KR840001647B1 - Racket - Google Patents

Abstract

The racket is useful in playing a simulated tennis game on a court of reduced demension, that is, it has an area approx. onr third that of a standard tennis court. The racket ha sa strungweight in the range from 340 to 400 grams, a length between 480 and 500mms, a center of the racket, and a radius of gyration in the range of from 156 to 176 mms.

Description

Racket

1 is a plan view of the racket of the present invention.

2 is a cross-sectional view taken along the line II-II of FIG.

3 is a cross-sectional view taken along line III-III of FIG.

4 is a cross-sectional view taken along the line IV-IV of FIG.

5 is a cross-sectional view taken along the line VV of FIG.

6 is a sectional view taken along the line VI-VI of FIG.

The present invention relates to a simulated tennis game, referred to herein as "Half Court Tennis."

The game is played on a court that is considerably smaller than the standard tennis courts, and the preferred size of the half court tennis court is 12.62m long and 6.4m wide. In addition, this game is played with a ball different from the standard tennis ball. In short, the half-coated tennis ball has a rebound coefficient of about 0.67 times that of a standard tennis ball, its mass is 36-40 grams compared to 54-60 grams of a standard tennis ball, and the standard tennis ball is about 4.54 kg per 6.45 cm2 While half filled with air, the half coot tennis ball is filled with air at standard temperature and pressure.

The surface coating of the half-coat tennis ball is practically the same as that of a standard tennis ball, and the compression coefficient for the half-coat tennis ball is between 4.8-5.9 mm forward compression and 9- return compression. It is between 11.5m.

The net of Haar-Coort is tucked between biaxial pillars, each 825 mm high, 785 mm high from the center of the coat.

In particular, the present invention relates to a racket for use in a simulated tennis game played at the Haar Coat tennis court, having a ball and net having the characteristics as described above, similar to a standard tennis game.

For simulated matches in a smaller court of standard tennis, the following points shall be taken into account:

(a) The sensation of the racket when stroked in a virtually certain area must match the sense of the standard tennis racquet when stroked equally in standard tennis competitions.

(b) In the same stroke, the half tennis ball shall land at a position proportionally similar to the landing point of the standard tennis ball in standard tennis.

(c) The defensive difficulty experienced by the defender by the opponent's stroke during the match shall be the same as the difficulty in a standard tennis game.

The optimum size for the half tennis coot and the optimum characteristics of the half coot tennis ball are as described above. Considerable research has been carried out on the basis of theoretical and practical experiences to determine the optimal characteristics for the half-court tennis racket.

This study was based on the average male (male) of 175cm height. The impact on the game by various players of different physiques compared to the average player is of little importance here because it is significantly less in half-court tennis than in standard tennis.

The characteristics of the players with average physique related to this study are as follows.

The length of the arm, ie from shoulder to knuckle, is 648 mm, and the finger joint outline is the line along the racket. In determining the effect of racket length on the entire range of reach of the cultivator, the "sweet spot" of the racket from the center of the grip is best felt by the impact of the ball. To the point on the number of rackets) can be added to the value 648 mm.

The reaction time from the moment of recognition to the opponent hitting the ball and the moment when the ball starts flying to the stroke position is estimated by 0.1 seconds.

The acceleration is 5 m / s ² . This is somewhat less than can be obtained with a linear acceleration (mostly by measurement), but this allows for a very accurate position and speed adjustment by the tennis player rather than a runner running on a straight line. This value is also treated as a constant as the effect on the body changes of the competitor in testing the limited condition can be neglected.

In using the playing field of the size described above, a number of marginal shots are analyzed, from the center of the baseline to the ball being hit from the opponent's corner and bound at the intersection of the service line and the sideline. You must run to the outside point, run from the rear corner to the center line of the sub-biscoort in order to catch the ball that falls in front of the net, and the player's misjudgment stops the movement and changes the direction of the baseline. You have to run from the center to the sideline.

It can be seen that the time required for each such movement in the Haar Koote Tennis Court is 74% -80% of the time required for the movement in the standard tennis stadium.

This figure was taken most appropriate in terms of the racket specification (arm length and the above description) as well as the specification for the ball.

Three important features of the half-court tennis racket can be considered for the best simulation of the standard tennis match. These features are the weight of the racket, the overall length of the racket and the radius of rotation, and these features combine to give an aerodynamic drag similar to a standard tennis racket in the maximum possible range while using the racket of the present invention.

The racket weight including the string is about 320-400 grams, the length of the racket is about 480-500mm, the radius of rotation is about 156-176mm, and the center of gravity of the racket is 240-260mm away from the tip of the racket head to produce the desired aerodynamic resistance. Is located.

The racket weighs about 16 grams. In order to play a game most similar to standard tennis, the racket of the present invention should feel similar to the tennis racket and preferably distribute weight according to the following criteria.

(a) the grip is formed in the same general shape as standard tennis,

(b) The overall weight should be about the same as a standard tennis racket and at the same time avoiding artificial weight. In addition, if the weight of the racket is lightened, it will cause a mismatch between the material properties, which will not give the necessary results and at the same time give a satisfactory "sense".

(c) The same moment of inertia as that of the standard tennis racket.

Existing miniature coat rackets are light in weight and have small rotational moments of inertia and are distributed with light weight, making it easy to adjust the ball even if the average sized player moves only his wrist. In regular tennis, where it is necessary to fix the wrist at the moment of impact on the ball, it is not easy to adjust the ball by only moving the wrist, and for this reason, existing miniature court rackets cannot be used to make strokes similar to those of standard tennis. .

In order to clarify the characteristics of the most desirable racket it is necessary to discuss the concept of "shock center". This is the point on the racket string where the impact to the ball is most felt by the player. This constitutes the following physical properties.

(a) This is the point of maximum energy transfer from the racket to the ball. This ensures that minimal energy remains in the player's racket and is absorbed after the ball is priced.

(b) This represents the vibration of the racket.

(c) When the ball is hit at the center point, vibration occurs in the center of the handle.

This means that there is no rotational torque on any axis of the grip and the player's wrist and hitting the ball makes it feel flexible in the next movement.

In addition to the above, there is a certain concept for the competitor for any racket that must have an impact center. It is not satisfactory if the center point does not appear to be in the right place and moves the center point or if there is a difference between the senses and the phenomenon. It is especially important for rackets that there is no mass that appears to be out of center of impact.

In the standard tennis, the regulations set forth by Huh do not impose any restrictions on weight. The racket weights and weight distributions applied in the provisions of the Haaf Coat tennis racket are based on the representative figures of current tennis rackets.

As described above, the weight of the half tennis racket according to the present invention is about 320-400 grams including the string. Thereby, the center of gravity of the racket of the present invention is located at a range of 240-260mm from the head of the racket, the radius of rotation of the racket is in the range of 156-176mm in the axis perpendicular to the racket surface passing through the center of gravity of the racket It was.

The polar moment of inertia is a significant factor in the racquet sense and is convenient for fixing the radius of rotation. This is the value of the weight distribution given by the frame contour and is not affected by the thickness of the frame, which can provide the total weight differently. For this particular racket, the moment of inertia is equal to the mass multiplied by the square of the radius of rotation. The figures for a typical standard tennis racket were measured at 177 mm.

The equation for the vibration period and the moment of inertia is as follows.

T = 211.

Where T = vibration cycle

K = turn radius

h = distance from the pivot point to the center of gravity

I = mK ²

Where I = moment of inertia

m = mass

K = turn radius

As mentioned above, the length of a suitable racket in accordance with the present invention is 480-500 mm, the grip of the racket being approximately 150 mm but may be slightly longer or shorter for the convenience of each competitor.

The last part that must be considered is the effect of aerodynamics on the racket and air resistance on the racket.

The head of the half tennis racket is smaller and moves slower than the head of an equivalent standard tennis racket. Therefore, it is important to make the aerodynamic resistance coefficient of the half tennis racket as similar as possible to the standard tennis racket's aerodynamic resistance. Since the aerodynamic resistance is proportional to the square of the racket speed, it is necessary to increase the aerodynamic resistance coefficient reflecting the difference in the square of the racket speed.

In addition, it is necessary to position the increased aerodynamic resistance as far as possible and to position the center of gravity of the increased aerodynamic resistance as close as possible to the pressure center point of the standard tennis racket.

In a specific embodiment of the present invention, this can be realized by adding a particularly extended inner part of the racket head. This inner part is of great importance in the present invention and is shaped so that the required aerodynamic resistance can be obtained without causing significant turbulence that would ruin the game.

It is an object of the present invention to provide a racket for use in a simulated tennis game played on a tennis court of a reduced size.

The general racket form in the present invention is about 340-400 grams including the string, the length is 480-500mm and the center of gravity is located on the longitudinal axis of the racket is located 240-260mm away from the tip of the racket head, the radius of rotation is 156-176mm Range.

The weight of the racket's gut or the entire string is 16 grams as described above, and it will be clearly understood that the present invention includes those with and without strings and the strings are a criterion.

Those skilled in the art of racket manufacture will appreciate that there are many ways to improve the racket head and change its weight while meeting the above criteria. For example, base castings, wood or aluminum frames can be used and one or more clips can be used to make the weight heavier.

One particularly preferred configuration, however, includes a unique head tip shape in the racket as described above, which consists of an outer main frame and a head inner portion, the outer main frame bordering substantially parallel inner and outer outlines, and a head inner portion. Is integrally or totally coupled to the inner and outer surfaces of the main frame, and the inner side of the head has a plurality of plungable pipes and a hole disposed symmetrically adjacent to the pipe about a racket axis.

Detailed description of the racket according to the present invention in detail by the accompanying drawings as follows.

In this embodiment, the racket 1 is composed of various basic members. That is, it consists of the main frame (2), the head inner portion (4), the handle shaft (3), the throat (5) and the string (6) of the unique head shape, the main frame (2) is the inner and outer outline 2a , Bounded by 2b.

One skilled in the art will appreciate that an unlined racket can be molded into one complete unit. The handle shaft 3 is located on an inner surface of a grip (not shown) of leather or the like, and there is a pair of pallets (not shown) between the grip and the handle shaft 3, which is made of an elastic material. The racket thus consists of a frame and string 6, grips and handle pallets, as shown.

The size of the racket shown is as follows. For certain types of rackets already described, this will be the most appropriate size. Tolerances of the inner and outer tolerance lines 8 and 9 indicate that they may be 10 mm away from the frame described above.

This description describes two basic criteria, one being the longitudinal axis of the racket along the line II-II and the other being the end 10 of the handle shaft 3. Since the racket is symmetric about this longitudinal axis, the shape of the racket is described only on one side.

The total length of the racket 1 is 497 mm, and the main frame 2 is 152.4 mm from the end 10 of the handle shaft 3, and the cross section of the main frame 2 is a sphere having a width of 11.4 mm and a thickness of 14 mm. The thickness can be varied between 9 and 19 mm to control the weight and physical properties of the racket. The edge of the racket cross section was rounded with a radius of 2.0 mm.

The main frame (2) has a hole for making a string, and there is a groove (7) in the round part or all the outside of the main frame to protect the row (6) here. The outer edge of the main frame 2 passes through nine reference points as follows.

(a) The point 11 is 152.4 mm away from the end 10 of the racket 1 along the racket axis and again 14.0 mm away from the racket axis. The main frame 2 follows the form of a hyperbola from the point 11 whose focus is at 26.2 mm from the axis of the racket 1 and the vertex at point 11.

40'의 각도를 유지하며 직선을 이루고 있다.(b) Point 12 is located at the end of the hyperbolic arc described in (a) above and is 231.1 mm away from the end 10 of the racket 1 along the racket axis and again 50.8 mm from this axis. 12 to the point 13, the outer edge is about the racket axis.

It maintains a 40 'angle and forms a straight line.

(c) Point 13 is located 248.2 mm from the end 10 along the racket axis and again 63.5 mm from this axis, the outer edge from point 13 to point 14 having an arc of 308.4 mm radius. It is coming true.

(d) Point 14 is located 326.4 mm away from the end 10 along the racket axis and again 104.1 mm away from this axis. The outer edge from point 14 to point 15 forms an arc of radius 98.4 mm.

(e) Point 15 is located on the arc line mentioned in (d) above, and the heading is at a position 110 mm away from the racket axis and in contact with a line parallel to the racket axis.

(f) Point 16 is located in the circular arc mentioned in (e) above with an arc length of 61.8 mm from point 14 to point 16. The outer edge from point 16 to point 17 constitutes an arc of radius 393.7 mm.

(g) Point 17 was positioned 472.7 mm away from the end 10 along the racket axis and again 71.9 mm from this axis. The outer edge extending from point 17 to point 18 forms an arc of 41.1 mm.

(h) Point 18 is located 487.8 mm from the end 10 along the racket axis and again 44.4 mm from this axis. The outer edge extending from point 18 to point 19 forms an arc of radius 294.4 mm.

(i) The leading edge point 19 of the racket head is on the racket axis and is 494.0 mm away from the end 10.

The inner side of the head inner part 4 was formed as follows.

(j) Point 20 is at a point 229.4 mm away from the end 10 along the racket axis. From this point the edge of the inner frame consists of a hyperbolic path whose focus is at point 253.8 mm from the end 10 along the racket axis, the vertex is point 20 and extends to point 21 of this arc. have.

(k) Point 21 was positioned 267.5 mm away from the end 10 along the racket axis and again 58.4 mm away from this axis. The inner edge from this point consists of an arc of radius 256.0 mm to point 22.

(l) Point 22 was positioned 339.3 mm away from the racket axis at end 10 and again 94.5 mm away from this axis. The inner edge from point 22 to point 23 consisted of an arc of 60.0 mm radius.

(m) Point 23 is located on the arc mentioned in (1) above, which arc is located 96.8 mm from the racket axis and in contact with a line parallel to it. This point is the maximum width of the head opening of the racket 1. The inner edge from point 23 to point 24 then consists of an arc as mentioned in (1) above.

(n) Point 24 is located on the arc and has an arc length of 35.6 mm from point 22 to point 24 and forms an arc of 250.0 mm radius from this point to point 25.

(o) The point 25 was placed 435.1 mm away from the end 10 along the racket axis and again 65.5 mm from this axis. From this point another circular curve of 62.5 mm radius arced up to point 26.

(p) Point 26 was positioned 460.2 mm from the end 10 along the racket axis and again 20.3 mm from this axis. To point 26 an arc of 292.0 mm radius was made up to point 27.

(q) Point 27 was on the racket axis and was positioned 463.1 mm away from the end 10 along the racket axis.

The handle shaft (3) is in the form of a rectangular prism, the thickness of which is equal to the thickness of the racket 28.2 mm and the thickness of the main frame (2), and the edge of the handle shaft (3) is rounded or chamfered. You can do The handgrip shaft 3 is 152.4 mm from the end 10 to the point 11. In this embodiment, the outer end of the handle is positioned as indicated by point 10 but the end of the handle shaft 3 is 20 mm in and out of the end point 10 in proportion to the length of the handle, including point 11. It may be modified within the limits.

The head inner portion 4 rigidly fixed to the main frame 2 or integrally molded will be described below.

The cross section of the inner part 4 located between the head end (point 19) of the main frame 2 and the widest point 15 of the frame has a base of 11.7 mm and is integral with the interior of the main frame 2 (or Fixed) and have a symmetrical truncated triangular shape (see FIG. 2).

The upper edge of this triangle is equal to the inner edge of the head inner portion 4 as described above. The cross section of the head inner part 4 located between the widest point 15 of the main frame 2 and the handle (point 11) is a rectangle of thickness 11.7 mm (which can vary over a range of 6.7-16.7 mm), It is located in the main frame 2 together with the inner side of the head inner portion 4 as described above.

The throat 5 has an opening symmetrical about the axis of the racket. The head inner portion 4 becomes unique by laying a plurality of holes 30 in the portion of the inner portion 4 farthest from the handle shaft 3. These holes are between 4.2mm wide and 15-20mm long and have rounded ends. Eight such holes 30 are shown, the axes of which are parallel to the racket axis II-II and symmetrically disposed about the axis II-II. Pipes 31 which tie each string 6 are located between adjacent holes 30.

The hole 30 reduces turbulence when swinging the racket 1 and stabilizes the airflow in the vicinity of the racket head to a desired degree.

Claims (1)

A racket with a head and a handle for a simulated tennis game made from a cote of 12-13m in length and 6-7m in width, whose overall length is shorter than that of a conventional racket, and the grip is a general grip of a standard tennis racket. In the racket, which is shaped and has a weight similar to that of a standard tennis racket and a rotational moment of inertia similar to a standard racket, the head inner portion 4 (the hole 15 is formed from the point 15) extended to the tip of the racket head Racquet that is formed so that aerodynamic resistance almost similar to that of a standard tennis racket can be obtained.

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