KR101370109B1 - Zigzag-type spring, and preparation method thereof - Google Patents

Abstract

The present invention is to select a suitable fiber-reinforced composite material according to the desired strength, elastic modulus, fatigue life and the like, and to easily adjust the width, the number and height of the spring and the like to continuously manufacture the spring and thereby It's about the spring.

Description

Zigzag-type spring and its manufacturing method {ZIGZAG-TYPE SPRING, AND PREPARATION METHOD THEREOF}

The present invention relates to a zigzag spring, and a method of manufacturing the same.

In general, a spring is a mechanical element that absorbs and accumulates energy by using elastic deformation of an object to act as a buffer, and is also called a spring. These springs can be classified in various ways according to shape and shape. Specifically, the spring may be classified into a metal spring and a non-metal spring according to the material, the metal spring is a steel (steel), non-ferrous spring, the non-metal spring is a rubber spring, air spring, liquid spring, fiber Reinforced composite springs. Meanwhile, the spring may be classified into a compression coil spring, a tension coil spring, a conical coil spring, a long coil coil spring, a drop coil spring, a leaf spring, a spring, a torsion coil spring, and a washer spring depending on the shape.

These springs are widely used throughout the industry, from home toys to the automotive and aviation industries. In particular, the spring in the vehicle is the first part to absorb the impact from the road surface transmitted through the tire while supporting the weight of the vehicle, which itself relieves the impact by repeating the bounds. Accordingly, metal springs are most often used in automobiles.

However, due to high oil prices in recent years, the weight of automobiles and transportation equipment is being reduced. Similarly, springs have been attempted to replace metals with fiber-reinforced composites. Recently, FRP coil springs were used in Audi using glass-fiber reinforced plastics. Developed (see FIG. 5). However, these FRP coil springs are difficult to produce in a continuous process due to structural problems, and are currently produced in a batch, thereby reducing productivity. In addition, it is difficult to automate the spring manufacturing process and the production cost is high.

The present invention is to select a suitable fiber-reinforced composite material according to the desired strength, elastic modulus, fatigue life and the like, and to easily adjust the width, the number and height of the spring and the like to continuously manufacture the spring and thereby We want to provide a spring.

The present invention comprises the steps of impregnating a fabric or multi-axis warp knitted fabric, a resin composition comprising a vinyl ester resin or polyester to form a prepreg sheet (prepreg sheet); Obtaining a spring preform sheet in the prepreg sheet by forming a plurality of corrugations extending in the longitudinal direction of the sheet along the width direction of the sheet; Curing the spring preform sheet; And cutting the cured spring preform sheet perpendicularly to the longitudinal direction of the sheet.

The present invention also provides a zigzag spring produced by the above-described manufacturing method.

The zigzag spring manufacturing method of the present invention can continuously produce a large amount of spring, and also can easily adjust the width, the number and height of the spring according to the shock absorber of the vehicle at the time of spring production.

In addition, the zigzag spring produced by the above production method is formed of a fiber-reinforced composite material, and because the fiber volume fraction is high, about 60% or more, the mechanical properties can be improved, and also light and high strength, Excellent chemical resistance and corrosion resistance.

1 is a flow chart schematically showing a method for continuously manufacturing a zigzag spring according to the present invention.
Figure 2 shows an example of a process for continuously manufacturing a zigzag spring according to the present invention.
Figure 3 is a perspective view showing an example of a zigzag spring produced by the manufacturing method according to the present invention.
FIG. 4 illustrates a state in which a plurality of zigzag springs of FIG. 3 are arranged in a vehicle shock absorber.
5 is a photograph of a conventional FRP coil spring manufactured by Audi.

Hereinafter, a method of continuously manufacturing a zigzag spring according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a flow chart schematically showing a method for continuously manufacturing a zigzag spring according to an embodiment of the present invention.

Referring to FIG. 1, first, a fabric or a multiaxial warp knitted fabric 10 is impregnated into a resin composition 20 including a vinyl ester resin or polyester to form a prepreg sheet 30 (S100). .

In the present invention, a woven or multiaxial warp knitted fabric is used as the reinforcing material. Since the woven fabric (or multiaxial warp knitted fabric) can arrange the fibers linearly in a desired direction, it is easy to maintain the strength of the fibers and is not easily deformed, so that a high strength zigzag spring can be obtained. In addition, woven fabrics and multiaxial warp knits are advantageous for mass production because they can be easily woven in widths of about 1 m or more.

The woven fabric is a planar structure having a certain width in which warp yarns and weft yarns are woven by crossing each other down and up, also called woven fabrics. The fabric has various patterns depending on the way of crossing the warp and weft yarns. In the present invention, while weaving the fabric according to the method known in the art, depending on the strength of the final zigzag spring, modulus of elasticity, fatigue life, etc., the thickness of the yarn (tilt, weft), the method of crossing the warp and weft yarn, the width of the fabric, etc. It can be adjusted to weave the fabric.

In addition, the multi-axial warp knitted fabric is a knitted fabric made by weaving the yarn to be reinforced at various angles and the very thin yarn is warp knitted, and the yarn making the ring has little influence on the strength and rigidity and is designed. By it can be arranged at various angles, such as 0 degrees, 90 degrees, 45 degrees, 60 degrees, the thin thread is formed by weaving. Since the multiaxial warp knitted fabric can be woven using additional yarns other than 0 degrees and 90 degrees for reinforcement of strength or rigidity, it is possible to further improve the strength and rigidity of the spring in the desired direction than the fabric.

The multiaxial warp knitted fabric lacks elasticity because the yarn used for strength and rigidity is laid straight, but high strength and rigidity. In the present invention, it is possible to weave multiaxial warp knitted fabrics according to methods known in the art. However, when weaving a multi-axis warp knitted fabric, it is possible to control the strength, elastic modulus, fatigue life, etc. of the final zigzag spring by adjusting the thickness of the yarn, the angle of the yarn, and the width of the multi-axis warp knitted fabric.

Examples of the yarn component (fiber) of the woven fabric and multi-axis warp knitted fabric is not particularly limited, but in the case of inorganic fibers such as glass fiber, carbon fiber, and the like, since the moisture content is low, pores in the spring are not formed during subsequent curing. Also, the thermal stability is excellent. Therefore, when using a woven fabric and a multi-axis warp knitted fabric of inorganic fibers, the strength and thermal stability of the final zigzag spring can be improved.

When the woven fabric or multiaxial warp knitted fabric 10 passes through the resin composition impregnation tank 200 containing the resin composition 20, the resin composition penetrates into the gap (space between the thread and the yarn) of the woven fabric or multiaxial warp knitted fabric, thereby causing the gap. By filling in, the prepreg sheet 30 is obtained.

The resin composition 20 contains a vinyl ester resin or polyester. When the vinyl ester resin or polyester is included, the curing speed is increased during the production of the spring, thereby improving productivity, and further improving the thermal and chemical stability of the spring.

The resin composition may further include one or more additives to improve other physical properties of the spring. For example, additives include dyes, pigments, UV blockers, antioxidants, fillers such as talc, and the like, which may be used alone or in combination of two or more. These additives may be added to the composition in amounts known in the art, such as from about 0.01 to 10 parts by weight based on 100 parts by weight of vinylester resin and / or polyester.

Next, as described above, at least one wrinkle portion 41 extending in the longitudinal direction of the sheet is formed in the prepreg sheet 30 along the width direction of the sheet to obtain a spring preform sheet 40 (S200). . In this case, the step S200 may include adjusting the number of the pleats 41 and the height h of the pleats 41 according to the shock absorber of the vehicle.

In the step S100, as shown in FIG. 2, at least one (preferably plural) wrinkles 41 extending in the longitudinal direction of the sheet may be formed in the prepreg sheet 30 along the width direction of the sheet. The preforming unit 300 is used.

The preforming unit 300 primarily deforms the prepreg sheet 30 prior to heating and molding by the forming unit 400 to form a plurality of wrinkles in the prepreg sheet 30, thereby forming a molding unit ( 400) it is possible to reduce the excessive curing residual stress generated during curing, and also to remove excess resin (excess resin).

The temperature during the preforming is not particularly limited, and is appropriately adjusted in consideration of the yarn component (fiber) of the fabric (or multiaxial warp knitted fabric), the thickness of the fabric (or multiaxial warp knitted fabric), the component of the resin composition, and the like. For example, it can be adjusted lower than the curing temperature of the following S300 step.

The number of the pleats 41 and the height of the pleats 41 may be adjusted according to the shock absorber of the vehicle in consideration of the width and thickness of the fabric (or multi-axis warp knitted fabric).

Thereafter, curing of the spring preform sheet 40 formed in the step S200 starts (S300).

The step S300 uses a molding unit 400 capable of curing the resin composition by heating the spring preform sheet while corresponding to the shape of the preforming unit 300.

The curing temperature and time are not particularly limited, and are adjusted in consideration of the yarn component (fiber) of the fabric (or multiaxial warp knit), the thickness of the fabric (or multiaxial warp knit), the component of the resin composition, the size of the molding unit, and the like. It is preferable. For example, when the spring preform sheet 40 is heated at a temperature of about 100 to 150 ° C. for about 10 to 20 minutes, the resin composition impregnated in a fabric or a multiaxial warp knitted fabric may be cured.

Finally, the cured spring preform sheet 50 is cut perpendicular to the longitudinal direction of the sheet (ie, in the width direction of the sheet) (S400). Thereby, the zigzag spring 60 shown in FIG. 3 can be obtained.

The curing spring preform sheet 50 may be cut using a cutting unit 500 known in the art. Examples of the cutting unit 500 include a high performance diamond saw.

The cutting length of the curing spring preform sheet 50 is not particularly limited, and is adjusted according to the vehicle shock absorber, and the width of the spring is determined according to the cutting length of the curing spring preform sheet 50.

As shown in FIG. 4, a plurality of zig-zag springs 60 continuously manufactured by the above-described method are arranged around the automobile shock absorber, so that the impact from the road surface that is transmitted through the tire while supporting the weight of the vehicle is supported. Can absorb the shock to mitigate the impact. At this time, the number of springs and the separation distance between the springs can be adjusted according to the desired strength, elastic modulus, fatigue life, etc. in consideration of the width of the spring, the number of wrinkles.

10: woven or multiaxial warp knit, 20: resin composition,
30: prepreg sheet, 40: spring preform sheet,
41: wrinkles, 50: curing spring preform sheet,
60: zigzag spring,
100: creel, 200: resin composition impregnation tank,
300: preforming unit, 400: molding unit,
500: cutting unit, 600: shock absorber,
A-A ': length direction of sheet, B-B': width direction of sheet

Claims (3)

Impregnating a fabric or multi-axial warp knitted fabric with a resin composition comprising a vinyl ester resin or polyester and at least one additive selected from the group consisting of dyes, pigments, UV blockers, antioxidants and talc. Forming a prepreg sheet;
Obtaining a spring preform sheet on the prepreg sheet by forming a plurality of corrugations extending in the longitudinal direction of the sheet along the width direction of the sheet;
Curing the spring preform sheet; And
Cutting the cured spring preform sheet perpendicular to the longitudinal direction of the sheet
Continuous manufacturing method of zigzag spring comprising a. The method of claim 1,
The spring preform forming step
According to the shock absorber characterized in that it comprises the step of adjusting the number of wrinkles, and the height of the wrinkle portion zigzag-type continuous manufacturing method. delete

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