JP2022507071A - Protective nets for sports, protective nets for golf using them, protective nets for soccer, protective nets for baseball, protective nets for tennis, and protective nets for volleyball. - Google Patents

Abstract

In the present invention, synthetic fiber cords (CORDs) having a form in which a large number of synthetic fiber filaments are combined and twisted intersect each other in a knotless type to form a mesh between intersections. Formed, the diameter (d) of the synthetic fiber cord (CORD) satisfies equation (I), the maximum spacing (D1) between adjacent intersections satisfies equation (II), and the minimum spacing between adjacent intersections. (D2) satisfies equation (III). Since the surface density is lower than that of the conventional protective net for sports, in other words, the weight is reduced, and the diameter of the synthetic fiber cord constituting the protective net is small and the void ratio is increased. The resistance to the wind is improved, the mechanical properties are excellent, and the resistance to the impact applied while the ball flies and hits is excellent. Therefore, damage is minimized and the replacement cycle is extended. Further, while the porosity is high and the visibility is improved, the ball can be effectively prevented from penetrating the inside of the mesh, so that the stability is also improved. In addition, it can be easily attached to a protective net structure and has excellent flame retardancy and weather resistance.

Description

INDUSTRIAL APPLICABILITY The present invention provides a protective net for sports, a protective net for golf using the protective net for sports, and a protective net for soccer, which are installed in a golf course or a baseball field to prevent a hit golf ball or a baseball ball from coming out of the protective net. Regarding nets, baseball protective nets, tennis protective nets, and volleyball protective nets, specifically, they are lightweight and have excellent resistance to wind, have excellent impact resistance, have a long replacement cycle, and have a high void ratio. In addition to excellent visibility, it effectively prevents golf balls or baseball balls from penetrating to the outside of the protective net to improve stability, and protects sports with excellent flame retardancy and weather resistance. The present invention relates to a net, a protective net for golf using this, a protective net for soccer, a protective net for baseball, a protective net for tennis, and a protective net for volleyball.

The protective net for sports is installed in a golf course or a baseball field to prevent a hit golf ball or a baseball ball from coming out of the protective net.

Conventional sports protective nets are knot type with a knot of HDPE cord (CORD) in which a large number of high density polyethylene (hereinafter referred to as “HDPE”) filaments are combined and twisted. ) Or a protective net for sports that forms a mesh between the intersections of the HDPE cord (CORD) while intersecting each other in a knotless type (Knotless type) has been mainly used.

However, conventional sports protective nets require the HDPE cord (CORD) diameter to be at least 1.8 mm thicker to achieve the desired level of impact resistance and wear resistance. Since the surface density of the protective net for sports is high and the resistance to wind is weak, there is a problem that it is easily damaged by the wind after installation and that it takes a lot of time and manpower to remove the protective net.

Further, the conventional protective net for sports is easily damaged because the resistance to the impact applied while the hit golf ball flies and hits is low, and the area of A in FIG. 3 is divided by the area of B in FIG. After that, since the porosity (%) calculated by multiplying by 100 is low, there is a problem that the visibility is also deteriorated.

Further, the conventional protective net for sports has a problem of low flame retardancy and low weather resistance.

The problems of the present invention are that it is lightweight and has excellent resistance to wind, has excellent impact resistance, has a long replacement cycle, has excellent visibility due to a high void ratio, and has a golf ball or a baseball ball outside the protective net. A protective net for sports that effectively prevents penetration into the ball, improves stability, and has excellent flame retardancy and weather resistance, a protective net for golf, a protective net for soccer, and a protective net for baseball. To provide nets, protective nets for tennis, and protective nets for volleyball.

In order to solve such a problem, synthetic fiber cords (CORD) having a form in which a large number of synthetic fiber filaments are combined and twisted intersect each other in a knotless type (Knotless type). However, a mesh is formed between the intersections of the synthetic fiber cords (CORD), the diameter (d) of the synthetic fiber cords (CORD) satisfies the following formula (I), and the intersections adjacent to each other satisfy the following formula (I). A protective net for sports is manufactured in which the maximum distance (D1) satisfies the following formula (II) and the minimum distance (D2) between the adjacent intersections satisfies the following formula (III).

The unit of the diameter (d) of the synthetic fiber cord (CORD) and the maximum spacing (D1) and the minimum spacing (D2) between the intersections adjacent to each other, which are obtained by the formulas (I) to (III), is mm, m is the mass of the ball, N is the constant 14.14214, ε is the draw ratio of the synthetic fiber filament material, θ is the impact angle of the ball, and σ is the stress of the synthetic fiber filament material. Vo is the maximum speed of the struck ball, L is the total length of the net that is impacted by the struck ball, is calculated by the following equation (IV), and h is the impact by the struck ball. The height of the net to be received, which is calculated by the following formula (V), where R is the radius of the ball to which the impact is applied, and n is the number of twists applied to the synthetic fiber filament for the production of the synthetic fiber cord (CORD). And

In the above formula (IV), N2 is the number of intervals (D) between the intersections of the nets that are impacted by the hit ball, and is an integer of 12, 17 or 24, and N1 is the number of impacts by the ball. The number of intersections of synthetic fiber cords to be added, which is an integer of 1, 2 or 4.

In the above equation (V), Vo is the initial velocity of the hit ball, and θ is the hit angle of the ball.

In the formula (IV), N2 is the maximum value of the diameter (d) of the synthetic fiber cord according to the formula (I), depending on the value of the number of intervals (D) between the intersections of the nets impacted by the hit ball. And the minimum value is obtained.

Since the surface density of the present invention is lower than that of the conventional sports protective net, in other words, the weight is reduced, and the diameter of the synthetic fiber cord constituting the protective net is much larger than the diameter of the HDPE cord of the conventional sports protective net. Due to its small size and increased void ratio, it has improved resistance to wind when manufacturing protective net structures, and has excellent mechanical properties and excellent resistance to impacts such as golf balls or baseball balls that fly and collide with each other. ing. Therefore, the present invention minimizes breakage and extends the replacement cycle.

Further, the present invention has a high porosity and improved visibility, but can effectively prevent a golf ball, a baseball ball, or the like from penetrating between the meshes, so that the stability is also improved.

Further, the present invention can be easily attached to a protective net structure, and is excellent in flame retardancy and weather resistance.

It is a top view of a part of a protective net for sports. It is an enlarged photograph of the intersection (X) of the synthetic fiber cord (CORD: C) in FIG. It is a schematic diagram which shows the area A and the area B used for the porosity calculation. It is a schematic diagram which shows the number (N2) of the interval (D) between the intersections of the net which is impacted by a ball depending on the position where a ball collides with a protective net. It is a schematic diagram which shows the number (N2) of the interval (D) between the intersections of the net which is impacted by a ball depending on the position where a ball collides with a protective net. It is a schematic diagram which shows the number (N2) of the interval (D) between the intersections of the net which is impacted by a ball depending on the position where a ball collides with a protective net.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings and the like.

In the present invention, as shown in FIGS. 1 and 2, a synthetic fiber cord (CORD) having a form in which a large number of synthetic fiber filaments are plyed and twisted is transformed into a knotless type (Knotless type). A mesh is formed between the intersections of the synthetic fiber cords (CORD) while intersecting with each other, and the diameter (d) of the synthetic fiber cords (CORD) satisfies the following formula (I) and is adjacent to each other. The maximum distance (D1) between the intersections satisfies the following formula (II), and the minimum distance (D2) between the adjacent intersections satisfies the following formula (III).

Units for the diameter (d) of the synthetic fiber cord (CORD) determined by the formulas (I) to (III), and the maximum distance (D1) and the minimum distance (D2) between adjacent intersections. Is mm, m is the mass of the ball, N is the constant 14.14214, ε is the draw ratio of the synthetic fiber filament material, θ is the impact angle of the ball, and σ is the synthetic fiber filament material. It is stress, Vo is the maximum speed of the struck ball, L is the total length of the net that is impacted by the struck ball, which is calculated by the following equation (IV), and h is the impact by the struck ball. The height of the net to be received, which is calculated by the following formula (V), where R is the radius of the ball to which the impact is applied and n is added to the synthetic fiber filament for the production of the synthetic fiber cord (CORD). The number of twists,

In formula (IV), N2 is the number of intervals (D) between net intersections that are impacted by the hit ball, an integer of 12, 17 or 24, and N1 is impacted by the ball. Is the number of intersections of the synthetic fiber cord to which is added, which is an integer of 1, 2 or 4.

In the above equation (V), Vo is the initial velocity of the hit ball, and θ is the hit angle of the ball.

The number (N2) of the intervals (D) between the intersections that are impacted by the hit ball is determined by the position where the ball collides with the protective net, as shown in FIGS. 4 to 6.

Specifically, when the ball collides with the position of the protective net shown in FIG. 4, the number of intervals (D) (N2) between the intersections to be impacted by the hit ball becomes 12, and the hit is made. The number of intersections (N1) that are impacted by the ball is one.

On the other hand, when the ball collides with the position of the protective net shown in FIG. 5, the number of intervals (D) (N2) between the intersections impacted by the hit ball becomes 17, and the ball is hit. The number of intersections (N1) that are impacted by the ball is two.

On the other hand, when the ball collides with the position of the protective net shown in FIG. 6, the number of intervals (D) between intersections (D) becomes 24, and the number of intersections that are impacted by the hit ball. (N1) becomes four.

The protective net for sports of the present invention can be used in a protective net for golf, a protective net for soccer, a protective net for baseball, a protective net for tennis, a protective net for volleyball, and the like.

As the synthetic fiber filament constituting the synthetic fiber cord, the aramid filament may be used alone, or the aramid filament and other synthetic fiber filaments excluding the aramid filament may be mixed and used.

When the present invention, in which the synthetic fiber cord is an aramid cord made of an aramid filament, is used as a protective net for golf, the diameter (d) of the aramid cord is 0.85 mm or more and 1.5 mm or less, and the intersections adjacent to each other. It is preferable that the maximum distance (D1) of the above is 35 mm or less, and the minimum distance (D2) of the intersections adjacent to each other is 20 mm or more.

When the present invention, in which the synthetic fiber cord is an aramid cord made of an aramid filament, is used as a protective net for soccer, the diameter (d) of the aramid cord is 0.59 mm or more and 0.84 mm or less, and the intersections adjacent to each other. It is preferable that the maximum distance (D1) of the above is 140 mm or less, and the minimum distance (D2) of the intersections adjacent to each other is 135 mm or more.

When the present invention, in which the synthetic fiber cord is an aramid cord made of an aramid filament, is used as a protective net for baseball, the diameter (d) of the aramid cord is 0.75 mm or more and 1.07 mm or less, and the intersections adjacent to each other. It is preferable that the maximum distance (D1) of the above is 50 mm or less, and the minimum distance (D2) of the intersections adjacent to each other is 40 mm or more.

When the synthetic fiber cord is used as the protective net for tennis of the present invention, the diameter (d) of the synthetic fiber cord is 0.73 mm or more and 1.03 mm or less, and the maximum distance (D1) between adjacent intersections is It is preferably 42 mm or less, and the minimum distance (D2) between adjacent intersections is preferably 38 mm or more.

When the synthetic fiber cord is used as a protective net for volleyball of the present invention, the diameter (d) of the synthetic fiber cord is 0.33 mm or more and 0.47 mm or less, and the maximum distance (D1) between adjacent intersections is It is preferably 126 mm or less, and the minimum distance (D2) between adjacent intersections is preferably 122 mm or more.

If the diameter (d) of the synthetic fiber cord is lower than the above range, the mechanical properties such as the tensile strength and wear resistance of the synthetic fiber cord will be deteriorated, and the hit golf ball or baseball ball will be damaged. There is a high possibility that the sports protective net will be easily damaged by the impact applied while flying and hitting, and if the diameter of the synthetic fiber cord (d) exceeds the above range, the surface of the sports protective net The density becomes heavier than 180 g / m ² , the net diameter increases, the resistance to external environment such as wind and typhoon decreases, the installed protective net is more likely to be easily damaged, and the protective net for sports The void ratio becomes less than 88%, and the competition viewing property becomes poor.

When the distance between the intersections (X) of the synthetic fiber cord exceeds the above range, a golf ball, a baseball ball, or the like penetrates between the meshes of the sports protective net, and the protective function of the sports protective net is activated. If it is less than the above range, the mesh is formed to be excessively small and the competition viewing property is deteriorated.

That is, the diameter (d) of the synthetic fiber cord (CORD) is 0.85 mm or more and 1.5 mm or less, the maximum distance (D1) of the intersections adjacent to each other is 35 mm or less, and the minimum distance (D2) of the intersections adjacent to each other. ) Is 20 mm or more, and a protective net for sports can be used as a protective net for golf.

Further, the diameter (d) of the synthetic fiber cord (CORD) is 0.59 mm or more and 0.84 mm or less, the maximum distance (D1) of the intersections adjacent to each other is 140 mm or less, and the minimum distance (D2) of the intersections adjacent to each other. ) Is 135 mm or more, and a protective net for sports can be used as a protective net for soccer.

Further, the diameter (d) of the synthetic fiber cord (CORD) is 0.75 mm or more and 1.07 mm or less, the maximum distance (D1) of the intersections adjacent to each other is 50 mm or less, and the minimum distance (D2) of the intersections adjacent to each other. ) Is 40 mm or more, and a protective net for sports can be used as a protective net for baseball.

Further, the diameter (d) of the synthetic fiber cord (CORD) is 0.73 mm or more and 1.03 mm or less, the maximum distance (D1) of the intersections adjacent to each other is 42 mm or less, and the minimum distance (D2) of the intersections adjacent to each other. ) Is 38 mm or more, and a protective net for sports can be used as a protective net for tennis.

Further, the diameter (d) of the synthetic fiber cord (CORD) is 0.33 mm or more and 0.47 mm or less, the maximum distance (D1) of the intersections adjacent to each other is 126 mm or less, and the minimum distance (D2) of the intersections adjacent to each other. ) Is 122 mm or more, and a protective net for sports can be used as a protective net for volleyball.

The aramid cord (CORD: C) is composed of two or more and three or less aramid filaments having a graininess of 1,200 denier or more and 5,000 denier or less, more preferably 2,000 or more and 5,000 denier or less. The draw ratio of the aramid filament is preferably 2% or more and 4% or less.

It is more preferable that the synthetic fiber cord is coated with a resin containing an ultraviolet stabilizer in order to improve weather resistance.

The protective net for sports of the present invention has a cutting strength of 114 daN (decaneton) or more, or 114 daN (1140 N) or more and 120 daN (1200 N) or less, and is used at the end of the protective net for sports to improve wearability at the time of installation. May be sewn with a narrow woven fabric.

As one embodiment, a narrow woven fabric is attached to the end of the protective net in order to prevent the threads of the protective net from fraying when the protective net is cut or attached in a knotless type. Sew.

As another embodiment, a metal ring is used when a narrow woven fabric is sewn to the end of the protective net so that the protective net can be easily hung or attached to the pillar for installing the protective net. You can also wear a jig.

As another embodiment, when a hook-and-loop fastener is attached to a pillar for installing a protective net, the protective net is used to improve the wearability and detachability of the protective net. When sewing a narrow woven fabric to the end of the, a hook-and-loop fastener can also be sewn together.

Since the surface density of the present invention is lower than that of the conventional protective net for sports, in other words, the weight is reduced, and the diameter of the synthetic fiber cord constituting the protective net is much smaller than the diameter of the conventional HDPE cord, and the void ratio is large. As the number increases, the resistance to wind is improved when manufacturing a protective net structure, and the mechanical properties are excellent, and the resistance to the impact applied when a golf ball or baseball ball flies and hits is excellent. .. Therefore, the present invention minimizes breakage and extends the replacement cycle.

Specifically, the porosity of the sports protective net according to the following formula (VI) may be 90% or more, 90% or more and 100% or less, or 90% or more and 99.5% or less.

In the formula (VI), A is the area of the mesh (Mesh), and B is the value (L1) obtained by adding the diameter (d) of the aramid code (CORD) to the lateral length (L2) of the mesh (Mesh). ) And the value (h1) obtained by multiplying the vertical length (h2) of the mesh (Mesh) by the diameter (d) of the aramid cord.

Further, after the sports protective net is attached to the rotational friction force tester, the wear resistance is the time required for the protective net to be damaged by bringing a golf ball rotating at 3,000 rpm into contact with the same portion of the protective net. However, it can be 20 minutes or more, or 20 minutes or more and 35 minutes or less.

Further, the surface density of the sports protective net may be 1 g / m ² or more and 100 g / m ² or less, or 5 g / m ² or more and 80 g / m ² or less.

Further, according to the present invention, while the porosity is high and the visibility is improved, it is possible to effectively prevent a golf ball, a baseball ball, or the like from penetrating the gap of the mesh, so that the stability is also improved.

Further, the present invention can be easily attached to a protective net structure, and is excellent in flame retardancy and weather resistance.

Hereinafter, the present invention will be described in more detail through Examples and Comparative Examples.

However, it should not be construed as limiting the scope of protection of the invention to the following examples alone.

Example 1
Two aramid filaments having a draw ratio of 3% and a denier of 4,500 denier were combined and twisted to produce an aramid cord (CORD) having a diameter (d) of 0.95 mm.

Next, as shown in FIGS. 1 and 2, the aramid cords were crossed with each other in a knotless state (Knotless type) to form a mesh, and a protective net for golf was manufactured. ..

At this time, the distance between the intersections (X) of the aramid cord was adjusted to 25 mm.

Table 1 shows the results of evaluating the cutting strength, surface density, porosity and wear resistance of the manufactured protective net for golf.

Comparative Example 1
Two 3,000 denier aramid filaments were combined and twisted to produce an aramid cord (CORD) having a diameter (d) of 0.8 mm.

Next, as shown in FIGS. 1 and 2, the aramid cords were crossed with each other in a knotless state (Knotless type) to form a mesh, and a protective net for golf was manufactured. ..

At this time, the distance between the intersections (X) of the aramid cord was adjusted to 23 mm.

Comparative Example 2
Five 3,000 denier high density polyethylene (HDPE) filaments were combined and twisted to produce an HDPE cord (CORD) having a diameter (d) of 1.40 mm.

Next, as shown in FIGS. 1 and 2, the HDPE cords were crossed with each other in a knotless state (Knotless type) to form a mesh, and a protective net for golf was manufactured.

At this time, the distance between the intersections (X) of the HDPE cord was adjusted to 23 mm.

Table 1 shows the results of evaluating the cutting strength, surface density, porosity and wear resistance of the manufactured protective net for golf.

In Table 1, the values of the formula (I), the formula (II), and the formula (III) are as follows.

The diameter (d) of the synthetic fiber cord (CORD) determined by the formulas (I) to (III).
Also, the units of the maximum spacing (D1) and minimum spacing (D2) between adjacent intersections are mm, m is the mass of the ball, N is the constant 14.14214, and ε is the synthetic fiber filament. The draw ratio of the material, θ is the hitting angle of the ball, σ is the stress of the synthetic fiber filament material, Vo is the maximum speed of the hit ball, and L is the net that is impacted by the hit ball. Is the total length of, which is calculated by the following formula (IV), h is the height of the net which is impacted by the hit ball, and is calculated by the following formula (V), and R is the hit. The radius of the ball to be added, where n is the number of twists added to the synthetic fiber filament for the production of the synthetic fiber cord (CORD).

In the formula (IV), N2 is the number of intervals (D) between the intersections of the nets impacted by the hit ball, which is an integer of 12, 17 or 24, and N1 is impacted by the ball. The number of intersections in the synthetic fiber cord, which is an integer of 1, 2 or 4.

In the above equation (V), Vo is the initial velocity of the hit ball, and θ is the hit angle of the ball.

As shown in Table 1, unlike the golf protective net manufactured in Example 1, the distance between the intersections (X) does not belong to the range of the formula (II) and the formula (III). It was confirmed that the protective net for golf manufactured in Example 1 had a significantly poor wear resistance.

Further, unlike the golf protective net manufactured in Example 1, not only the cord diameter does not satisfy the formula (I), but also the golf protective net manufactured in Comparative Example 2 in which the cord material is changed to HDPE. Was able to confirm that the wear resistance and cutting strength were significantly poor.

Example 2
Two 3,000 denier aramid filaments were combined and twisted to produce an aramid cord (CORD) having a diameter of 0.7 mm.

Next, as shown in FIGS. 1 and 2, the aramid cords were crossed with each other in a knotless state (Knotless type) to form a mesh, and a protective net for soccer was manufactured.

At this time, the distance between the intersections (X) of the aramid cord was adjusted to 137 mm.

Table 2 shows the results of evaluating the cutting strength, surface density, porosity and wear resistance of the manufactured soccer protective net.

Example 3
Two 3,000 denier aramid filaments were combined and twisted to produce an aramid cord (CORD) having a diameter of 0.9 mm.

Next, as shown in FIGS. 1 and 2, the aramid cords were crossed with each other in a knotless state (Knotless type) to form a mesh, and a protective net for baseball was manufactured. ..

At this time, the distance between the intersections (X) of the aramid cord was adjusted to 45 mm.

Table 2 shows the results of evaluating the cutting strength, surface density, porosity and wear resistance of the manufactured baseball protective net.

Example 4
Two 3,000 denier aramid filaments were combined and twisted to produce an aramid cord (CORD) with a diameter of 0.85 mm.

Next, as shown in FIGS. 1 and 2, the aramid cords were crossed with each other in a knotless state (Knotless type) to form a mesh, and a protective net for tennis was manufactured. ..

At this time, the distance between the intersections (X) of the aramid cord was adjusted to 40 mm.

Table 2 shows the results of evaluating the cutting strength, surface density, porosity and wear resistance of the manufactured protective net for tennis.

Example 5
Two 3,000 denier aramid filaments were combined and twisted to produce an aramid cord (CORD) having a diameter of 0.4 mm.

Next, as shown in FIGS. 1 and 2, the aramid cords were crossed with each other in a knotless state (Knotless type) to form a mesh, and a protective net for volleyball was manufactured. ..

At this time, the distance between the intersections (X) of the aramid cord was adjusted to 124 mm.

Table 2 shows the results of evaluating the cutting strength, surface density, porosity and wear resistance of the manufactured protective net for volleyball.

The physical properties of <Table 1> and <Table 2> were evaluated by the following methods.

Cutting strength (daN)
It was measured by KS K ISO 1806, fishing net-mesh cutting load measuring method. After collecting the mesh and fixing both ends, the cutting strength was measured.

Porosity (%)
As shown in FIG. 3, (i) the area (A) of the mesh (Mesh), and (ii) the lateral length (L2) of the mesh (Mesh) and the diameter (d) of the aramid code (CORD). ) And the vertical length (h2) of the mesh (Mesh) plus the diameter (d) of the aramid cord (h1) to obtain the area (B). After that, these were substituted into the following equation (VI) to calculate the void ratio.

Area density (g / m ² )
The weight of the protective net, which is a standard of 1 m in width × 1 m in length, was measured and obtained.

Abrasion resistance (time)
Abrasion resistance is the time (minutes) required for the protective net to be damaged by contacting the same part of the protective net with a golf ball rotating at 3,000 rpm after attaching the protective net to the rotary friction force tester. Indicated.

C: Synthetic fiber cord (CORD)
d: Diameter of synthetic fiber cord (C) X: Intersection of synthetic fiber cord (C) A: Area of mesh (Mesh) h2: Vertical length of mesh (Mesh)
L2: Horizontal length of mesh (Mesh) h1: Value obtained by adding the diameter (d) of the aramid cord to the vertical length (h2) of the mesh (Mesh).
L1: The value obtained by adding the diameter of the aramid cord to the lateral length (L2) of the mesh (Mesh) B: Area obtained by multiplying h1 and L1 1: Protective net for sports 2: Ball D: Intersection of synthetic fiber cord ( X) Interval

Claims (20)

Synthetic fiber cords (CORDs) having a form in which a large number of synthetic fiber filaments are plyed and twisted intersect each other in a knotless type (Knotless type) to cross the intersections of the synthetic fiber cords (CORDs). A mesh is formed between the fibers, the diameter (d) of the synthetic fiber cord (CORD) satisfies the following formula (I), and the maximum distance (D1) between the intersections adjacent to each other satisfies the following formula (D1). A protective net for sports, which satisfies (II) and the minimum distance (D2) between the adjacent intersections satisfies the following formula (III):

The unit of the diameter (d) of the synthetic fiber cord (CORD) determined by the formulas (I) to (III) and the maximum distance (D1) and the minimum distance (D2) between the intersections adjacent to each other is mm, m is the mass of the ball, N is the constant 14.14214, ε is the draw ratio of the synthetic fiber filament material, θ is the impact angle of the ball, and σ is the stress of the synthetic fiber filament material. Vo is the maximum speed of the hit ball, L is the total length of the net that is impacted by the hit ball, and is calculated by the following equation (IV), and h is the impact by the hit ball. The height of the net to be received, which is calculated by the following formula (V), R is the radius of the ball to which the impact is applied, and n is added to the synthetic fiber filament for the production of the synthetic fiber cord (CORD). The number of twists to be made

In the formula (IV), N2 is the number of intervals (D) between the intersections of the nets impacted by the hit ball, which is an integer of 12, 17 or 24, and N1 is impacted by the ball. The number of intersections in the synthetic fiber cord, which is an integer of 1, 2 or 4.

In the above equation (V), Vo is the initial velocity of the hit ball, and θ is the hit angle of the ball. The sports protective net according to claim 1, wherein the synthetic fiber filament is an aramid filament. The sports protective net according to claim 1, wherein the synthetic fiber cord contains an aramid filament. The protective net for sports according to claim 2, wherein the draw ratio of the aramid filament is 2% or more and 4% or less. The sports protective net according to claim 1, wherein the surface density of the sports protective net is 1 g / m ² or more and 100 g / m ² or less. The protective net for sports according to claim 1, wherein the synthetic fiber cord (CORD) is coated with a resin containing an ultraviolet stabilizer. The sports protective net according to claim 1, wherein a narrow woven fabric is sewn on the end portion of the sports protective net. The sports protective net according to claim 1, wherein the cutting strength of the sports protective net is 114 daN (1140 N) or more. The sports protective net according to claim 1, wherein the sports protective net according to the following formula (VI) has a porosity of 90% or more.

In the formula (VI), A is the area of the mesh (Mesh), and B is the value (L1) obtained by adding the diameter (d) of the aramid code (CORD) to the lateral length (L2) of the mesh (Mesh). The area is obtained by multiplying the vertical length (h2) of the mesh (Mesh) by the value (h1) obtained by adding the diameter (d) of the aramid cord. After attaching the sports protective net to the rotational friction force tester, a golf ball rotating at 3,000 rpm is brought into contact with the same part of the protective net, which is the time required for the protective net to be damaged. The sports protective net according to claim 1, wherein the sex is 20 minutes or more. The diameter (d) of the synthetic fiber cord (CORD) is 0.85 mm or more and 1.5 mm or less, the maximum distance (D1) of the intersections adjacent to each other is 35 mm or less, and the minimum distance (D2) of the intersections adjacent to each other. The sports protective net according to claim 1, wherein the weight is 20 mm or more. The diameter (d) of the synthetic fiber cord (CORD) is 0.59 mm or more and 0.84 mm or less, the maximum distance (D1) of the intersections adjacent to each other is 140 mm or less, and the minimum distance (D2) of the intersections adjacent to each other. The sports protective net according to claim 1, wherein the weight is 135 mm or more. The diameter (d) of the synthetic fiber cord (CORD) is 0.75 mm or more and 1.07 mm or less, the maximum distance (D1) of the intersections adjacent to each other is 50 mm or less, and the minimum distance (D2) of the intersections adjacent to each other. The sports protective net according to claim 1, wherein the weight is 40 mm or more. The diameter (d) of the synthetic fiber cord (CORD) is 0.73 mm or more and 1.03 mm or less, the maximum distance (D1) of the intersections adjacent to each other is 42 mm or less, and the minimum distance (D2) of the intersections adjacent to each other. The sports protective net according to claim 1, wherein the weight is 38 mm or more. The diameter (d) of the synthetic fiber cord (CORD) is 0.33 mm or more and 0.47 mm or less, the maximum distance (D1) of the intersections adjacent to each other is 126 mm or less, and the minimum distance (D2) of the intersections adjacent to each other. The sports protective net according to claim 1, wherein the weight is 122 mm or more. A protective net for golf, characterized in that the protective net for sports according to claim 11 is used. A soccer protective net, characterized in that the sports protective net according to claim 12 is used. A protective net for baseball, which comprises using the protective net for sports according to claim 13. A protective net for tennis, which comprises using the protective net for sports according to claim 14. A protective net for volleyball, which comprises using the protective net for sports according to claim 15.

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