KR20100059095A - Golf ball keeping equipment for increasing distance of golf ball - Google Patents

Abstract

PURPOSE: A golf ball storage apparatus is provided, which can multiply the fight distance by increasing the restitution coefficient of the golf ball in a process of hitting a golf ball. CONSTITUTION: A golf ball storage apparatus includes: a case(9) located in the bottom portion of a container in which a golf ball enters; a cylindrical metal(3) having the good heat conductivity, and located in the inside of the container in which the golf ball enters; a hotwire(4) rolled on the outside of the cylinder; a thermocouple(7) installed at the location which does not contact the golf ball without touching the bottom floor of the cylinder; an inner wall(8) spread with yellow soil inside the metal case; an adiabatic material(5) installed outside the inner barrel; an exterior(6) finished with the material with good appearance.

Description

Golf ball keeping equipment for increasing distance of golf ball}

The present invention relates to a device for increasing the distance of the golf ball, more specifically, by increasing the rebound coefficient of the golf ball in the course of hitting the golf ball by exposing the golf ball to a constant temperature and low humidity conditions to increase the distance Disclosed is a device for letting.

The golf industry in Korea has recently expanded to the third market size in the world with the popularization of golf games. As golf club technology development and sales increase, the consumption of golf balls is increasing by more than 15% per year. Golfers can use golf balls to meet their tastes in order to send golf balls farther and more accurately. I choose.

In general, the golf ball is made of a cover (Cover), casing (Casing), the core (Core). Recent development trends include urethane for the cover, ionomer for the casing, and polybutadiene for the core. In the past, several layers of golf balls, such as 3 and 4 pieces, have been developed from two pieces of golf balls. The materials constituting the golf ball are changed in physical properties according to the temperature or humidity at the time of hitting the golf ball, thereby changing the repulsive force of the golf ball. The golfer therefore experiences a change in distance with temperature. Typically, many people experience an increased distance when hitting golf balls at higher temperatures than at lower temperatures. With this in mind, a device has been developed to keep the golf ball warmer to increase the distance of the golf ball when the temperature is low. Conventionally, there was no specific numerical temperature range or the purpose was to maintain about 40-55 ° C. In general, a heating device is used to increase the temperature, and a thermocouple is used to maintain the temperature. The number of balls kept at one time was developed in the size of 2 to 6 balls. However, the conventional apparatus lacks consideration of a range in temperature for optimizing the distance of golf ball without considering the humidity.

In addition, the related arts, US4545362, US7138613 B1, WO01 / 28639 A2, and the like do not introduce a technique for solving the above problems.

The present invention relates to a device for maintaining the temperature and humidity of the golf ball that can implement the highest distance that was not considered in the conventional golf ball temperature maintaining apparatus, to form a golf ball by storing the golf ball in a container maintained at a constant temperature The purpose is to increase the repulsive force of constituent materials such as urethane, ionomer, polybutadiene, and finally increase the distance of the golf ball.

The present invention is heated to a temperature of 37 ℃ to 40 ℃ using a heating wire in the aluminum container, in order to maintain the temperature and humidity of the golf ball has the largest repulsion coefficient, glass fiber, so that the temperature can be maintained continuously The container is made of insulation materials such as composites and ceramics to further insulate, and use a thermocouple to measure the temperature of the golf ball and use a temperature controller to keep the temperature constant. A dehumidifying effect is obtained by applying a material such as ocher with large voids and strong viscous force to the inner surface of the container in which the golf ball is stored, or inserting a dehumidifying material into the container.

The present invention is to maintain a constant temperature at which the repulsive force of the material constituting the golf ball acts the most, and not to expose the golf ball to a high humidity environment, when driving the golf game, stored in a normal room temperature environment The golf ball has a higher repulsion coefficient than a drive shot, so it can get a relatively longer distance.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to the following contents.

1 is a cross-sectional view of a temperature and humidity maintaining apparatus configured to maintain a constant temperature and humidity of a golf ball, and FIGS. 2A to 2C are photographs of prototypes of a golf ball temperature and humidity maintaining apparatus. The innermost part is a metal (3) with good thermal conductivity and is composed of a cylinder. The outer side of the cylinder is wound from the top end to the bottom by a hot wire (4). The diameter of the cylinder is larger than the diameter of at least one golf ball, smaller than the diameter of two golf balls, and the golf balls form several layers, so that only one golf ball occupies a space. And the height of the three golf balls, the height of the cylinder three times the diameter.

The bottom surface of the cylinder does not touch the side, the thermocouple 7 is installed in a position that will not touch the golf ball to detect the temperature inside the container in which the golf ball is located. The inner wall 8 of the inner metal 3 container is coated with a material having a large void and strong viscous force such as ocher. This removes the humidity of the container in which the golf ball is stored.

In order to keep the golf ball at a constant temperature, it is necessary to minimize heat loss. To prevent this, the outside of the inner cylinder is made of a heat insulating material (5) such as glass fiber, composite, ceramic, etc., which has a low heat transfer rate.

The exterior of the device is a sheath 6, which is finished with a material that is easy for the user to hold the device and looks good. The upper surface (2) is used to fix the heating wire and the multi-ply internal structure and reduce the loss of heat, and the same material as the exterior (6) is used as the user sees when the lid is opened. It was also covered with a lid (1) to prevent the portion containing the golf ball is in direct thermal contact with the outside.

The case 9 located below the container in which the golf ball enters is made of the same material as the sheath 6, taking up part of the appearance. In addition, the case 9 is for keeping the temperature constant. Inside the case 9, the controller enters a signal from the thermocouple to reach a constant temperature, and serves to block the current entering the heating wire. The optimum temperature value obtained from the experiment can be set as a threshold value, and the user can control the temperature by mounting it inside so that there is only a line to connect the power to the surface of the case. A panel that can be set to a desired temperature is mounted, and a signal is received from a thermocouple inside, and when a value input from the panel is set, it is set not to send a current to the heating wire, and there is a wire to connect power to the other side of the case 9. There is a way to do this.

The power source required for the golf ball temperature maintaining apparatus according to the present invention is obtained from a golf cart, a battery, a portable generator, and the like. The method of obtaining power from the cart is equipped with a generator on the wheels of the cart, when the cart is moving, it gets electricity from it and supplies it to the device of the invention, and another method is to directly plug the device of the invention into the battery of the cart. How to get electricity.

For the implementation of the present invention, using a golf ball that is generally used to measure the repulsion coefficient according to the golf ball temperature and humidity change through the drop test as follows, the change of the flying distance according to the golf ball temperature change through the hit test By confirming, the temperature condition to maximize the flying distance was derived.

First, the rebound coefficient was measured by dropping a golf ball at a constant height. The golf ball used at this time was a two-piece golf ball, and the iron plate was placed on the floor so that the golf ball could bounce up well after it reached the floor. The definition of the repulsive coefficient is shown in Equation 1.

In Equation 1, v ₁ , v ' ₁ is the speed of the floor, v ₂ is the speed before the ball hits the floor, v' ₂ is the speed after the ball hits the floor. The sign is the negative direction toward the ground. d ₁ and d ₂ are the heights of the balls in the two frames measured just before the ball hits the floor, and d ₃ and d ₄ are the heights of the balls in the two frames measured immediately after the impact.

Therefore, the measurement of the rebound coefficient was obtained through the difference in the distance by grabbing the two frames after touching the two frames before the golf ball touches the floor as shown in FIG. From this, the coefficient of repulsion according to temperature and humidity changes was derived. At this time, the temperature range was -10 ° C, 10 ° C, 30 ° C, 50 ° C, 70 ° C, and the humidity range was 0% RH, 30% RH, 50% RH, 70% RH, 100% RH. It was. Each was exposed for 2 hours, and in order to further confirm the effect on humidity, experiments were conducted for 24 hours, 72 hours, and 120 hours in the 100% RH region.

This is the result when the humidity in FIG. 4 is kept constant at 0% RH and the temperature is changed. Through this, it is possible to confirm the change of repulsion coefficient according to the temperature change, and it can be seen that the resilience coefficient is the largest in the range between 30 ° C and 50 ° C.

Figure 5a is a graph showing the change in the coefficient of resilience according to the change in relative humidity at a constant temperature (30 ℃). The golf ball exposure time is constant for 2 hours. The mean value indicates that the coefficient of repulsion decreases with increasing temperature, but since this change is within the margin of error, it can be seen that humidity has little effect on the coefficient of restitution for exposures of about two hours. In addition, considering the general atmospheric humidity, it can be seen that the humidity does not have a great effect unless it is humid. The graph of Figure 5b shows the change in repulsion coefficient with exposure time when the temperature of the golf ball external environment is 30 ℃ and humidity is 100% RH. When exposed to such a high humidity environment for a long time, it can be seen that the coefficient of repulsion decreases from about 0.05 to about 0.1 compared to a general state or a state where the humidity is almost 0% RH.

Hitting experiments were conducted using screen golf equipment. At this time, the golf ball was used using a two-piece golf ball and a four-piece golf ball that many people are using recently. In the drop test, the effect of humidity was found to have little effect for a short time. Therefore, the experiment was performed by changing only the temperature in the humidity condition of the general environment.

6A and 6B are graphs showing a change in distance according to the number of pieces of a golf ball. The maximum distance was shown at 35.88 ° C for two-piece golf balls and at 38.62 ° C for four-piece golf balls. This is also in accordance with the results of the above experiment, it can be limited to a temperature range of 35 ℃ to 40 ℃.

1 is a schematic diagram of a golf ball temperature and humidity maintaining apparatus used in the present invention.

Figures 2a to 2c is a photograph of the prototype of the golf ball temperature and humidity maintenance device.

Figure 3 is a photograph taken with a high speed camera for the measurement of rebound coefficient.

Figure 4 is a diagram showing the results of the experiment to change the coefficient of resilience of the golf ball with temperature at a constant humidity.

Figures 5a and 5b is a diagram showing the results of the experiment to change the rebound coefficient of the golf ball with humidity at a constant temperature.

Figures 6a and 6b is a view showing the results of the flight distance change of the two-piece, four-piece golf ball according to the temperature when the humidity is constant.

Claims (3)

The golf ball storage device, characterized in that to maintain the temperature of the golf ball at a predetermined temperature, and to maintain the driver's shot distance lower than the predetermined humidity, lower than the atmospheric humidity of the golf course to increase the distance of the driver shot. The method of claim 1, wherein the golf ball storage device is an inner aluminum cylinder, the inner wall surface of the inner aluminum cylinder is made of a material having a lot of pores, such as ocher, a viscous force to absorb moisture in the interior, or aluminum It has a dehumidifying agent inside the cylinder to reduce humidity. The outer side of the cylinder consists of a heating wire, and the outside of the inner aluminum cylinder consists of insulation material such as fiberglass, composites, ceramics, etc. Golf ball storage device characterized in that. The golf ball storage device according to claim 1, wherein the golf ball temperature is 35 to 40 ° C.

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