JP5267507B2 - Splash amount judgment device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To determine the amount of momentum of a ball regardless of its diameter. <P>SOLUTION: A momentum determination device 2 comprises a pressure plate 4 for pressing a ball 1 by a biasing force of bias means 7, and a pressure-receiving plate 5 for holding the ball 1 between the pressure plate 4 and the pressure-receiving plate 5. With the pressure plate 4 positioned at a measurement start position, the pressure plate 4 and the pressure-receiving plate 5 are arranged to intersect each other, and the pressure plate 4 is biased to be pressed toward the inside of the ball from the measurement start position by the biasing means 7. Then, the amount of momentum of the ball is determined based on the displacement amount of the pressure plate 4 when the pressure plate 4 has deformed the ball. <P>COPYRIGHT: (C)2012,JPO&amp;INPIT

Description

  The present invention relates to a splash amount determination device, and more specifically, a ball amount is deformed by a pressure plate biased by a biasing means, and the ball splash amount is determined based on a movement amount of the pressure plate at that time. Relates to the device.

Today, in tennis and other ball games, there are standards for the size and the amount of play for each ball used in the game. To do.
However, when practicing, the athlete presses the ball for practice with his / her fingers, etc., and uses a ball that is out of specification to judge the amount and dimension of the ball from the dent and pressure. In some cases, the sense of the ball used in the competition is impaired.
In order to solve such a problem, it is known that the ball amount according to the standard is determined by using the following amount determination device.
The splash amount determination device described in Patent Document 1 is configured to hold a ball between a pressure plate that presses the ball by the biasing force of the biasing means and the pressure plate that is provided on the opposite side of the pressure plate. Pressure receiving plate.
According to this splash amount determination device, the pressure plate urged by the urging means from the measurement start position advances to the inside of the ball to deform the ball, and depending on the amount of movement of the pressure plate at that time The amount of ball splash is determined.

JP 2001-91391 A

However, in the case of the splash amount determination device of Patent Document 1, since the pressure plate and the pressure receiving plate face each other, if the diameter of the sandwiched ball is different, the movement amount of the pressure plate is different. There is a problem that different determination results are produced even with the same amount of splash due to the difference in diameter.
In view of such a problem, the present invention provides a splash amount determination device capable of determining the splash amount regardless of the diameter of the ball.

That is, the splash amount determination device according to the present invention clamps the ball between the pressure plate that presses the ball by the biasing force of the biasing means and the pressure plate that is provided on the opposite side of the pressure plate. A pressure receiving plate,
The pressure plate is advanced to the inside of the ball from the measurement start position where the pressure plate is retracted to the outside of the ball by the urging force of the urging means, and the amount of splash of the ball is determined by the amount of movement of the pressure plate due to the deformation of the ball In the splash amount determination device,
The state where the pressure plate is located at the measurement start position, it is characterized in that the said pressure plate and pressure plate are arranged so that such a and a predetermined angle not parallel.

According to the invention, since the pressure plate in a state of being positioned in the measurement initiating position, and the pressure plate and the pressure plate is arranged so that such a and a predetermined angle not parallel, the diameter of the ball The measurement can be started from a state in which the ball is sandwiched between the pressure plate and the pressure receiving plate regardless of the size of the pressure plate, so that there is no difference in the determination result.

Sectional drawing of the amount determination apparatus concerning a present Example Plan view of splash amount determination device Circuit diagram for warning means Sectional drawing of the splash amount determination apparatus concerning 2nd Example Sectional drawing of the splash amount determination apparatus concerning 3rd Example

The embodiment shown in the drawings will be described below. FIG. 1 shows the internal structure of the amount determining device 2 for determining the amount of the ball 1, FIG. 2 is a plan view of the amount determining device 2, and FIG. The circuit diagram of the warning means provided in 2 is shown, respectively.
The ball 1 in this embodiment is a tennis ball used for hard tennis, and has a diameter of 6.54 to 6.86 cm, a weight of 56.7 to 58.5 g, and a height of 254 cm at the International Tennis Federation and the Japan Tennis Association. There is a standard in which when dropped from a height, it must be bounced within a range of 134.67 to 147.32 cm in height.
In order to maintain a sense during the competition, the athlete should use the ball 1 that complies with the above-mentioned standards during practice, but may also use the worn ball 1 during practice. Pressurizes the ball 1 with a finger or the like, and sensuously determines the amount and size of the splash based on the amount of depression and pressure.
However, since this feeling varies from person to person, there is a case where the ball 1 having a deviation amount outside the above-mentioned standard is used, and as a result, the feeling of the ball 1 used in the competition is impaired, and further, such a ball 1 is used. In some practice games, there was a sense of unfairness among the competitors.
Therefore, by determining the amount of the ball 1 using the above-mentioned amount-of-spacing determination device 2, it is possible to easily and fairly determine the amount of the ball 1 that conforms to the above-mentioned standard, with a feeling close to that at the time of competition. It becomes possible to practice.

The splash amount determination device 2 includes a housing 3 in which a recess 3 a for accommodating the ball 1 is formed, a pressure plate 4 and a pressure receiving plate 5 that are provided in the recess 3 a and sandwich the ball 1, and a pressure plate 4. Is moved to the measurement start position retracted to the outside of the ball 1, biasing means 7 for biasing the pressure plate 4 via the control lever 6, and a warning for generating a warning under required conditions. Means 8 are provided.
As shown in FIG. 2, the housing 3 is formed with the concave portion 3 a on the right side of the figure, and holds the operation lever 6 on the left side of the figure so as to be able to swing, and the user holds the operation lever 6 together with the housing 3. It is formed in a shape that is easy to grip.
The recess 3a is formed in a substantially semicircular shape with a diameter capable of accommodating the ball 1, and is formed in a shape capable of accommodating the ball 1 having the maximum diameter or the minimum diameter in the above-mentioned standard indicated by two two-dot chain lines. Yes.

The pressure plate 4 and the pressure receiving plate 5 are provided so as to protrude inward with respect to the inner wall of the concave portion 3a of the housing 3, and the pressure plate 4 is provided on the operation lever 6 side of the concave portion 3a as shown in FIG. The pressure receiving plate 5 is provided on the opposite side of the pressure plate 4 with the ball 1 interposed therebetween.
The pressure plate 4 is formed with a pressure surface 4a in contact with the ball 1 in the vertical direction in the figure. The pressure surface 5a of the pressure plate 5 and the pressure surface 4a intersect when the ball 1 is sandwiched. In other words, they are arranged not to be parallel and at a predetermined angle .
In this embodiment, in particular, the pressure surface 4a and the pressure receiving surface 5a are arranged so as to form an angle formed by 30 °.
Further, the pressure plate 4 and the pressure plate 5 have lengths that can accommodate the balls 1 having the maximum diameter or the minimum diameter in the standard, respectively. As shown in FIG. Each surface 5a is provided with a mark 5b (the mark on the pressing surface 4a is not shown) indicating the maximum diameter and the minimum diameter in the above standards.
Further, the pressing surface 4a and the pressure receiving surface 5a of the pressure plate 4 and the pressure receiving plate 5 are formed in a circular arc shape as shown in FIG. 2, and the diameter thereof is larger than the diameter of the maximum diameter ball 1 in the standard. It is a diameter.
With such a configuration, the ball 1 is prevented from falling off when the splash amount determination device 2 is used, and when the ball 1 is sandwiched between the pressure plate 4 and the pressure receiving plate 5, The load from the surface 5a is not dispersed.

The pressure plate 4 can be projected and retracted through a through hole 3 b formed in the recess 3 a of the housing 3, and is held swingably by a parallel movement mechanism 11 provided inside the housing 3.
The parallel movement mechanism 11 includes two metal leaf springs 11a provided in parallel and two spacers 11b sandwiched between both ends of the leaf spring 11a. 3 and the pressure plate 4 is fixed to the position of the upper spacer 11b in the leaf spring 11a.
According to the above configuration, the two leaf springs 11a try to maintain a straight extension state as shown in FIG. 1 due to their own elastic force, and in this straight extension state, the pressure plate 4 is moved to the housing 3. It is located at the measurement start position in contact with the inner wall of the recess 3a.
From this state, when the upper end portion of the leaf spring 11a is pressed from the opposite side of the pressure plate 4, the two leaf springs 11a are deformed while being kept parallel by the spacer 11b, and thereby the pressure plate 4 is deformed. Can advance horizontally while the pressure surface 4a faces in the vertical direction, and the angle formed by the pressure plate 4 and the pressure receiving plate 5 can be kept constant.

The pressure receiving plate 5 can be projected and retracted through a through hole 3 b formed in the recess 3 a of the housing 3, and is held swingably by a leaf spring 12 provided inside the housing 3.
When the ball 1 is not sandwiched between the pressure plate 4 and the pressure plate 4, the pressure receiving plate 5 protrudes inside the recess 3 a of the housing 3 by the urging force of the leaf spring 12.
When the ball 1 is sandwiched between the pressure plate 4 and the pressure receiving plate 5, the ball 1 presses the pressure receiving plate 5 to the outside of the recess 3 a, the pressure receiving plate 5 contacts the housing 3, and the pressure plate 4 and the pressure receiving plate 5 form an angle formed by 30 degrees.

The operating lever 6 includes a substantially L-shaped swinging member 13 that is swingably provided inside the housing 3, and a grip portion 14 that is provided on a portion of the swinging member 13 that extends substantially horizontally to the left in the drawing. And a pressing pin 15 provided at the tip of a portion of the swinging member 13 that extends upward in the figure.
The swing member 13 is held so as to be swingable around a bearing portion 3c provided inside the housing 3, and the grip portion 14 is moved from a non-operation position indicated by a two-dot chain line to a measurement start position indicated by a solid line. It is designed to move.
The pressing pin 15 is located on the back side of the pressure plate 4 held by the parallel movement mechanism 11 and retracts to the left in the drawing from the leaf spring 11a of the parallel movement mechanism 11 at the measurement start position shown in FIG. It has become.

The biasing means 7 includes a spring 16 that is elastically mounted between the bottom of the housing 3 and the swing member 13 of the operation lever 6, and an adjustment means 17 that adjusts the biasing force of the spring 16. Yes.
The spring 16 biases the operating lever 6 toward the non-operating position. When the operating lever 6 swings from the measurement start position toward the non-operating position by the biasing force of the spring 16, the pressing pin 15 is applied. The upper part of the leaf spring 11 a of the parallel movement mechanism 11 is pressed from the back side of the pressure plate 4.
Then, when the pressure plate 4 located at the measurement start position moves forward toward the inside of the ball 1 and then the operation lever 6 reaches the non-operation position, the pressure plate 4 is maximized from the recess 3a of the housing 3. It is designed to protrude as much as possible.
The adjusting means 17 includes a bolt 17a that penetrates the grip portion 14 and the swing member 13 of the operation lever 6, a nut 17b that is fixed to the lower surface of the swing member 13 and that is screwed with the bolt 17a, and the nut 17b. The spring 17 is fixed to the tip of a bolt 17a that protrudes further downward and holds one end of the spring 16.
With the above configuration, the spring receiving portion 17c can be protruded and retracted from the nut 17b by rotating the bolt 17a, and thereby the biasing force of the spring 16 can be adjusted.

As shown in FIGS. 1 and 3, the warning means 8 includes a battery 21, a first switch 22 that operates when the pressure plate 4 and the pressure receiving plate 5 hold the ball 1, and the pressure plate 4 A second switch 23 that operates when positioned at the measurement start position, a third switch 24 that operates when the pressure plate 4 moves a predetermined distance or more from the measurement start position to the inside of the ball 1, and a buzzer 25 that generates a warning sound. And a wiring 26 (not shown in FIG. 1) for connecting them.
The first switch 22 is provided on the back side of the pressure receiving plate 5 in the housing 3 and is turned OFF when the pressure receiving plate 5 protrudes inside the recess 3a of the housing 3 by the biasing force of the leaf spring 12. 1, the ball 1 is turned ON when the ball 1 is sandwiched between the pressure plate 4 and the pressure receiving plate 5.
The second switch 23 is disposed in the vicinity of the operation lever 6 of the housing 3 so as to face upward, and the third switch 24 is disposed to face the second switch 23 so as to face downward. Yes. A detection piece 27 is provided on the lower surface of the operation lever 6 so as to come into contact with the second and third switches 23 and 24.
When the operation lever 6 is positioned at the measurement start position, the detection switch 27 turns on the second switch 23 and turns off the third switch 24.
On the other hand, when the operation lever 6 is positioned at the non-operating position, the third switch 24 is turned on by the detection piece 27 and the second switch 23 is turned off.
Since the detection piece 27 is detached from both the second switch 23 and the third switch 24 while the operation lever 6 moves from the measurement start position to the non-operation position, the second switch 23 and the third switch The switch 24 is turned off.

In FIG. 3, the circuit of the warning means 8 is arranged in the order of the battery 21, the first switch 22, the second switch 23, the third switch 24, and the buzzer 25. The first and third switches 22 and 24 are one circuit and one contact. The second switch 23 is a changeover switch for one circuit and two contacts.
In the second switch 23, the circuit branches in two directions. When the second switch 23 is ON, a circuit is directly connected to the buzzer 25. When the second switch 23 is OFF, the buzzer 25 is connected via the third switch 24. The circuit to be connected to is configured.

A method for determining the amount of splash of the ball 1 using the splash amount judging device 2 having the above-described configuration will be described.
First, in a non-use state in which the amount of splash of the ball 1 is not determined by the amount of splash determination device 2, the operation lever 6 is positioned at the non-operating position by the biasing force of the biasing means 7, and the pressure plate 4 is The pressing pin 15 projects into the recess 3 a of the housing 3.
Further, the pressure receiving plate 5 is in a state of projecting inside the recess 3a of the housing 3 by the urging force of the leaf spring 12, whereby the first switch 22 of the warning means 8 is OFF.
Since the operation lever 6 is in the non-operating position, the second switch 23 is turned off and the third switch 24 is turned on by the detection piece 27 provided on the operation lever 6.
That is, in the unused state of the splash amount determination device 2, the circuit of the warning means 8 has the first switch 22 OFF, the second switch 23 OFF, and the third switch 24 ON, and the current from the battery 21 Does not flow to the buzzer 25, so that a warning sound from the buzzer 25 is not emitted.

Next, when using the amount determination device 2, the user first presses the operation lever 6 to the measurement start position against the urging force of the urging means 7.
Then, the swinging member 13 of the operating lever 6 swings and the pressing pin 15 moves backward, and the leaf spring 11a of the parallel movement mechanism 11 that holds the pressing plate 4 returns straight due to its elastic force, The pressure plate 4 moves backward to the measurement start position.
Further, by setting the operation lever 6 to the measurement start position, the second switch 23 is turned on and the third switch 24 is turned off by the detection piece 27 provided on the operation lever 6.
That is, when the user presses the operation lever 6 to the measurement start position, the circuit of the warning means 8 is such that the first switch 22 is turned off, the second switch 23 is turned on, and the third switch 24 is turned off. There is no warning sound.

Subsequently, the user inserts the ball 1 into the recess 3 a of the housing 3 while pressing the operation lever 6 to the measurement start position, and holds the ball 1 between the pressure plate 4 and the pressure receiving plate 5. .
At this time, the pressure plate 5 is pressed by the ball 1 to form an angle of 30 ° between the pressure plate 4 and the pressure plate 5, so that the ball 1 is pressed against the pressure plate regardless of the diameter of the ball 1. 4 and the pressure receiving plate 5 can be clamped.
When the ball 1 is sandwiched between the pressure plate 4 and the pressure receiving plate 5, the pressure plate 4 comes into contact with the first switch 22 of the warning means 8, and the first switch 22 is turned on.
That is, when the user holds the ball 1 between the pressure plate 4 and the pressure receiving plate 5 while pressing the operation lever 6 to the measurement start position, the first switch 22 is turned on in the circuit of the warning means 8 and the second switch. 23 is ON and the third switch 24 is OFF.
As a result, the current from the battery 21 is energized to the buzzer 25, and a warning sound is emitted from the buzzer 25. This warning sound indicates that the measurement of the amount of splash of the ball 1 can be started.
Further, if the user observes the amount-of-bending amount determination device 2 from the direction of FIG. 2 in a state where the ball 1 is sandwiched between the pressure plate 4 and the pressure receiving plate 5, the diameter of the ball 1 is within the range of the above standard. It can be determined whether it is within.
Specifically, when the two marks 5b provided on the pressure plate 4 and the pressure receiving plate 5 are not visible when viewed from the direction of FIG. 2, the ball 1 is a ball 1 having a diameter larger than the standard, and conversely When two marks 5b are visible, the ball 1 is a ball 1 having a smaller diameter than the standard.

When the warning sound from the warning means 8 is confirmed, the user gradually opens the operation lever 6 positioned at the measurement start position.
Then, the operating lever 6 tries to return from the measurement start position to the non-operating position by the urging force of the urging means 7, whereby the pressure plate in which the pressing pin 15 of the operating lever 6 is held by the parallel movement mechanism 11. 4 is pressed from the back side.
Then, the pressure plate 4 is advanced in parallel toward the ball 1 by the parallel movement mechanism 11, so that the pressure plate 4 applies a pressing force toward the center of the ball 1 regardless of the diameter of the ball 1. Will act.
The spring 16 of the biasing means 7 generates a biasing force conforming to the standard by the adjusting means 17, and the pressing plate 4 deforms the ball 1 by the biasing force and deforms the inside of the ball 1. Move forward toward.
The advance amount of the pressure plate 4 at this time varies depending on the amount of the ball 1 to be judged, and when the ball 1 is small, that is, when the ball 1 is soft, the pressure plate 4 advances greatly and the amount of the fly is large. In some cases, it will be a small step forward.
Further, when the pressure plate 4 moves forward in this way, the operation lever 6 pressing the pressure plate 4 by the urging means 7 moves from the measurement start position toward the inoperative position.

When the amount of splash of the ball 1 is within the range of the standard, the urging force of the urging means 7 and the elastic force of the ball 1 are balanced, and the operation lever 6 stops between the measurement start position and the non-operation position. .
As a result, after the detection piece 27 provided on the operation lever 6 is detached from the second switch 23, the detection piece 27 stops without contacting the third switch 24, so the second and third switches 23 are turned off.
That is, in the circuit of the warning means 8, the first switch 22 is turned on, the second switch 23 is turned off, and the third switch 24 is turned off, so that the warning sound from the buzzer 25 is stopped.
As described above, when the warning sound is stopped by releasing the operation lever 6 after the warning sound indicating that the measurement of the ball 1 can be started, the amount of splash of the ball 1 is within the range of the standard. Can be determined to be within.

Next, when the amount of fly of the ball 1 is smaller than the above standard, the pressure plate 4 moves forward to the position where it protrudes to the maximum while resisting the elastic force of the ball 1 by the urging force of the urging means 7. The operation lever 6 moves to the non-operating position.
As a result, since the detection piece 27 provided on the operation lever 6 is detached from the second switch 23 and contacts the third switch 24, the second switch 23 is turned off and the third switch 24 is turned on.
That is, in the circuit of the warning means 8, the first switch 22 is turned on, the second switch 23 is turned off, and the third switch 24 is turned on. Become.
After the warning sound indicating that the measurement of the ball 1 can be started in this way, when the warning sound stops and the warning sound is generated again, the amount of splash of the ball 1 is based on the above standard. Can be determined to be small.

On the other hand, when the amount of the ball 1 is larger than the above standard, the pressure plate 4 can hardly move forward against the elastic force of the ball 1, so that the operation lever 6 is located near the measurement start position. Stay stopped.
As a result, the detection piece 27 provided on the operation lever 6 is not detached from the second switch 23, the second switch 23 remains ON, and the third switch 24 also remains OFF.
That is, in the circuit of the warning means 8, the first switch 22 is turned on, the second switch 23 is turned on, and the third switch 24 is turned off, so that a warning sound is continuously generated from the buzzer 25.
In this way, when the warning sound is continuously generated after the warning sound indicating that the measurement of the ball 1 can be started, the amount of splash of the ball 1 is larger than the above standard. It can be determined that there is.

According to the fly amount determination device 2 in the above embodiment, the ball 1 having a desired fly amount can be determined by changing the biasing force of the spring 16 by the adjusting means 17 of the biasing means 7.
On the other hand, in order to set the ball 1 having a fly amount equivalent to the above standard using the adjusting means 17, an unillustrated test piece is inserted between the pressure plate 4 and the pressure receiving plate 5 to reduce the biasing force. Adjustments can be made.
As this test piece, a spring-cylindered cylinder and piston having an urging force capable of obtaining the amount of deflection in the above-mentioned standard in advance can be considered.
Then, while the cylinder of this test piece is brought into contact with the pressure plate 4 and the piston is brought into contact with the pressure receiving plate 5, the amount-of-slip determination device 2 is operated according to the above procedure, so that no warning sound from the warning means 8 is generated at this time. By adjusting the adjusting means 17, the urging force by the urging means 7 can be adjusted to an appropriate value.

The splash amount determination device 2 determines the splash amount of the ball 1 that is deformed by pressing, such as the soft ball 1 of the soft baseball and the tennis ball 1 of the soft tennis, in addition to the tennis ball 101 used for the hard tennis. Can do.
Thus, when measuring the ball 1 of a different game, the biasing force of the spring 16 by the biasing means 7 may be changed by the adjusting means 17.
In the present embodiment, the angle formed by the pressure plate 4 and the pressure receiving plate 5 is 30 °. However, when the ball 1 is sandwiched, the pressure plate 4 and the pressure receiving plate 5 cross each other, If 1 can be clamped, it can be set freely.
Furthermore, unevenness may be formed on the pressure surface 4a of the pressure plate 4 and the pressure surface 5a of the pressure plate 5 to prevent the ball 1 from being displaced.

FIG. 4 shows a cross-sectional view of the splash amount determination device 102 according to the second embodiment, in which the ball 101 having a small splash amount smaller than the above standard is determined with respect to the splash amount determination device 2 in the first embodiment. It has become.
In the following description, description of parts common to the amount determination device 2 of the first embodiment will be omitted, and description will be made using a code obtained by adding 100 to the code used in FIG.
The concave portion 103a of the housing 103 holds the pressure plate 104 and the pressure receiving plate 105 in a state inclined by 10 ° with respect to the vertical direction, and the pressure plate 104 is held in a state inclined by the parallel movement mechanism 111. On the other hand, the pressure receiving plate 105 is fixed to the inner surface of the recess 103a.
That is, the splash amount determination device 102 of the present embodiment also determines the splash amount of the ball 101 regardless of the diameter by providing the pressure plate 104 and the pressure receiving plate 105 so as to cross each other and sandwiching the ball 101. It is possible to do.

The operating lever 106 includes a substantially L-shaped swinging member 113 swingably provided on the bearing portion 103c inside the housing 103, and a grip provided at a position spaced above the left end of the swinging member 113 in the figure. Part 114 and a pressing pin 115 provided at the tip of the swinging member 113 extending upward in the figure. The biasing means 107 is provided between the swinging member 113 and the grip part 114. Yes.
A first spring 118 is elastically mounted on the lower surface of the swinging member 113 on the left side of the bearing 103c with respect to the housing 103, and a detection piece 127 is formed on the left end of the swinging member 113. Yes.
In a non-use state of the amount-of-slip determination device 102 shown in FIG. 4, the pressing pin 115 provided on the swing member 113 by the first spring 118 is detached from the back side of the pressing plate 104, and the detection piece 127 abuts against a stopper 103 d formed inside the housing 103 and prevents further swinging.
The grip part 114 is provided so as to be movable up and down with respect to the housing 103, and a flange 114 a formed at the lower end of the grip part 114 abuts on a step 103 e formed inside the housing 103. The amount of movement is limited.

The biasing means 107 includes a second spring 116 elastically mounted between the swinging member 113 of the operation lever 106 and the grip portion 114, and an adjusting means 117 for adjusting the biasing force of the second spring 116. It is configured.
The second spring 116 urges the swing member 113 of the operation lever 106 and the grip portion 114 in a direction separating them from each other, and the second spring 116 is set to have a higher urging force than the first spring 118. ing.

The warning means 108 includes a battery 121, a switch 124 corresponding to the third switch 24 of the first embodiment, a buzzer 125 that generates a warning sound, and a wiring (not shown) that connects them in series. Yes.
The switch 124 is disposed in the vicinity of the operation lever 106 of the housing 103 so as to face upward. When the swing member 113 of the operation lever 106 swings and the detection piece 127 comes into contact, the switch 124 is turned on. And the buzzer 125 are energized to generate a required warning sound.

The operation of the amount determination device 102 having the above configuration will be described. First, when the amount determination device 102 is not used in this embodiment, the urging force from the urging means 107 acts on the pressure plate 104. In addition, the pressure plate 104 is located at the measurement start position in contact with the inner wall of the recess 103 a of the housing 103 by the parallel movement mechanism 111.
The grip portion 114 of the operation lever 106 protrudes upward from the housing 103 due to the urging force of the first spring 118 and the second spring 116, and the detection piece 127 formed on the swing member 113. Is in contact with a stopper 103 d formed in the housing 103 and is detached from the switch 124.
Then, the user accommodates the ball 101 in the recess 103 a of the housing 103 in the unused amount determination device 102 and holds the ball 101 between the pressure plate 104 and the pressure receiving plate 105.
At this time, the pressure plate 104 and the pressure receiving plate 105 are provided so as to intersect with each other, and the pressure surface of the pressure plate 104 and the pressure receiving surface of the pressure receiving plate 105 are marked with respect to the diameter of the ball 101. Thus, the user can determine whether or not the diameter of the ball 101 conforms to the standard.

Subsequently, the user presses the grip portion 114 of the operation lever 106 downward, and lowers the flange 114a of the grip portion 114 until it contacts the step 103e formed inside the housing 103.
Then, the illustrated left end portion of the swinging member 113 swings downward against the urging force of the first spring 118, and the pressing pin 115 advances and contacts the back surface of the pressing plate.
Here, since the second spring 116 of the biasing means 107 has a biasing force larger than that of the first spring 118, the left side of the swinging member 113 is biased downward by the biasing force of the second spring 116, As a result, the pressure plate 104 pressed by the pressing pin 115 moves forward while deforming the ball 101.
At this time, since the pressure plate 104 is moved in parallel by the parallel movement mechanism 111, the ball 101 can be pressed from the same direction regardless of the difference in diameter.
When the amount of splash of the ball 101 is equal to or greater than the lower limit value of the above standard, the urging force of the second spring 116 and the elastic force of the ball 101 are positions where the detection piece 127 of the swing member 113 does not contact the switch 124. Let's balance.
That is, since the circuit of the warning means 108 maintains the switch 124 in the OFF state, when the warning sound is not generated from the buzzer 125, it can be determined that the amount of splash of the ball 101 is within the range of the standard.
On the contrary, when the amount of the ball 101 is smaller than the above standard, the urging force of the second spring 116 does not balance with the elastic force of the ball 101, and the pressure plate 104 moves forward to detect the detection piece of the swing member 113. 127 contacts the switch 124.
That is, the circuit of the warning means 108 can determine that the amount of splash of the ball 101 is smaller than the above standard because the switch 124 is turned on and the battery 121 and the buzzer 125 are energized to generate a warning sound.

FIG. 5 shows a splash amount determination device 202 according to the third embodiment. This splash amount determination device 202 determines the splash amount of a large-diameter ball 201 such as a volleyball.
Here, according to the Japan Volleyball Association, the volleyball standard is defined as 65-67 cm in circumference, 260-280 g in weight, and 294.3-318.2 hPa in internal pressure.
In the following description, description of parts common to the amount determination device 102 of the second embodiment will be omitted, and description will be made using a code obtained by adding 100 to the code used in FIG.
The concave portion 203a of the housing 203 holds the pressure plate 204 and the pressure receiving plate 205 in a state where each of the pressure plate 204 and the pressure receiving plate 205 is inclined by 10 ° with respect to the vertical direction. On the other hand, the pressure receiving plate 205 is fixed to the inner surface of the recess 203a.
That is, the splash amount determination device 202 of the present embodiment also determines the splash amount of the ball 201 regardless of the size of the diameter by providing the pressure plate 204 and the pressure receiving plate 205 so as to cross each other and sandwiching the ball 201. It is possible to do.

The operating lever 206 includes a substantially L-shaped swinging member 213 swingably provided on a bearing portion 203 c inside the housing 203 and a stepping portion 214 provided so as to straddle the ball 201 above the housing 203. And a pressing pin 215 provided at the tip of the swinging member 213 extending upward in the figure, and the biasing means 207 is provided between the swinging member 213 and the stepping portion 214.
The left end portion of the swing member 213 constitutes a detection piece 227, and when it is not in use, the amount determination device 202 shown in FIG. 5 is in contact with the stopper 203d formed inside the housing 203 and swings further. It is supposed not to.
The step portion 214 is pressed downward by an operator with his / her foot, and the two support members 214a provided below both ends of the step portion 214 slide in the vertical direction with respect to the housing 203. Held possible.
The lower ends of the support member 214a are connected to each other by a connecting member 214b, and a first spring 218 is mounted between the lower surface of the connecting member 214b and the housing 203.
Due to the urging force of the first spring 218, the stepping portion 214 is positioned at the rising end when the amount-of-slip determining device 202 is not in use.
When the operator presses the stepping portion 214 downward, the connecting member 214b comes into contact with the bottom surface of the housing 203, and the stepping portion 214 stops.

The biasing means 207 adjusts the biasing force of the second spring 216 elastically mounted between the swing member 213 of the operation lever 206 and the connecting member 214b of the stepping portion 214, and the second spring 216. And adjusting means 217.
The second spring 216 is accommodated in a case 219 provided on the upper surface of the connecting member 214b, and the upper end of the second spring 116 elastically contacts the upper surface of the case 219 to urge the stepping portion 214 upward. At the same time, the swing member is biased downward. The second spring 116 is set to have a higher urging force than the first spring 218.
The upper end of the bolt 217a constituting the adjusting means 217 is screwed into a nut 217b provided on the upper surface of the swinging member 213, and the bolt 217a is biased downward by a second spring 116 elastically mounted on a spring receiving portion 217c. Then, the left side of the swing member 213 in the figure is moved downward, thereby moving the pressing pin 215 to the pressure plate 204 side.

The warning means 108 has a battery 221, a switch 224, and a buzzer 225 wired in series as in the amount measuring device 102 of the second embodiment, and the switch 224 has an operation lever 206 of the housing 203. It is arrange | positioned in the state which faced the upper direction in the vicinity.
The switch 224 is turned on when the swing member 213 of the operation lever 206 swings and the detection piece 227 comes into contact, and the battery 121 and the buzzer 125 are energized to generate a required warning sound. Yes.
The operation of the amount determination device 202 having the above configuration has no fundamental difference except that the user operates the stepping portion 214 of the operation lever with his / her foot, and thus detailed description thereof will be omitted.

In addition, the splash amount determination devices 102 and 203 in the second and third embodiments are configured to be able to determine a ball whose fly amount exceeds the standard as in the splash amount determination device 2 of the first embodiment. It is also possible.
Specifically, as in the first embodiment, the pressure receiving plate is provided so as to be able to protrude and retract with respect to the housing, the first switch 22 is provided on the back side of the pressure receiving plate, and the position facing the switches 124 and 224 above. The second switch 23 may be provided, and the circuit of the warning means 8 may have the same configuration as that of the splash amount determination device 2 of the first embodiment.
Even in such a configuration, it is not necessary to operate the operation lever 6 to position the pressure plate 4 at the measurement start position as in the first embodiment, and the ball is moved from the unused state to the pressure plate. And the pressure receiving plate, the first switch is turned on and a warning sound is generated.
After that, when the grip or stepping part of the operation lever is pressed downward and the warning sound disappears, the amount of ball splash is within the range of the above standard. If it is smaller than the standard and the warning sound continues to sound without disappearing, it will be larger than the standard.

In the above-described first to third embodiments, the angle formed between the pressure plate and the pressure receiving plate is an acute angle. For example, if anti-skid means such as irregularities is formed on the pressure surface and the pressure receiving surface. The angle formed above can be an obtuse angle.
Moreover, it is also possible to provide a plurality of these pressure plates and pressure receiving plates. Specifically, a plurality of pressure plates and pressure receiving plates may be arranged in a substantially mortar shape so that even a small-diameter ball and a large-diameter ball can be sandwiched.

DESCRIPTION OF SYMBOLS 1 Ball | bowl 2 Splash amount determination apparatus 3 Housing 4 Pressure plate 5 Pressure receiving plate 6 Operation lever 7 Energizing means 8 Warning means 11 Translation mechanism 17 Adjustment means 22 1st switch 23 2nd switch 24 3rd switch 25 Buzzer

Claims (2)

A pressure plate that presses the ball by the biasing force of the biasing means, and a pressure receiving plate that is provided on the opposite side of the pressure plate and holds the ball between the pressure plate,
The pressure plate is advanced to the inside of the ball from the measurement start position where the pressure plate is retracted to the outside of the ball by the urging force of the urging means, and the amount of splash of the ball is determined by the amount of movement of the pressure plate due to the deformation of the ball In the splash amount determination device,
The pressing in a state where the pressure plate is located at the measurement start position, momentum amount determination apparatus characterized by and the pressure plate and the pressure plate is arranged so that such a and a predetermined angle not parallel.   2. The amount determination device according to claim 1, further comprising a parallel movement mechanism for moving the pressure plate while maintaining an angle formed by the pressure plate and the pressure receiving plate constant.

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