having a layer 
of resin containing at least 10% fluorine resin or silicone resin having 
not more than 1.mu. in surface coarseness superposed directly on the 
surface of the aluminum foil layer or indirectly thereon through a colored 
layer. Optionally, the surface protecting material of the present 
invention may have a self-adhesive applied to the rear surface of the film 
substrate and a release paper superposed on the surface of the applied 
layer of self-adhesive agent. 
The plastic film to be used as the substrate in this invention is a film, 
particulary a soft film, of polyethylene, polypropylene, polyester, or 
polyvinyl chloride which has a thickness of not more than 100.mu., and 
preferably has a thickness of 10 to 50.mu.. The thickness of the film is 
not desired to be too great, since the fabricability, workability and cost 
of the film is dependent upon the thickness of the film. If the film is 
too thin, however, it tends to wrinkle while it is being handled during 
the fabrication of the surface protecting material. Further, if the film 
of a surface protecting material applied to the surface of a metallic 
product is too thin, the material is disadvantageous since pinholes or 
ruptures of the film may be created during the fabrication of the surface 
protecting material and the superposed aluminum foil would then be 
directly or indirectly in contact with the metallic product to induce 
galvanic corrosion. For the prevention of such troubles and for permitting 
the application of an adhesive agent, the film is required to have a 
certain thickness, preferably in the range of 10 to 50.mu.. The plastic 
film used in the surface protecting material is highly effective in 
protecting the aluminum foil from corroding. 
From the standpoint of workability, the aluminum foil is desired to be 
soft. It may have a glossy or matte surface. The thickness of the aluminum 
foil is selected to be in the range of 15 to 50.mu.. When desired, the 
aluminum foil may be printed or colored. For coloration, deposition of a 
transparent colored coating layer proves advantageous where the metallic 
gloss of the aluminum foil is required to be retained. The stiffness 
derived from the presence of the aluminum foil gives thd surface 
protecting material good workability as a repairing material. The presence 
of the aluminum foil also allows the surface protecting material to 
withstand heat and imparts thermal and dimensional stability to the 
surface protecting material and prevents edge curling and shrinkage. 
Further, the aluminum foil satisfactorily intercepts various rays of light 
and reflects heat rays to prevent an otherwise possible increase of 
temperature inside the surface protecting material. Optionally, the 
colored layer may be formed as a black-colored layer for permitting 
absorbance of solar heat to contribute to the utilization of solar heat. 
With respect to the layer of resin containing a fluorine resin or a 
silicone resin, examples of fluorine resin that may be used include 
polytetrafluorethylene (PTFE), tetrafluoroethylene-perfluoroalkylvinyl 
ether copolymer (PFA), tetrafluoroethylene-hexafluoropropylene copolymer 
(FEP), polychlorotrifluoroethylene (PCTFE), tetrafluoroethylene-ethylene 
copolymer (ETFE), chlorotrifluoroethylene-ethylene copolymer (ECTFE), 
polyvinylidene fluoride (PVDF), and polyvinyl fluoride (PVF). 
Examples of the silicone resin that may be used include methyl silicone and 
phenylmethyl silicone. 
Examples of the base resin which can contain such fluorine resins or 
silicon resins include resins of peculiar qualities such as polysulfone, 
alkyd resin, amino resin, polyester resin, phenolic resin, allyl resin, 
polyaryl sulfone, urethane resin, polybenzimidazole, polyamide-imide, 
polyphenylene sulfide, polyphenylene, polyphenylene oxide, polyoxybenzoyl 
ester, polyether sulfone, polyimide, epoxy resin, polyethylene, 
polypropylene, ionomer, acrylic resin, nylon, and polyvinyl chloride. Such 
a resin may be present in any form such as a dispersion, an emulsion, a 
solvent-based coating, a powder, or fine particles. This resin, containing 
a suitable proportion of the aforementioned fluorine resin or silicone 
resin, is deposited in the form of a layer. 
The content of the fluorine resin or silicone resin may range from 10 
weight percent up to and including 100 weight percent. To accomodate the 
peculiar properites possessed by the base resin, the content of the 
fluorine resin or silicon resin is preferably in the range of 50 to 99 
weight percent. 
The fluorine resin or silicone resin is used in the layer of resin because 
it posesses water repellency, wear resistance, minimal friction 
(lubricity), resistance to chemicals, resistance to solvents, resistance 
to the action of food stains, resistance to oil, resistance to weather 
conditions, heat resistance, thermoresistance adhesion, good electric 
properties, and flame retardancy. These properties are particularly 
significant when the surface protecting material of the present invention 
is applied as a roofing material for houses, a chute for snow dumped from 
roofs in snowy areas, a decorative or reinforcing coating, a covering for 
the inner walls of refrigerator cards or blades of ventilation fans, as 
bulletin boards and signal boards, and skis and boats, and further as 
decorative or repairing coatings for the inner walls of structures likely 
to be smeared with oil, ink, and blood, such as bathrooms. In the former 
applications, moderately low friction is necessary for ensuring a smooth 
fall of snow or preventing the adhesion of sand, dust and dirt. 
Weatheraility is also an important requirement. In the latter appliations, 
prevention adhesion of ice sheets is an indispensable requirement in 
addition to the requirements of low friction, resistance to the action of 
food stains, and resistance to oil. The surface protecting material of the 
present invention may also be applied to the inner and outer surfaces of a 
smoke stack for the prevention of soot deposition. To offer the properties 
required for such applications, the fluorine resin or silicone resin, 
depending on the particular type selected, may be present at 100 weight 
percent. By suitably selecting the type and mixing ratio of the base resin 
and by varying the amount of the added fluorine resin or silicone resin, 
the desired properties may be imparted to the layer of resin. 
The formation of the aforementioned layer of resin in the manufacture of 
the surface protecting material of the present invention may be effected 
by applying the resin solution directly to the surface of the aluminum 
foil. It may also be accomplished by first forming a film of the resin 
solution by any known method and then applying the film to the surface of 
the aluminum foil with, or without, the aid of an adhesive agent. 
For the layer of resin to acquire the aforementioned properties, it is 
desired to have a surface coarseness of not more than 1.mu. in 
irregularity. To produce a surface with this degree of flatness, a molten 
freshly extruded film may be pressed with rolls having a surface 
coarseness of not more than 1.mu.. Also, the resin solution may be applied 
to the surface of a glass or metallic plate having the aforementioned 
degree of coarseness to form a film thereon and then removing the film 
from the plate. 
In the formation of the layer of resin, the layer is preferably baked when 
it contains a fluorine resin. Depending on the type of resin, the film, 
after being dried, is baked at a temperature in the range of 200.degree. 
to 450.degree. C. under atmospheric or reduced pressure. 
The adhesion of resin film in the formation of the layer of resin is 
preferably effected by dry lamination techniques. It may also be effected 
by the application of both heat and pressure. Typical examples of the 
adhesive used in this case are polyurethane and acrylic resin. 
When the surface protecting material is intended for use as a roofing 
material, the layer of resin must have a sufficient thickness to endure 
harsh conditions, resist weather conditions, offer durability, and 
withstand the friction of sliding snow. If the thickness of the resin 
layer exceeds 50.mu., the fabricability and workability of the surface 
protecting material are deteriorated and the cost of the material are 
increased. Therefore the thickness of the resin layer preferably is not 
more than 50.mu.. Generally, it is selected in the range of 20 to 40.mu.. 
For application of an adhesive to the rear surface of the film substrate 
any of the self-adhesive agents known in the art must be used. The 
adhesive agent is applied in a thickness within the range of ordinary 
thickness of adhesive agents, i.e. from 10 to 100.mu., and preferably in 
the neighborhood of 40.mu.. 
Ordinary silicone-treated paper or polyethylene film may be used as the 
release paper. When a small thickness of surface protecting material of 
the present invention is designed to be used, the release paper preferably 
has a relatively large thickness. 
Since the surface protecting material of the present invention has a 
non-sticky surface, it may be wound in a coil in much the same way as 
ordinary self-adhesive tape is coiled, with no release paper attached to 
the surface of the self-adhesive. 
The surface protecting material of the present invention may be used, as 
described above, in the form of a tape. It may also be produced in the 
form of roll having a width of 500 to 1000 mm. or even more. Of course, it 
may be produced in the form of a flat sheet. 
A specific construction of the surface protecting material of the present 
invention will now be described with reference to the accompanying 
drawings. 
FIG. 1 is an enlarged cross section illustrating a basic construction of 
the surface protecting material of the present invention. In the 
illustrated embodiment, aluminum foil 2 and a layer of resin 3 are 
superposed on the surface of a film substrate 1 with self-adhesive agent 4 
and release paper 5 applied to the rear surface of substrate 1. 
FIG. 2 illustrates a second embodiment which involves the use of adhesive 6 
for the superposition of the aluminum foil 2. FIG. 3 illustrates a third 
embodiment in which a printed colored layer 7 is formed on the surface of 
the aluminum foil 2 and the surface layer of resin 3 is superposed through 
the medium of an adhesive 6. 
Now, the effect of the surface protecting material of the present invention 
will be described with reference to certain test examples. 
Test Examples 1 (wind tunnel test) 
A polypropylene film substrate having a thickness of 50.mu., a soft 
aluminum foil having a thickness of 40.mu. and a surface resin layer of 
polyvinyl fluoride having a thickness of 25.mu. were laminated in a 
construction as shown in FIG. 1. A self-adhesive agent was applied to the 
entire rear surface of the substrate to complete the surface protecting 
material of the present invention. Assuming that this surface protecting 
material would be used as a roof repair material, its behavior under wind 
pressure was tested. 
The test was performed by preparing an iron sheet 11 having support points 
12 projected in the form of cross pieces along opposite ends separated by 
450 mm. as illustrated in FIGS. 4-6, stretching a given specimen, A-D, 
between the support points 12, fixing the opposite ends of the specimen to 
the support points 12 with clips 13, and then exposing the specimen to 
wind pressure. The results of the test were rated by visual inspection of 
the test specimen. The results are shown in Table 1. 
Specimens A and B, had self-adhesive agents 4 applied to 150 mm. and 50 mm. 
of the rear surface of the substrate respectively, as illustrated in FIGS. 
4-5. Specimen C had self-adhesive 4 applied to the entire rear surface of 
the substrate. Specimen D had the identical surface protecting material 
construction of specimen C but without the aluminum foil. 
TABLE 1 
______________________________________ 
Speci- 
Wind pressure 
Wind velocity 
men (kg/mm.sup.2) 
(m/sec.) Results 
______________________________________ 
A -80 35 The specimen inflated. 
B -160 50 The specimen inflated. 
C -280 66 Absolutely no change. 
D -160 50 The specimen inflated. 
______________________________________ 
From the data in Table 1, it is apparent that the specimen having 
self-adhesive applied to the entire surface endured a fairly high wind 
velocity. In contrast, speciment D which did not contain aluminum foil, 
had a low stiffness and failed to conform to the irregular surface of the 
iron sheet of the test stand, and consequently, was observed to bulge and 
come off with wind pressure. 
Test Example 2 (weatherability of self-adhesive agent) 
Specimens of the following constructions were prepared for the 
weatherability test. 
Specimen 1--Polyvinyl fluoride (25.mu.)/self-adhesive agent 
Specimen 2--Polyvinyl fluoride (25.mu.)/aluminum foil 
(25.mu.)/polypropylene (50.mu.)/self-adhesive agent 
The self-adhesive was an acrylic resin type and was applied by dry 
lamination techniques. 
The aforementioned specimens, cut in the size of a 10 cm. square, were 
applied to the surface of a galvanized iron sheet and subjected to a 
sunshine-dew cycle test of exposure to sunshine for 60 minutes and to dew 
condensation for 60 minutes. 
In the test, the specimen 1 sustained peeling along the edge after standing 
300 hours, while specimen 2 of the present invention showed absolutely no 
sign of peeling even after standing 1000 hours. This sharp contrast 
indicates that the aluminum foil effectively intercepted solar rays, 
especially ultraviolet solar rays. 
The surface protecting material of the present invention, as described 
above, has a layer resin containing fluorine resin or silicone resin which 
excels in various properties such as peelability, lubricity, and 
weatherability, superposed on a soft plastic film through the medium of 
soft aluminum. This surface protecting material possesses flexibility and, 
at the same time, exhibits the property of conforming to the irregular 
contour of a given surface under treatment. Particularly, the 
incorporation of aluminum foil which transfers heat, intercepts light, and 
stops the passage of gas, protects the adhesive agent and the substrate 
film against deterioration and enables the surface protecting material to 
enjoy a long service life. further, since the surface protecting material 
has a self-adhesive applied to the entire surface with release paper 
covering the layer of self-adhesive, it is incapable of wrinkling while it 
is being handled. In the actual use of the surface protecting material, it 
can be easily applied to a given surface sequentially from one end to the 
other by peeling off the release paper and, at the same time, 
press-fitting the peeled-off portion. In this manner, even a layman can 
simply apply this material to a surface of great area without causing air 
to be entrapped in the interface and without wrinkling the material. If in 
material of this kind used for repairing a roof, wrinkles are created or 
air is entrapped in the interface between the applied material and the 
surface of the roof, the voids in the interface may cause the material to 
peel off in strong wind or to be washed away by sliding snow. Further, the 
oxygen in the trapped air has the possibility of oxidizing the 
self-adhesive agent. In the case of the surface protecting material of the 
present invention, however, the flexibility of the plastic substrate and 
the shape-retaining property of the aluminum foil allows an airtight 
application of the surface protective material to surfaces of the object 
to be applied having various kinds of surfaces, without causing the 
above-mentioned defects. 
Examples of applications in which the surface protecting material of this 
invention proves useful are as follows: 
1. The surface protecting material is applied to the roof and frontages of 
a house in a snowy area to prevent snow from piling at and protruding from 
the edge of eaves in the shape of a sun-visor. 
2. The surface protecting material is applied to the exterior and interior 
of an automobile or refrigerator car, for example, to the inside of a 
fender, or a wheel housing etc. thereof, to prevent muddy water from 
adhering to the covered surface. 
3. The surface protecting material is applied to the inner wall surface of 
a hopper or chute for conveying fine grains, divided particles or powders 
such as plastic chips or flour to decrease the friction and improve the 
lubricity of the surface. It is also applied to the outer wall surface to 
protect it against deposition of such fine particles, or to prevent 
corrosion thereon. 
4. The surface protecting material is applied to the interior of a 
laboratory or surgical operation room or is used for coating the inner 
walls of a plant, a printing house, or a paper cutting room. 
5. The surface protecting material is used for coloring and corrosion 
proofing sashes. 
6. The surface protecting material is used for covering the inner walls and 
particularly a ceiling in a bathroom or other similar room exposed to high 
humidity to prevent the adhesion of waterdrops. 
7. The surface protecting materal is used for coating the outer surface of 
a tower or smoke stack to protect the surface against corrosion and 
preclude the adhesion of soot and dirt. 
8. The surface protecting material is applied to the surface of skis, a 
sled, or a slide to improve lubricity of the surface. 
9. The surface protecting material is applied to the inner and outer 
surfaces of a tank, a swimming pool, a sewage conduit, a water pipe, a 
ship, or a boat to protect the surfaces against corrosion and deposition 
of fur, slime, algae, and shells. It also proves to be effective in 
preventing formation of dew on the surfaces. 
10. The surface protecting material is applied to the inner and outer wall 
surfaces of an outdoor or indoor swimming pool, and particularly to the 
ceiling and walls in the case of an indoor swimming pool, to protect the 
surfaces against corrosion. The surface protecting material can be applied 
to a slide to prevent bather's swimming suits from being worn out by 
friction. 
11. The surface protecting material is used as a surface material for a 
signboard, a sign post, bulletin board or a sticker to protect the surface 
against adhesion of dirt, dust, snow, and rainwater. It is applied to a 
bridge or a girder of a bridge to protect the surface against adhesion of 
defiling matter and prevent it from corrosion. 
12. The surface protecting material is used for covering the inner and 
outer walls of a house for protection against defilement. It is also used 
on furniture and kitchen articles for the same purpose. It is applied to a 
roof or the upper surface (roof top) of a concrete building or a veranda 
for the prevention of water leakage. 
13. In a snowy area, the surface-protecting material is applied to the 
joint faces of a house door or to a car door to preclude the possibility 
of the door being stuck with hard frozen ice. It is similarly used on the 
door of a freezer or a refrigerator car. 
The conventional surface protecting material which has only a fluorine 
resin superposed on a substrate has suffered from the disadvantage that it 
sustains cracks because it does not easily withstand a change in 
temperature. The surface protecting material of the present invention, 
however, is free from this trouble because it employs an aluminum foil. 
When it is used for roof repair, for example, it protects the roof from 
leakage of rainwater. It has a salient advantage in that by suitably 
selecting the amount of fluorine resin or silicone resin contained in the 
layer of resin and the kind of the base resin and the mixing ratio 
thereof, desired various properties such as heat resistance, adhesiveness, 
weatherability, durability, low friction, resistance to chemicals, 
resistance to solvents, resistance to the actions of food stains, and 
resistance to oils can be desirably imparted to the produced surface 
protecting material. It will find extensive utility in a wide variety of 
applications and fulfill the demands of the population at large.