CA1089505A - Injection molded ski and method for producing the same - Google Patents

Abstract

ABSTRACT OF THE DISCLOSURE
An improved injection molded ski having excellent me-chanical properties which comprises an injection molded ski body that is made of thermoplastic resin and provided with a pair of edge receiving portions on the bottom surface thereof, a pair of steel edges attached to the edge receiving portions of the ski body and a sole plate integrally formed by injec-tion molding of thermoplastic resin on the bottom surface of said skit body; and an injection molding method for producing the above ski.

Description

lV~9505 BACKGROUND OF T~E I~VENTION
This invention relates to an injection molded ski and a method for producing the same. More particularly, the inven-tion relates to a novel injection molded ski having excellent properties and an improved injection molding method for produc-ing the same in which the ski is produced by using thermoplastic resin materials.
It is well known in the field of ski manufacturing that skis are produced by means of injection molding of thermoplastic resins. However, except simple and low-grade ones, it has been considered to be quite difficult to produce skis integrally through injection molding by using thermoplastic resins since the attaching of steel edges is not easy.
Further, when steel edges are attached to both the side edges of the sole plate or bottom running surface of a ski body with set screws, stress is set up in screw holes, and if the ski is bent too much, cracks are caused to occur in the portions of screw holes to result in the damage of the ski. Accordingly, even when a ski body and a sole plate are integrally formed together by injection molding, the strength of such ski is inferior to that of conventional ones and still more investi-gation for producing the injection molded skis is required.
The inventor of the present application has made eager . and extensive studies on the production of skis through injectio i molding method, and as the result, the present invention has been accomplished.
BRIEF SUMMARY OF THE INVENTION
It is therefore an object of the present invention to provide a plastic ski which is free from the above-mentioned disadvantages caused to occur in conventional ones.

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Another object of the invention is to provide an improved injection molded ski having excellent strength and other characteristics.
Further object of the invention is to provide an improved injection molding method for producing such skis, by which method quite satisfactory skis can be produced with neither difficulty nor troubles.
According to the present invention, the ski consists of ski body, a sole plate and a pair of steel edges. These members are put tightly together in injection molding process.
The ski body constituting the main portion of a ski is provided with a pair of edge receiving portions on both the longitudinal sides of the bottom surface. Each edge receiving portion is provided with a plurality of projections generally formed at ~, regular intervals, with which projections a steel edge is attached to the ski body. Between the pair of edge receiving portions on the bottom surface of the ski body is an uneven abutting surface to receive thereon the above-mentioned sole plate. After the steel edges are applied to the projections formed on the edge receiving portions, the sole plate is formed on the lower surface of the ski body, in which the sole plate is firmly secured to the uneven lower surface of the ski body and to the projections on the edge receiving portions with interposing the steel edges.
In the method for producing plastic skis of the present invention, the ski body having the edge receiving portions is firstly made by injection molding, the die is then opened to attach a pair of steel edges to the projections oh the edge ; receiving portions of ski body, and finally, the die is again closed with another different half mold and the sole plate is ; lV~5~S

then formed by injection molding.
In accordance with the method of the present invention, the bonding of the ski body, sole plate and steel edges are easily and reliably performed as compared with the conventional method because the sole plate is adhered to the ski body in fused state. Therefore, even when the ski of the present invention is intensely bent in the use, the component parts are hardly peeled off. Further, the steel edges are attached to the ski body through the above-mentioned improved injection molding process without using any set screws so that the edges are easily secured to the ski body without the troublesome work as that caused in the conventional method.
In addition to the above advantages, the skis produced through the method of the present invention have other merits in the excellence of several mechanical properties such as bending strength, fatigue deformation, torsional rigidity, and ~` impact strength.
Thereare various kinds of thermoplastic resins appli-cable to the above-disclosed injection molding method, however, exemplified as the most ~ypical ones are ABS (acrylonitrile-butadiene-styre~e) resin and glass fiber reinforced ABS resin.
Like the ordinary skis, those of the present invention may also be finished on the surfaces thereof by using various kinds of coating materials and coloring materials.
BRIEF DESCRIPTION OF THE DRAWINGS
These and other objects and features of the invention will become more apparent from the following description taken in connection with the accompanying drawings in which:
Fig. 1 is a longitudinal sectional view of an embodi-ment of the ski of the present invention;

1(3h5'505 Fig. 2 is a cross-sectional view of the same embodi-ment~
Fig. 3 is a perspective e~ploded view of the same embodiment taken from the under side;
S Fig. 4 is a cross-sectional view of a set of molds for injection molding;
Fig. 5 is a cross-sectional view of the same molds which are fed with the material for ski body;
Fig. 6 is a cross-sectional view of the female mold carrying a molded ski body to which a pair of steel edges are fitted;
Fig. 7 is a cross-sectional view of a set of molds in which the female mold is applied with a male mold different from that of Fig. 4 or 5;
Fig. 8 is a partial cross-sectional view of another embodiment of a set of molds;
Fig. 9 is a schematic illustration of the state of bend-ing tests;
Fig. 10 is a graphic chart showing the results of bend-: ing tests;
Fig. 11 is a schematic illustration of the state of fatigue deformation tests; and Fig. 12 is a graphic chart showing the results of fatigue deformation tests.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
Referring now to the accompanying drawings, some embodiments of the present invention will be described in the following.
A ski body 1 having a configuration similar to that of conventional one is made by in]ection molding with using a l()~SO~

therm~plastic resin, for exQmple, ~5 resin containing 10~ of glass fiber. As shown in Fig. 2, the ski body 1 has a smooth top surface and a corrugated or grooved bottom surface 3. The grooves formed in the bottom surface 3 are arranged in a plurality of rows along the longitudinal sides of the ski body 1. On both the longitudinal edge portions of the bottom surface

3 are formed edge receiving portions 2 which are provided with a plurality of projections 5 as shown in Fig. 3. The projec-tions 5 are generally formed at regular intervals for receiving the apertures of the below-mentioned fixing pieces 4b of the steel edges 4, and the length or height of each projection 5 is made somewhat larger than the thickness of the fixing piece 4b of the steel edge 4.
The steel edge 4 is made of a long, flat and angled steel and the edge body 4a is provided with a plurality of fix-ing pieces 4b at regular intervals interposing therebetween a plurality of narrow cuts 4c. Formed in the middle portion of each fixing piece 4b is an aperture 4d which is to be caught by the above-mentioned projection 5. Thus when the steel edges

4 are attached to the ski body 1, the projections 5 on the edge receiving portions 2 are fitted into the respective apertures 4d of the fixing pieces 4b and the steel edges 4 are pressed against the edge receiving portions 2. In order to attach the . steel edges 4 firmly to the ski body- 1, if desired, the protrud-ing ends of the projections 5 may be melted down into the form like a rivet head.
Then the bottom surface 3 of the ski body 1 is applied with a sole plate 6 by injection molding of a thermoplastic resin as ABS resin. As shown in Fig. 2, the top or upper side of the sole plate 6 adheres tightly to the grooved bottom . .

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surface 3 of the ski body 1 and the bottom surface, that is the running surface, of the sole plate 6 is aligned with the lowermost edges of the edge bodies 4a. When this sole plate 6 is formed by injection molding, the molten resin is brought into contact with the grooved bottom surface 3 and the protrud-ing ends of the projections 5 and then it is solidified as it stands. Thus the steel edges 4 are tightly held between the ski body 1 and the sole plate 6, in addition, they are firmly fixed by the projections 5. With the above-disclosed structure, the steel edges 4 are not released as far as the projections 5 are not damaged. Further, since the sole plate 6 is formed on the under side of the ski body by injection molding, the sole plate 6 can be firmly bonded to the ski body 1 and even when the ski is bent, the sole plate 6 is not peeled off from the ski body 1 and the steel edges 4. Therefore, the ski of the present invention having the above-disclosed unified structure is safe and durable in practical uses.
In the following, the injection molding method of the present invention for producing the above-disclosed ski will be : explained with reference to the accompanying drawings, especial-ly to Figs. 4 to 8.
As shown in Fig. 4, a female mold 10 and a first mold half 12 are closed by pùtting them together. The female mold 10 has mold surfaces for forming the top and both side surfaces of a ski body 1. It is to be noted that the positioning of the cavity 11 is upside-down relative to the foregoing Figs. 1 to 3.
The first mold half 12 has a mold surface 13 to form the bottom surface 3 and the edge receiving portions 2 of the ski body 1.
Further, a plurality of holes 14 are formed along the longitudi-nal sides (perpendicular to Fig. 4) of the mold surface 13.

. . . , , , ! ~ , lVt~950:j The mold surface 13 of the first mold half 12 is a little lowered into the cavity 11 of the female mold 10. The distance between the boundary plane of both the mold halves 10, 12 and the surface to form the edge receiving portions (indicated by "Q" in Fig. 5) coincides with the height of edges 4.
In the next step as shown in Fig. 5, the injection nozzle 16 is brought into contact with the sprue 15 of the first mold half 12 and molten thermoplastic resin (e.g. AsS resin containing 10% of glass fiber) is then injected into the cavity 11 to form a preliminary molding of the ski body 1 having integral parts of edge receiving portions 2 and a plurality of projections 5.
In the above embodiment, the sprue 16 may be formed in any portion of the ski body 1, however, it may be advantageous-ly positioned at the tail end of the ski body 1 in order to make the material flow unidirectional and to prevent the ~! occurrence of dead points of material.
The set of molds is then opened byremoving the first mold half 12, and the female mold 10 with the molded ski body 1 is shifted to the position of a second mold half 17. A pair ~ of steel edges 4 are respectively fitted into the spaces 18 ,i which are previously formed by the mold surface 13 of the first mold half 12. When the steel edges 4 are attached, the apertures 4d of fixing pieces 4b are fitted to the projectlons

5 on the edge receiving portions 2 so that the lateral move-ment of the edges 4 can be avoided. The bottom surfaces (upper side in Fig. 6) of the edges 4 are positioned on the same level as the upper surface (parting line) of the female mold 10.
Therefore, when the second mold half 17 is applied to the female mold 10, the steel edges 4 are firmly and accurately placed on ~, . ~ - , lO~S~

the edge receiving portions 2 of the ski body 1. ' In place of the above procedure, if desired, the molded ski body 1 can be once taken out from the female mold 10 and the steel edges 4 are fitted to the edge receiving portions 2 outside the female mold 10. And after that, the assembly may be again inserted into the female mold 10 shifted under the second mold half 17 or another similar female mold 10 under the second mold half 17. With such process, a special molding machine is not required since the shifting of the female mold 10 can be avoided.
Further, in another embodiment, the ski body 1 may be prov,ided with a continuous ridge 5a on the inside of each edge receiving portion 5 as shown in Fig. 8. With such structure, ~'~ the fitting of steel edges 4 can be made more reliable. Still , 15 further, after the fitting of steel edges 4 to the edge receivin . portions 2, the protruding end of each projection 5 may be thermally pressed down like rivets as shown in Fig. 8. It will be understood that these modified structures are effectual for the reliable securing of the steel edges 4 to the ski body 1~
After the fitting of steel edges 4, the second mold half 17 is placed on the female mold 10 carrying the ski body 1 with the steel edges 4 as shown in Fig. 7. The second mold half 17 , ;` has a mold surface 19 that forms the running surface of the ski.
- The mold surface 19 has a flat face generally positioned on the same level as the parting line between the molds, and a middle longitudinal projection to form a cross-sectionally arcuate groove in the running surface of a ski to be formed.
, After the closing of the second mold half 17, an injection nozzl ,, 21 is brought into contact with the inlet of a sprue 20 and molten thermoplastic resin (for example ABS resin~ is injected 1~

into the space between the ski body 1 and the mold surface 19, thereby forming a sole plate 6 of the ski. In this process, the steel edges 4 are tightly secured between the longitudinal sides of the sole plate 6 and the edge receiving portions 2 of the ski body 1, at the same time, the protruding ends or flattened ends of the projections 5 (and 5a) are well bonded to the material of sole plate 6.
As disclosed above, the durability of ski is excellent as compared with that of the conventional ones because the ski body 1 and the sole plate 6 are integrally formed by using thermoplastic resins without the use of any adhesive agent.
Further, the steel edges are also integrally secured between the ski body and the sole plate by injection molding, accordingly, the concentration of stress to attaching screws can be success-fully avoided. Therefore, the ski of the present invention can be prevented from the peeling of the sole plate and loosening or breaking off of the steel edges. Furthermore, the integral formation of the ski body and the sole plate can be performed by using the same female mold in a continuous manner, so that any special technique is not required and the injection molding : of the ski body and the sole plate with different thermoplastic materials can be quite easily carried out. Therefore, the present invention is very useful in view of ski manufacturing.
Performance Tests 1. Flexural Rigidity and Maximum Bending Strength ~ The skis of the present invention were produced accord-; ing to the above-disclosed method by using ABS resin reinforced with 10~ by weight of glass fiber for ski body portions and sole ABS resin for sole plates, and they were compared with commercial ly available skis as follows:

lV~'~50~i Table 1. Skis Used for Tests Symbol Description Length L (below) A Semi-plywood ski 110 cm 830 mm B Fiber glass reinforced 110 cm 830 mm plastic ski C Ski of this invention 110 cm 830 mm D Fiber glass rei,forced 140 cm 1130 mm plastic ski E Semi-plywood ski 140 cm 1130 mm F Ski of this invention 140 cm 1130 mm .
In the above Table 1, the skis A, B, D and E were bought from the market. Each ski 30 was supported as shown by the solid lines of Fig. 9, and a load 31 was applied to the center of the ski 30 between the supports 32. The initial dis-tance between the supports 32 was L cm. The ski 30 was gradually bent down by the load 31 as shown by the dash lines in the same figure and finally the ski 30 was broken.
The relation between the load (kg) and bending ~d, mm~, and the maximum bending strength (kg) were measured, the result of which are shown in Fig. 10. The numerals indicated at the free ends of resultant curves are the maximum loads (kg) and the ,~ bendings (d, mm) when the skis were broken.
From the results shown in Fig. 10, it may be understood that the skis of this invention are excellent in view of the flexural rigidity and maximum bending strength as compared with those of the conventional ones.
2. Fatigue Deformation Each ski 30 was set as shown in Fig. 11 between the supports 32 and it was bent by applying a load 31 for the stroke I.'Vh~

S mm. The bending operation was continually repeated at 45 to 50 cycles per minute and at each of 500, 1000, 2000, 3000, 4000 and 5000 bendings, the vertical distance between the horizontal center of both supports 32 and the center of a ski (indicated by the symbol dl in Fig. 11) was measured. Thus obtained value d1 was compared with the initial arch bend do as shown in Fig.ll.
Thus the value of arch bend durability (~) was obtained according to the following equation:
dl - x 100 = Arch bend durability The data of the skis used for the tests and some test conditions are shown in the following Table 2.
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Table 2. Skis and Test Conditions 15Symbol Description Length (mm) (mm) (mm) A Finly foamed poly- 110 830 7.4 80 styrene , B Ski of this invention 110 830 7.2 80 C -do.- 140 1130 11.5 150 ; D Semi-plywood ski 120 930 7.0 80 E Fiber glass reinforced110 830 4.0 80 plastic ski , , , , ~, The skis A, D and E were obtained from the market and the skis B and C were made according to the method of this in-vention by using ABS resin reinforced with 10% by weight of glass fiber for ski bodies and ABS resin for sole plates. The results of the tests are shown in Fig. 12. ~
The ski A was broken before 3000 bendings even though the fatigue deformation of ski A was small.

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~urther, it will be understood from the res~lts shown in ~ig. 12 that the fatigue deformations of the skis of this invention are very small as compared with those of the commercially available ones.
3. Impact Resistance In this test, each ski was loaded with a 20 kg weight, then caused to glide on a horizontal plane by an air cylinder and allowed to collide with a vertical solid wall surface at a speed of 5.4 m/s (19.5 km/hr). In the tests, three kinds of 140 cm skis were used. A plywood ski was broken off at the point near the front bent end. Another glass fiber reinforced plastic ski was folded at a similar point. The ski of this invention similar to those used in *he foregoing tests was bent to some e~tent but it was not broken off.
From the abové tests, it will be understood that the mechanical properties of the ski produced according to the pre-sent invention are quite good. This is owing to the fact that the ski body, sole plate and a pair of continuous steel edges are integrally and firmly joined together by injection molding.
Although the present invention has been described in connection with a preferred embodiment thereof, many variations and modifications will now become apparent to those skilled in the art. It is preferred, therefore, that the present invention be limited not by the specific disclosure herein, but only by the appended claims.

Claims (18)

The embodiments of the invention in which an exclusive property or privilege is claimed are defined as follows;-

1. A ski comprising, in combination:
a molded ski body having a pair of edge receiving portions extending longitudinally along the sides of the ski body on the bottom surface thereof;
each of said edge receiving portions being provided with a plurality of projections arrayed along the length thereof at regular intervals;
a pair of edge members each having a plurality of fixing pieces on one side thereof and adapted to be attached to the ski body by mating with the projections on the edge receiving portions of the ski body;
the height of each of said projections being slightly larger than the thickness of the fixing pieces of the edge members to be secured thereon;
the bottom surface of the ski body being irregular in shape; and a sole plate integrally formed to mate with the irregular bottom surface of the ski body, whereby said sole plate covers the bottom surface of the ski body and, together with the projections formed on the edge receiving portions, firmly holds the steel edges between the sole plate and the edge receiving portions of the ski body.

2. The ski of claim 1 wherein each of the fixing pieces contains an aperture therein for receiving one of the projections.

3. The ski of claim 2 wherein a space is inter-posed between adjacent pairs of the fixing pieces.

4. The ski of claim 1 wherein a space is inter-posed between adjacent pairs of the fixing pieces.

5. The ski of claim 1 wherein the ski body is made of thermoplastic resin.

6. The ski of claim 5 wherein each of the fixing pieces contains an aperture therein for receiving one of the projections.

7. The ski of claim 6 wherein a space is inter-posed between adjacent pairs of the fixing pieces.

8. The ski of claim 5 wherein the ski body is formed by injection molding.

9. The ski of claim 8 wherein the sole plate is formed by injection molding onto the bottom surface of the ski body.

10. the ski of claim 9 wherein each of the fixing pieces contains an aperture therein for receiving one of the projections.

11. The ski of claim 10 wherein a space is inter-posed between adjacent pairs of the fixing pieces.

12. A ski produced according to the injection molding process by the steps of:
injection molding a ski body from a thermoplastic resin, the ski body having an irregular bottom surface and a pair of edge receiving portions extending longitu-dinally along the sides thereof, each of said edge receiving portions being provided with a plurality of projections arrayed along the length thereof at regular intervals, the height of each of said projections being slightly larger than the thickness of the fixing pieces of the steel edges to be secured thereto, attaching a pair of steel edge members to the bottom surface of the ski body, one of each of said edge members being attached on each side of said bottom surface, each of said edge members having a plurality of fixing pieces on one side thereof for attachment to said edge receiving portions by mating said fixing pieces with said projections formed on said edge receiving portions; and injection molding a sole plate onto the bottom surface of the ski body to cover said bottom surface and join with the projections formed on the edge receiving portions thereof to firmly hold the steel edges between the longitudinal sides of the sole plate and the edge receiving portions of the ski body, whereby an integrally formed ski comprised of said ski body, steel edges and sole plate is produced.

13. An injection molded ski according to claim 12, wherein said ski body is made of ABS resin reinforced with fiber glass and said sole plate is made of ABS resin.

14. An injection molded ski according to claim 12 wherein said edge receiving portions are provided with ridges on the respective inside brinks of the edge receiving portions.

15. A method for producing injection molded skis which comprises:
(A) closing a pair of molds including a female mold having mold surfaces for forming the top surface and both side surfaces of a ski body and a first mold half having mold surfaces to form a bottom surface and edge receiving surfaces having a plurality of projections, of said ski body, and injecting molten thermoplastic resin into the cavity of said closed molds to form a ski body having edge receiving portions with said projections;
(B) opening said molds by removing said first mold half from said female mold and fitting a pair of steel edges to said edge receiving portions by fixing said steel edges to said projections on said edge receiving portions; and (C) closing said female mold with a second mold half forming another cavity between said ski body and said second mold half, and injecting thermoplastic resin into said another cavity to form a sole plate which is integrally joined with said ski body and said steel edges.

16. A method for producing injection molded skis as claimed in claim 15 wherein after the fitting of said steel edges to said edge receiving portions in clause (B), the protruding ends of said projections are thermally pressed down.

17. A method for producing injection molded skis as claimed in claim 15 wherein said injection molded ski body is once taken out from said female mold after the mold opening and before the fitting of said steel edges in clause (B) and said ski body that is provided with said steel edges are again fitted into the female mold before said female mold is closed with said second mold half in clause (C).

18. A method for producing injection molded skis as claimed in claim 15 wherein ABS resin reinforced with fiber glass is used for the injection molding in clause (A) and ABS resin is used for the injection molding in clause (C).