KR102555583B1 - Method for detecting pressure on grip of golf club and golf training device performing the method - Google Patents

Abstract

The present invention relates to a method for detecting pressure in grip of a golf club and to a golf training device performing the method. The method for detecting pressure in grip of a golf club comprises the steps of: receiving pressure generated on the grip through a piezoelectric film by a golf training tool; and generating pressure data by sensing pressure based on a pressure sensing signal input to a flexible printed circuit board (FPCB) by the golf training tool.

Description

Method for detecting pressure on grip of golf club and golf training device performing the method}

The present invention relates to a method for detecting pressure in a golf club grip and a golf practice device for performing the method. More specifically, it relates to a method for detecting pressure in a golf club grip to help a user practice golf by measuring the pressure with which a user grips the golf club grip, and a golf practice device performing the method.

Golf instructors always advise 'play with less force' for a consistent golf swing. However, it is difficult for beginners to relax and hit during the golf swing. The grip holding the golf club with both hands is the start of the swing. In particular, grip strength is a precondition for a smooth swing, and if the grip is gripped too tightly, the entire body stiffens and causes miss shots. However, many golfers unknowingly strain their grip. In fact, it was investigated that there is a huge difference in grip strength, that is, grip strength, between professional golfers and amateur golfers.

In Golf Magazine, a professional golf magazine in the United States, changes in grip strength during swing were analyzed by computer for professional and amateur golfers. The results of the experiment showed that amateur golfers hold twice as much grip as professional golfers.

Grip strength is one of the reasons why professional golfers have a smooth swing. First of all, grip strength at address is similar between professional golfers (20%) and amateur golfers (26%). However, once the backswing begins, the professional golfer's grip strength increases slightly by 29%, while the amateur golfer jumps by 52%.

Even at the top of the backswing, the grip strength of professional golfers increased by 48%, about twice that of address, while the grip strength of amateur golfers tripled to 78%. This is because the golf club is lifted only with the arms while the torso is not sufficiently rotated. This is pointed out as the cause of creating a swing trajectory outside-in and producing slices or hooks. At impact, the grip strength of professional golfers was 85% and that of amateur golfers was 97%, showing no significant difference. However, in the post-impact follow-through at waist level, the pros had 25%, while the amateurs had 55%, more than double the pros. In other words, while pros increase grip strength only when necessary, amateurs always work hard. In particular, the angle between the left arm and the club shaft at the beginning of the downswing from the top of the backswing was 104 degrees for the pros, but only 76 degrees for the amateurs. This is one of the reasons the pro's shots go the distance. The pro's angle is what accelerates head speed right up to impact.

In order to prevent stiffening of the body due to a strong grip, instructors recommend practicing with a light grip with the left hand held normally and the right hand next to the left hand. It is necessary to develop a golf mechanism for this practice method, and such a golf mechanism can be a good tool for correcting the swing habits of existing amateur golfers.

As for related technologies, there are Korean registered patents 10-2337323.

The object of the present invention is to solve all of the above problems.

Another object of the present invention is to assist a user in training a golf swing by measuring pressure generated on a grip when a user swings a golf club.

In addition, an object of the present invention is to help a user perform accurate swing training by more accurately analyzing the pressure generated on the grip by subdividing the area on the grip based on the first and second wire patterns.

Representative configurations of the present invention for achieving the above object are as follows.

According to one embodiment of the present invention, a method for detecting pressure in a golf club grip includes the steps of a golf practice tool receiving pressure generated on the grip through a piezoelectric film and the golf practice tool on a flexible printed circuit board (FPCB). The method may include generating pressure data by sensing the pressure based on the input pressure sensing signal.

Meanwhile, the FPCB includes a first conducting wire pattern and a second conducting wire pattern, and the golf practice tool is applied onto the second conducting wire pattern based on the pressure sensing signal input onto the first conducting wire pattern and the piezoelectric film. The pressure data may be generated based on the outputted pressure sensing signal.

In addition, the first conducting wire pattern includes a plurality of pressure sensing signal input units and includes a plurality of pressure sensing signal input areas for transmitting a plurality of pressure sensing signals transmitted by the plurality of pressure sensing signal input units, The 2-conductive wire pattern may include a plurality of pressure sensing signal output regions for receiving and outputting at least one pressure sensing signal transmitted through the piezoelectric film among the plurality of pressure sensing signals.

According to another embodiment of the present invention, a golf practice tool implemented to detect pressure in a golf club grip receives pressure generated on the grip through a piezoelectric film, and a pressure sensing signal input onto a flexible printed circuit board (FPCB) It may be implemented to sense the pressure based on to generate pressure data.

Meanwhile, the FPCB includes a first wire pattern and a second wire pattern, and the pressure data is output onto the second wire pattern based on the pressure sensing signal input onto the first wire pattern and the piezoelectric film. It may be generated based on the pressure sensing signal to be.

In addition, the first conducting wire pattern includes a plurality of pressure sensing signal input units and includes a plurality of pressure sensing signal input areas for transmitting a plurality of pressure sensing signals transmitted by the plurality of pressure sensing signal input units, The 2-conductive wire pattern may include a plurality of pressure sensing signal output regions for receiving and outputting at least one pressure sensing signal transmitted through the piezoelectric film among the plurality of pressure sensing signals.

According to the present invention, accurate golf swing training information can be provided to the user by measuring the pressure generated on the grip when the user swings the golf club.

In addition, according to the present invention, by subdividing the area on the grip based on the first and second wire patterns, the pressure generated on the grip is more accurately analyzed and accurate golf swing training information can be provided to the user.

1 is a conceptual diagram showing a golf practice tool according to an embodiment of the present invention.
2 and 3 are conceptual diagrams showing the structure of an FPCB according to an embodiment of the present invention.
4 is a conceptual diagram illustrating a pressure sensing method based on an FPCB and a piezoelectric film according to an embodiment of the present invention.
5 is a conceptual diagram illustrating a pressure sensing method based on an FPCB and a piezoelectric film according to an embodiment of the present invention.
6 is a conceptual diagram illustrating a method for training based on pressure generated on a grip according to an embodiment of the present invention.
7 is a conceptual diagram illustrating a golf practice tool according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The detailed description of the present invention which follows refers to the accompanying drawings which illustrate, by way of illustration, specific embodiments in which the present invention may be practiced. These embodiments are described in sufficient detail to enable any person skilled in the art to practice the present invention. It should be understood that the various embodiments of the present invention are different from each other but are not necessarily mutually exclusive. For example, specific shapes, structures, and characteristics described herein may be implemented from one embodiment to another without departing from the spirit and scope of the present invention. It should also be understood that the location or arrangement of individual components within each embodiment may be changed without departing from the spirit and scope of the present invention. Therefore, the detailed description to be described later is not performed in a limiting sense, and the scope of the present invention should be taken as encompassing the scope claimed by the claims and all scopes equivalent thereto. Like reference numbers in the drawings indicate the same or similar elements throughout the various aspects.

Hereinafter, various preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings in order to enable those skilled in the art to easily practice the present invention.

1 is a conceptual diagram showing a golf practice tool according to an embodiment of the present invention.

Referring to FIG. 1, the handle of the golf practice tool includes an internal printed circuit board (PCB) 100, a shaft 110, a sensing signal supply unit (not shown), and a flexible printed circuit board (FPCB) 120 from the inside to the outside. , It may be implemented based on the piezoelectric film 130 and the grip 140 .

The internal PCB 100 may be implemented to sense the user's swing and process pressure data generated by the user's hand. The internal PCB 100 may directly process swing data and pressure data and provide training data according to the processing result. Alternatively, the internal PCB 100 transmits swing data and pressure data to an external device (eg, a smartphone) through a communication unit, and analysis of the swing data and pressure data is performed on the smartphone or a server associated with the smartphone. It could be.

The internal PCB 100 may serve as a processor for processing various data for golf practice.

The shaft 110 may have a structure of a golf shaft formed outside the inner PCB 100 . A transmission structure for transmitting pressure data generated based on the piezoelectric film 130 and the FPCB 120 to the internal PCB 100 may be implemented on the shaft 100 .

A sensing signal supply unit (not shown) may be implemented to supply a pressure sensing signal onto the FPCB 120 . A pressure sensing signal may be supplied to sense pressure on a sensing pattern on the FPCB 120 . For example, the pressure sensing signal may be sequentially input to a lower sensing structure on the FPCB 120 as a signal of a specific frequency (eg, 1 kHz).

The FPCB 120 may transmit a pressure sensing signal through the piezoelectric film 130 as a wire pattern to sense the position of the pressure generated on the grip. The FPCB 120 may be formed outside the shaft 110 . For example, the FPCB 120 may include a first wire pattern and a second wire pattern. When an input is applied to the piezoelectric film 130, the pressure at the corresponding position is lowered, and the pressure sensing signal may be transferred from the first wire pattern to the second wire pattern in consideration of the position where the pressure is generated. Information on the location and magnitude of the pressure generated on the grip 140 may be obtained in consideration of the location where the pressure sensing signal is transmitted. The first conductive wire pattern and the second conductive wire pattern are not connected to each other, and the pressure sensing signal transferred to the first conductive wire pattern based on the piezoelectric film 130 may be transferred to the second conductive wire pattern.

The piezoelectric film 130 may be an ultra-thin piezoresistive film such as a velostat. The piezoelectric film 130 may be formed outside the FPCB. The piezoelectric film 130 may transmit a pressure sensing signal on a specific position by conducting only a specific position on the FPCB 120 by lowering resistance to a region where pressure is generated.

The grip 140 may be formed outside the piezoelectric film 130 . A user can hold the grip 140 and swing golf, the pressure generated on the grip 140 is transferred to the piezoelectric film 130, and the position of the pressure on the grip 140 can be sensed.

2 and 3 are conceptual diagrams showing the structure of an FPCB according to an embodiment of the present invention.

2 and 3 disclose the structure of the FPCB for sensing the pressure applied to the grip by the user.

Referring to FIGS. 2 and 3 , the FPCB may include a first wire pattern 210 and a second wire pattern 250 . The first conducting wire pattern 210 and the second conducting wire pattern 250 disclosed in FIGS. 2 and 3 are examples, and various other structures can be utilized as long as they are included in the spirit of the present invention, and these examples are also the rights of the present invention. may be included in the scope.

The first wire pattern 210 may include a plurality of pressure sensing signal input units and a plurality of pressure sensing signal input areas for transmitting a plurality of pressure sensing signals.

In the present invention, for convenience of description, it is assumed that the plurality of pressure sensing signal input units are six pressure sensing signal input units, and the plurality of pressure sensing signal input areas are assumed to have six pressure sensing signal input areas.

Six pressure sensing signal input units include pressure sensing signal input unit 1 (211), pressure sensing signal input unit 2 (212), pressure sensing signal input unit 3 (213), pressure sensing signal input unit 4 (214), and pressure sensing signal input unit 5 (215). ), and a pressure sensing signal input unit 6 216.

The six pressure sensing signal input areas include pressure sensing signal input area 1 (221), pressure sensing signal input area 2 (222), pressure sensing signal input area 3 (223), pressure sensing signal input area 4 (224), and pressure sensing signal input area 4 (224). A signal input area 5 225 and a pressure sensing signal input area 6 226 may be included.

The pressure sensing signal input area 1 221 is an area to which the pressure sensing signal input by the pressure sensing signal input unit 1 211 is transmitted. The pressure sensing signal input area 2 222 is an area to which the pressure sensing signal input by the pressure sensing signal input unit 2 212 is transmitted. The pressure sensing signal input area 3 223 is an area to which the pressure sensing signal input by the pressure sensing signal input unit 3 213 is transmitted. The pressure sensing signal input area 4 224 is an area to which the pressure sensing signal input by the pressure sensing signal input unit 4 214 is transmitted. The pressure sensing signal input area 5 225 is an area to which the pressure sensing signal input by the pressure sensing signal input unit 5 215 is transmitted. The pressure sensing signal input area 6 226 is an area to which the pressure sensing signal input by the pressure sensing signal input unit 6 216 is transmitted.

The first wire pattern 210 of the FPCB may have a structure that interlocks with the grip, and accordingly, the width decreases from the top (first pattern layer) where the pressure sensing signal input unit is located to the bottom (eighth pattern layer). can have a structure. Therefore, as shown in the example of the drawing, the number of patterns included in the wire pattern included in the pressure sensing signal input area 1 221 may decrease as it moves from the top to the bottom.

A plurality of pattern layers may be included from an upper end to a lower end of each of the plurality of input sensing signal input regions. Each of the plurality of pattern layers may include an upper conductive wire pattern 230 and a lower conductive wire pattern 240 . The top wire pattern 230 is It is a form in which the pattern of the form is connected left and right, and the lower wire pattern 240 is It is a form in which the pattern of the shape is connected left and right. The upper wire pattern 230 and the lower wire pattern 240 are pattern of shape It can be implemented so that the patterns of the shape are interlaced with each other so that they are not connected to each other with spaces between the patterns.

The upper conductive wire pattern 230 or the lower conductive wire pattern 240 located on each of the plurality of pattern layers is connected to the pressure sensing signal input unit, and pressure is transmitted from the upper pattern layer (first pattern layer) to the lower pattern layer (eighth pattern layer). A pressure sensing signal may flow on the sensing signal input area.

Based on this structure, the pressure sensing signal generated from the specific pressure sensing signal input unit may be transmitted only to the specific pressure sensing signal input area, and may be transmitted from the upper pattern layer to the lower pattern layer on the specific pressure signal sensing input area.

The second wire pattern 250 of the FPCB may include a plurality of pressure sensing signal output regions for receiving and outputting the pressure sensing signal transmitted through the first wire pattern 210 . The second wire pattern 250 of the FPCB may also have a structure that interlocks with the grip, and thus may have a structure in which the width decreases as the pressure goes from the top (first pattern layer) to the bottom (eighth pattern layer).

The second conducting wire pattern 250 may also include a plurality of pattern layers from the top to the bottom, and an upper conducting wire pattern or a lower conducting wire pattern may be formed on the plurality of pattern layers. The upper and lower conducting wire patterns on the second conducting wire pattern 250 are pattern of shape It can be implemented so that the patterns of the shape are interlaced with each other so that they are not connected to each other with spaces between the patterns. One of the upper conductive wire pattern and the lower conductive wire pattern may transfer a pressure sensing signal transmitted from each of the plurality of pattern layers to the output unit. For example, the upper conducting wire pattern of each of the plurality of pattern layers on the second conducting wire pattern 250 may transmit a pressure sensing signal generated in each of the plurality of pattern layers on the first conducting wire pattern 210 .

According to an embodiment of the present invention, the first conducting wire pattern 210 and the second conducting wire pattern 250 are not directly connected, and the pressure sensing signal generated from the first conducting wire pattern 210 passes through the piezoelectric film to the second conducting wire pattern 250 . It may be transferred to the conductive wire pattern 250 .

4 is a conceptual diagram illustrating a pressure sensing method based on an FPCB and a piezoelectric film according to an embodiment of the present invention.

4 discloses a pressure sensing method based on an FPCB and a piezoelectric film when a user applies pressure to a grip.

Referring to FIG. 4 , pressure sensing signals may be sequentially transmitted to the pressure sensing signal input unit 1 to the pressure sensing signal input unit 6 .

A pressure sensing signal may be generated from the pressure sensing signal input unit 1 and transmitted to the pressure sensing signal input area 1 . It can be assumed that pressure sensing signal input area 1 is divided into lower pressure sensing signal input area 1-1 to lower pressure sensing signal input area 1-N, and pressure is generated on a specific lower pressure sensing signal input area. For example, when pressure is generated in the lower pressure sensing signal input areas 1-3 (400), pressure is applied to the piezoelectric film at the corresponding position, and resistance of the piezoelectric film at the corresponding position is lowered. In this case, it can be seen that the pressure sensing signal is transmitted to the pressure sensing signal output unit 1 through the piezoelectric film, and pressure is generated in the lower pressure sensing signal input regions 1-3 (400) through the output of the pressure sensing signal.

In this way, pressure generated in the lower pressure sensing signal input region 1-1 to the lower pressure sensing signal input region N-N corresponding to the grip can be sensed.

The division of the lower pressure sensing signal input area 1-1 to the lower pressure sensing signal input area N-N may be performed differently according to the accuracy of the pressure sensing. For example, as the number of pressure sensing signal input units increases relatively, as the number of pattern layers increases, the lower pressure sensing signal input area becomes smaller and the density of the pressure sensing area corresponding to the lower pressure sensing signal input area increases. can rise

In the case of FIG. 2 , a total of 48 lower pressure sensing signal input areas exist as 8 layered parts and 6 pressure sensing signal input areas, and pressure generated on the 48 lower pressure sensing signal input areas can be measured.

5 is a conceptual diagram illustrating a pressure sensing method based on an FPCB and a piezoelectric film according to an embodiment of the present invention.

5 discloses a method of sensing pressure based on an FPCB and a piezoelectric film when a user applies pressure to a plurality of locations on a grip.

Referring to FIG. 5 , when the user holds the grip, the lower pressure sensing signal input area 2-4 (510), the lower pressure sensing signal input area 3-3 (520), and the lower pressure sensing signal input due to the pressure of the user's hand. It is assumed that pressure is generated in the region 4-3 (530).

First, the pressure sensing signal of the pressure sensing signal input unit 2 is transmitted to the lower pressure sensing signal input area 2-4 (510), and the resistance of the piezoelectric film in the area corresponding to the lower pressure sensing signal input area 2-4 (510) is The signal may be transmitted to the pressure sensing signal output unit 2 as it is lowered due to the pressure.

Next, the pressure sensing signal of the pressure sensing signal input unit 3 is transmitted to the lower pressure sensing signal input area 3-3 (520), and the resistance of the piezoelectric film in the area corresponding to the lower pressure sensing signal input area 3-3 (520) is The signal may be transmitted to the pressure sensing signal output unit 3 as it is lowered due to the pressure.

Next, the pressure sensing signal of the pressure sensing signal input unit 4 is transmitted to the lower pressure sensing signal input area 4-3 (530), and the resistance of the piezoelectric film in the area corresponding to the lower pressure sensing signal input area 4-3 (530) is The signal may be transmitted to the pressure sensing signal output unit 4 as it is lowered due to the pressure.

In the above manner, pressure generated on a plurality of pressure sensing areas on the grip may be measured. The magnitude of the pressure can be measured based on the magnitude of the transmitted signal.

6 is a conceptual diagram illustrating a method for training a golf swing based on pressure generated on a grip according to an embodiment of the present invention.

6 discloses a method for training a user to hold a golf grip based on pressure generated on the grip.

Referring to FIG. 6 , the golf practice tool may further include a vibration unit. When abnormal pressure is generated based on the user's pressure data, the vibration unit may inform the user that the abnormal pressure is generated through a vibration signal.

The golf practice tool may analyze a user's swing based on swing data, and provide analysis data on what state the pressure generated at each stage of the user's swing is based on the pressure on the grip generated at each stage of the swing. .

As shown in FIG. 6, the amount of pressure is sensed in the stages of Address, Top, Down, Impact, Follow-through, and Finish, and is generated for each position of the grip. Information on the magnitude of the pressure being applied can be provided.

7 is a conceptual diagram illustrating a golf practice tool according to an embodiment of the present invention.

7 discloses an algorithm for generating a pressure sensing result by sensing pressure in a golf practice tool.

Referring to FIG. 7 , pressure data measured on a plurality of pressure sensing regions corresponding to a plurality of lower pressure sensing signal input regions may be integrated or divided and processed.

As for the pressure data, most simply, the total pressure data 700 generated at each swing stage may be generated through processing of the magnitude of pressure generated in the entire area.

Also, an analysis of pressure in a vertical direction may be performed based on the pressure data. Based on the plurality of pattern layers, vertical pressure data 710 , which is pressure for a plurality of regions divided in a vertical direction, may be generated based on pressure data generated in each of the plurality of pattern layers.

When processing the vertical direction pressure data 710, at least one pattern layer may be integrated and processed in consideration of a region requiring pressure analysis. For example, the first pattern layer to the second pattern layer may be integrated from the top and integrated as one vertical area to be sensed, and pressure data may be processed. The third pattern layer, the fourth pattern layer, the fifth pattern layer, and the sixth pattern layer are individual sensing target vertical regions, and pressure data is processed, and the seventh pattern layer and the eighth pattern layer are pressure data as one sensing target vertical region. Data can be processed.

Similarly, when processing the horizontal direction pressure data 720, at least one lower pressure sensing signal input area may be integrated and processed in consideration of an area requiring pressure analysis. For example, on the third pattern layer, areas corresponding to lower pressure sensing signal input areas 1-3, lower pressure sensing signal input areas 2-3, and lower pressure sensing signal input areas 3-3 are integrated to form one sensing target horizontally. Pressure data 720 may be processed as an area.

The vertical area to be sensed and the horizontal area to be sensed may be determined in consideration of the golf grip. When a general golf grip is formed, an area with a high probability of generating pressure and an area with a low probability of generating pressure may be distinguished, and the vertical area to be sensed or the horizontal area to be sensed may be integrated as the probability of pressure to occur is low.

In addition, the vertical area to be sensed and the horizontal area to be sensed may be set differently according to sensing sensitivity. When the sensing sensitivity is set to be relatively high, the vertical area to be sensed and the horizontal area to be sensed may be relatively less integrated and processed.

In addition, according to an embodiment of the present invention, swing data may be processed by setting different vertical regions to be sensed and horizontal regions to be sensed according to swing stages. Depending on the gravity or the centrifugal force along the trajectory of the swing, it is necessary to analyze the grip pressure differently for each step of the swing, and considering the gravity or the trajectory of the swing, different vertical areas to be sensed and horizontal areas to be sensed are set. It can be.

Embodiments according to the present invention described above may be implemented in the form of program instructions that can be executed through various computer components and recorded on a computer-readable recording medium. The computer readable recording medium may include program instructions, data files, data structures, etc. alone or in combination. Program instructions recorded on the computer-readable recording medium may be specially designed and configured for the present invention, or may be known and usable to those skilled in the art of computer software. Examples of computer-readable recording media include magnetic media such as hard disks, floppy disks and magnetic tapes, optical recording media such as CD-ROMs and DVDs, and magneto-optical media such as floptical disks. medium), and hardware devices specially configured to store and execute program instructions, such as ROM, RAM, flash memory, and the like. Examples of program instructions include high-level language codes that can be executed by a computer using an interpreter or the like as well as machine language codes generated by a compiler. A hardware device may be modified with one or more software modules to perform processing according to the present invention and vice versa.

Although the present invention has been described above with specific details such as specific components and limited embodiments and drawings, these are only provided to help a more general understanding of the present invention, and the present invention is not limited to the above embodiments, and the present invention Those with ordinary knowledge in the technical field to which the invention belongs may seek various modifications and changes from these descriptions.

Therefore, the spirit of the present invention should not be limited to the above-described embodiments and should not be determined, and all scopes equivalent to or equivalently changed from the claims as well as the claims described below are within the scope of the spirit of the present invention. will be said to belong to

Claims (6)

How to detect the pressure in the golf club grip,
receiving, by the golf practice tool, pressure generated on the grip through the piezoelectric film; and
Generating pressure data by sensing the pressure based on a pressure sensing signal input onto a flexible printed circuit board (FPCB) by the golf practice tool,
The FPCB includes a first wire pattern and a second wire pattern,
The golf practice tool generates the pressure data based on the pressure sensing signal input onto the first wire pattern and the pressure sensing signal output onto the second wire pattern based on the piezoelectric film,
The first wire pattern has a plurality of pressure sensing signal input units and includes a plurality of pressure sensing signal input areas for transmitting a plurality of pressure sensing signals transmitted by the plurality of pressure sensing signal input units,
The second wire pattern includes a plurality of pressure sensing signal output areas for receiving and outputting at least one pressure sensing signal transmitted through the piezoelectric film among the plurality of pressure sensing signals. method. According to claim 1,
Each of the first wire pattern and the second wire pattern includes a plurality of pattern layers from top to bottom,
Each of the plurality of pattern layers includes an upper conductive wire pattern and a lower conductive wire pattern,
The top wire pattern is It is a form in which the pattern of the form is connected left and right,
The lower wire pattern is It is a form in which the pattern of the form is connected left and right,
The upper wire pattern and the lower wire pattern are pattern of shape A golf club grip pressure detection method, characterized in that the patterns of the shape are alternately connected to each other so that they are not connected to each other with spaces between the patterns. According to claim 1,
The first conducting wire pattern and the second conducting wire pattern are not directly connected,
The golf club grip pressure detection method, characterized in that the pressure sensing signal generated in the first wire pattern is transmitted to the second wire pattern through a piezoelectric film. A golf practice tool implemented to detect pressure in the golf club grip,
receiving the pressure generated on the grip through the piezoelectric film;
It is implemented to generate pressure data by sensing the pressure based on a pressure sensing signal input onto a flexible printed circuit board (FPCB),
The FPCB includes a first wire pattern and a second wire pattern,
The golf practice tool generates the pressure data based on the pressure sensing signal input onto the first wire pattern and the pressure sensing signal output onto the second wire pattern based on the piezoelectric film,
The first wire pattern has a plurality of pressure sensing signal input units and includes a plurality of pressure sensing signal input areas for transmitting a plurality of pressure sensing signals transmitted by the plurality of pressure sensing signal input units,
The second wire pattern includes a plurality of pressure sensing signal output areas for receiving and outputting at least one pressure sensing signal transmitted through the piezoelectric film among the plurality of pressure sensing signals. According to claim 4,
Each of the first wire pattern and the second wire pattern includes a plurality of pattern layers from top to bottom,
Each of the plurality of pattern layers includes an upper conductive wire pattern and a lower conductive wire pattern,
The top wire pattern is It is a form in which the pattern of the form is connected left and right,
The lower wire pattern is It is a form in which the pattern of the form is connected left and right,
The upper wire pattern and the lower wire pattern are pattern of shape A golf practice tool characterized by being implemented so that the patterns of the form are interlaced with each other so that they are not connected to each other with spaces between the patterns. According to claim 4,
The first conducting wire pattern and the second conducting wire pattern are not directly connected,
A golf practice tool, characterized in that the pressure sensing signal generated in the first wire pattern is transmitted to the second wire pattern through a piezoelectric film.

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