HU194500B - Apparatus for evaluating and signalling the touches of sword-play and vibration sensor particularly for this apparatus - Google Patents

Abstract

In this device for evaluating and displaying valid and invalid hits when blows are struck in fencing and which comprises left and right hit-surfaces A1, A2, left and right sabres comprising respective blades B1, B2, shells (coquilles) B3, B4 and handles (hilts) and a metallic mat, the hit surfaces, the sabres and the metallic mat being connected to a processing and displaying system, vibration sensors C1, C2 which are sensitive to the acceleration and to the frequency of mechanical vibrations are mounted in the shells (coquilles) B3, B4 of the sabres and a sensor of the force of blows with the tip, equipped with a switch C3, C4, is mounted in the handle (hilt) of each sabre. Application, particularly, to fencing. <IMAGE>

Description

FIELD OF THE INVENTION The present invention relates to an apparatus for evaluating and displaying hits during sword fencing, preferably valid and invalid hits achieved by edge, degree, blade cutting, and stabbing, which apparatus has a valid right and left hit surface, a sword basket, sword blade and sword grip. it has a sword on the left and on the left, and is provided with a metal carpet, where the valid hit surface and the sword are connected to an evaluation display system.

The invention also relates to a vibration detector, preferably for the above apparatus.

Evaluating and displaying hits on an invalid hit surface so that the fencer does not need to wear metal trousers, and edges, tails, edges, cuts and stabs are detected on a valid and invalid hit surface, where a valid hit surface is formed by a metal vest and headgear . Displaying the results available on an invalid hit surface (also known as deep cut or puncture) can be accomplished by prior art using metal fiber trousers connected to a common circuit unit via a cable harness. This idea is not supported by fencers because of the extra cost.

In the solution described in HU 189996, an electromechanical vibration sensor is incorporated into the sword. By using a vibration detector according to this solution, any mechanical vibration results in an invalid hit signal, even if, for example, the fencer merely shakes his sword.

It is also known that the whole sword blade moves longitudinally in the sword handle by the force of a jerk and this switches an electrical switch. It is slightly disadvantageous that the back of the sword blade is not screwed together as usual, but a specially designed basket is integrated with the handle, to which the specially designed sword blade moves, and the mechanics of the given strength are heavier than usual according to the skilled person.

It is an object of the present invention to provide an apparatus for ensuring that a sword does not receive an invalid hit signal when striking the sword, either when striking an opponent or on its own valid hit surface, or when being hit or hit on the ground.

In the evaluation display system, to prevent invalid hit signaling, we must include prohibitions that eliminate mechanical vibrations caused by the collision of the right and left swords, and the impact of the sword on its own and the opponent's valid hit surface. an electrical signal emitted by a vibration sensor caused by a collision with a standard metal carpet covering a pâté.

Another task is to eliminate the display of valid hits with the swords basket.

To solve this problem, we have created an apparatus having a valid hit surface on the right and left, a right and left sword consisting of a swords basket, a sword blade and a handle, and a metal mat with a valid hit surface and an evaluation display system according to the invention, a vibration detector responsive to the acceleration and frequency of mechanical vibrations and a puncture force sensor with a switch in the sword grip are arranged in the sword basket.

Edge, degree, and blade cuts and punctures are detected on a valid and invalid hit surface with a vibration sensor built into the swords basket and a puncture force sensor with a switch.

The vibration detector in the swords basket provides a three-way sensitive electronic switch, which means an electrical break at rest, but senses mechanical vibrations at the edges of edges, degrees, blades and stings, and is sensitive to the frequency of mechanical vibrations.

In the apparatus according to the invention, the vibration detector is provided with a low cut filter and the vibration sensor can be configured in series with an electromechanical converter, a low cut filter, a rectifier circuit and an electronic switch, wherein the electronic switch output has a output is the output terminal of the vibration sensor.

In a preferred embodiment of the device according to the invention, the puncture sensing device with the switch is integrated in the sword grip with a socket fixed on the sword blade, on which the switch is mounted, and a sliding sword grip pre-tensioned on the fixed socket wherein the sliding sword grip has an anti-skid plate at one end and a split sleeve at the other end, and a palm resting plate attached to the split sleeve.

The device according to the invention can be advantageously configured by connecting the left and right hit surface to the input of a first and second adapter circuits and to a resistor or to a current generator via a current generator, respectively. it is connected to one or more corners of the power supply via a resistor. The left and right sword blades are connected via a resistor to the left and right swords basket, on the one hand, and to one of the clamps on the left and right swords, it is connected to the input of a third or fourth adapter circuit and to a left or right voltage source via a resistor, respectively. The other terminal of the left and right sword vibration detector is located at the pins on the left and right sword grip pins, the inputs of the fifth and the sixth adapter circuits, and one of the corners of the power supply via a resistor. connected.

The output of the first interface circuit is connected to one of the inputs of the second logic gate circuit, while the output of the second interface circuit is connected to an input of the first logic gate circuit. The output of the third adapter circuit leads to an input of a third logic gate circuit while the output of the fourth adapter circuit leads to an input of a fourth logic gate circuit

194,500 ve. The output of the fifth interface circuit is connected via a first timing circuit to the other input of the third logic gate circuit and to an input of the third timing circuit and to the other input of the first logic gate circuit. The output of the sixth interface circuit is connected via a second timing circuit to the other input of the fourth logic gate circuit and to the other input of the third timing circuit and to the other input of the second logic circuit.

The output of the third timing circuit is led to the third input of the first and second logic gate circuits. The output of the first logic gate circuit is connected to the input of a first logic storage and drive circuit that passes through a valid hit to the right fencer, the output of which is connected to a first hit indicator lamp.

The output of the second logic gate circuit is led to an input of a second logic storage and drive circuit that passes through a valid hit for the left fencer, the output of which is connected to a second hit indicator lamp.

The output of the third logic auxiliary circuit is connected to the input of a third logic storage and drive circuit, which is connected to a third hit indicator lamp and is inclined to an invalid hit on the right fencer.

The output of the fourth logic gate circuit is connected to the input of a fourth logic storage and drive circuit, which is connected to a fourth lamp, and passes through an invalid hit to the left fencer.

Finally, a metal carpet that eliminates the need for a puncture puncture is led to one of the terminals of the power supply spinning through an interposed resistor.

Preferably, the resistance between the sword blade and the sword basket is greater than the maximum resistance required for the fifth and second adapter circuits and the first and sixth adapter circuits to be tilted together and less than the maximum resistance required to jointly rotate the fifth and sixth adapter circuits.

In this case, we will not receive a valid hit when a swordsman collides with a valid hit surface. When evaluating invalid hits, the scoring system includes the same timing circuit for both fencers which, when two swords collide with each other, or one sword collides with a valid hit surface, or swords collide with a metal mat. Disable the display for a predetermined period of prohibition.

The invention will now be described in more detail with reference to preferred embodiments, by means of a drawing, wherein:

Figure 1 is a simplified circuit diagram of the apparatus of the invention, a

Fig. 2 is a time diagram illustrating the operation of the apparatus for displaying valid hits, a

Figure 3 is a time diagram illustrating the operation of the equipment for displaying invalid hits, a

Figure 4 is a simplified circuit diagram of a vibration detector for use in the apparatus of the present invention, and

Figure 5 is a simplified mechanical drawing of a puncture sensor embedded in a sword grip.

The device according to the invention (Fig. 1) can be advantageously configured such that the left and right valid surface A1, A2 have a first and second input circuit II, 14 input, respectively, and a resistor R1 and R8, respectively. or is connected via a power generator E1 or E2 to one of the corners D1 and D2, respectively, and is connected via a resistor R2 and R7, respectively, to one of the corners D2 and D1, respectively. The left and right sword blades B1 and B2 are connected via a resistor R5 and R6, respectively, to the left and right swords B3 and B4, and to the left and right B3 and B4 swords, with one of the terminals of the vibration detector C2 and one of the switches C3 and C4 on the left and right and in the sword grip, respectively, through the third and fourth inputs of the 12,15 interface circuits, and through the resistors R3, R9 connected to the right U1, U2 voltage source. The other terminal C1, C2 in the left and right swords B3 and B4, respectively, has the other terminal of the latch force sensor with switch C3, C4 with the left and right sword grips, with each of the fifth and sixth inputs 13,16, and is connected to one of the corners D1 and D2 of the power supply via a resistor R4, RIO, respectively.

The output of the first interface circuit II is connected to an input of a second logic gate circuit K2, while the output of the second interface circuit 14 is connected to an input of a first logic gate circuit KI. The output of the third interface circuit 12 is directed to one of the inputs of the third logic gate circuit K3, while the output of the fourth interface circuit 15 is directed to an input of the fourth logic gate circuit K4. The output of the fifth interface circuit 13 is connected via a first TI timing circuit to one of the inputs of the third logic gate circuit K3 and to an input of a third T3 timing circuit and to the other input of the first logic gate circuit KI. The output of the sixth interface circuit 16 is connected via a second timing circuit T2 to a second input of a fourth logic gate circuit K4, and to a second input of a third timing circuit T3 and a second input of a second logic gate circuit K2.

The output of the third timing circuit T3 is led to the third input of the first and second logic gate circuits K1, K2.

The output of the first logic gate circuit KI is connected to the input of a first logic storage and drive circuit S1, which is connected to a first hit indicator L1, which is connected to a valid hit for the right fencer.

The output of the second logic gate circuit K2 is led to the input of a second logic storage and drive circuit S2, which is connected to a second hit indicator lamp L2, which passes over a valid hit for the left fencer.

The output of the third logic gate circuit K3 is connected to the input of a third logic storage and drive circuit S3, which is connected to a third hit indicator lamp L3, in the event of an invalid hit to the right fencer.

The output of the fourth logic gate circuit K4 is connected to the input of a fourth logic storage and drive circuit S4, which is connected to a fourth lamp L4, and passes through an invalid hit to the left fencer.

Finally, the carpet M, which eliminates the indication of phoid puncture, is led to one of the power supply sources D1, D2 through an interposed resistor R1, R12.

The operation of the apparatus will now be illustrated in the light of practical situations.

The simplest case of displaying a valid hit is: for example, the sword blade B2 is cut or inserted into the valid hit surface A1 on the left. If the acceleration value is higher than the specified for edge, degree or blade cutting or puncture, the vibration sensor C2 will conduct electrically, or the electric switch C4 operating at a force greater than the specified force will conduct. The circuit closes in the following way between the power supply terminals D1 and D2; Via a resistor R1 and R10, a valid hit surface A1, a sword blade B2, a vibration sensor C2 or a power switch C4 acting on the force (Fig. 1).

The logic levels at the outputs of the first and sixth interface circuits II and 16 are varied such that the logic storage and drive circuit S2 at the output of the second logic gate circuit K2 is tilted, as indicated by the second lamp L2.

In case of a hit on an invalid hit surface, refer to Figure 3a! monitor the operation of the circuit board.

For acceleration at edge, degree, or blade cutting or puncture, the vibration detector Cl or C2 is electrically conductive, or a power switch C3 or C4 is operating at a higher puncture force. For example, by default, the input of the fourth interface circuit 15 is at the same voltage level as the voltage source U2. When the vibration sensor C2 or power switch C4 is driven, the circuit closes between the voltage source U2 and the other terminal D2 of the power supply: at resistor R9 and RIO, and at the vibration sensor C2 or at the power switch C4 (time moment x1). Since RIO resistance is approx. an order of magnitude less than resistor R9, the input voltage of the fourth interface circuit 15 drops below the tilt level U _{bi) 1} , whereas the voltage across the RIO resistor is only so low that the sixth interface circuit 16 does not overturn. In this case, the second timing circuit T2 also does not provide a stop signal, so the signal of the fourth interface circuit 15 passing through the fourth logic gate circuit K4 tilts the fourth logic storage and drive circuit S4 and indicates the fourth lamp L4.

If a fencer cuts or stabs at his own valid hit surface, then 3 / b. The operation of the circuit unit can be monitored according to Fig.

For example, the right-hand fencer cuts or stabs on its own valid hit surface A2 with a sword blade B2. Compared to the previous case, a closed circuit is also created between terminals D1 and D2 of the power supply: via a resistor R7 and RIO, a valid hit surface A2, a sword blade B2 and a vibration sensor C2 and / or a power switch C4. Since the resistor R7 is of the same order as the RIO resistor, the voltage at the input of the sixth circuit 16 il4 is such that its output goes to another logic state. As a result, the second pulse circuit T2 provides an input signal to the input of the fourth logic gate circuit K4 (time x2). As long as the valid hit surface A2 and the sword blade B2 are in electrical contact, there is no need to disable the second timing circuit T2 because the input of the fourth interface circuit 15 has not fallen below its own tilt voltage level U _bi n. However, when the electrical contact is interrupted, the vibration detector C2 or the electric switch C4 acting on power may still be in a conductive state for a few times 10 ms, so that the input of the fourth interface circuit 15 drops below the torsional voltage level U _bi | i. However, the output signal of the fourth interface circuit 15 is not yet effective on the fourth logic gate circuit K4, because the second timing circuit T2 is still disabled, so no invalid hit signal is received.

If, for example, the right fencer cuts or inserts on the carpet M with the sword blade B2, the following circuit closes between terminals D1 and D2 of the power spun: R11 and RIO, M carpet, B2 sword blade, and C2 vibration sensor and / or power. switch.

Since the values of resistances R11 and R12 are equal to those of RIOs of the same magnitude, the previous case can be followed from Fig. 3 / b, and no valid hit signal is obtained.

For example, if the right fencer cuts or pricks with a sword blade B2 on the left hit surface A1, then there is a valid hit without the blade contact. Therefore, in this case, do not produce invalid hit signals, the circuit also operates as shown in Figure 3 / b, i.e. the contact time of the Al valid target surface and B2 sword blade input level of the fourth 15 matching circuit does not fall below the U _bi n tripping voltage level, and when the contact is interrupted, disabling the second beacon circuit T2 prevents hit signaling.

The vibration detector C1, C2 (Fig. 4) is preferably configured with (1) an electromechanical converter, (2) a low cut filter, (3) a rectifier circuit, (4) an electronic switch, and (5) a diode bridge. are sequentially connected in sequence.

The distinction between a fencer-struck sword and a cut or stab is based on the recognition that the frequency of mechanical vibration by shaking your hand is significantly lower than that of a sword or sword blade on a single surface (blade contact or impact) mechanical harmonics in harmonics. Thus, if an electromechanical transducer (1) of the vibration detector C1, C2 and a diode bridge of the alternating voltage rectifier (5) are inserted a low frequency filter (2) with a defined frequency break point (2), the vibrations thus, we will not receive an invalid hit signal.

The electromechanical converter (1), sensing the acceleration or amplitude of the mechanical vibrations, supplies an electrical voltage to its output. The frequency of this electric ac voltage is approximately the same as that of mechanical vibrations on the blade B1, B2. The electromechanical converter (1) can operate on any basic principle: it can be magnetic, piezoelectric, Hall generator, etc.

The undercut filter (2) is connected to the output of the electromechanical converter (1). The breakpoint frequency is preferably in the range of 20-200 Hz.

The rectifier circuit (3) is connected to the output of the undercut filter (2), to the output of which the control input of the electronic switch (4) is connected.

The electronic switch (4) can be any electronic switching element having an input resistance of at least 1 to 10 Mohm, so that it does not load upstream circuits (e.g., Darlington-switched transistors or field-effect transistors). If the output circuit of the electronic switch (4) is polarity dependent, the diode bridge (5) may also be used. Thus, when connecting the vibration sensor C1, C2, the direction of the connection need not be taken into account.

The blocking of valid hits with swords is prevented by the circuit diagram of Figure 1 and Figure 2a. (Figure 2 shows the output signals.) For example, the right fencer strikes or presses the valid hit surface A1 of the left fencer with the swordsman B4 (snapshot time). The circuit between the terminals D1 and D2 of the voltage source closes via a resistor R1 or a current generator E1, a resistor R6 and a RIO, a valid hit surface A1, a sword basket B4, a vibration sensor C2 and / or a switch C4.

At the input of the sixth interface circuit 16, a voltage change is obtained such that it goes to another state of its output, the second timing circuit T2 prohibits displaying an invalid hit. However, resistor R6 has reduced the current in the circuit to such an extent that no voltage change is obtained at the input of the first interface circuit II, so that its output is tilted to another logic state: Thus, the conditions of the valid hit signal are not obtained at the input of the second logic gate circuit.

In case of a good defense, the prevention of a valid display on the B3 or B4 swords basket caused by the sword blade B2 or B1 is also shown in Figure 1 and Figure 2 / b, respectively. For example, the sword blade B2 of the right fencer first collides with the sword basket B3 of the left fencer (time y2). The circuit closes through terminals D1 and D2 of the power supply, resistor R4, R5 and RIO, sword basket B3, sword blade B2 and vibration detector C1, C2. The logic voltage level change at the output of the fifth and sixth interface circuits 13 and 16 triggers the third timing circuit T3 to output an output signal that determines whether the deflection of the sword blade B2 to the valid hit surface A1 was good or bad. colliding.

For example, the contact between y3 and y4 in FIG. 2 / b does not produce a valid hit because the blocking time of the T3 timing circuit is longer. However, if, due to a poor defense, the contact time of the sword blade B2 and the valid hit surface A1 is longer than the time of the timing circuit T3, then a valid hit signal is obtained at time y5 in FIG.

The puncture force sensor with a C3, C4 switch in the sword grip is shown in Figure 5.

The blade blade B2, B2 is electrically insulated with the insulator (15) and (6) from the sword basket B3, B4. (16) is provided with a securing screw (9) extending through the threaded end of the sword blade B1, B2 extending inside the fixed sleeve. The outer surface of the fixed sleeve (16) and the inner surface of the sliding sword grip (17) are joined to one another by a sliding surface (13) secured to the sliding sword grip (13). A spring (14) is provided between the fixed sleeve (16) and the anti-skid plate (13). A slit sleeve (8) is attached to the sliding sword grip (17), as well as a palm rest plate (10). The electrical switches C3, C4 (16) are mounted on a fixed socket.

Operation is as follows: the sliding sword handle (17) is moved longitudinally against the force of the spring (14). The switches C3, C4 are activated by the movement of the sliding sword handle (17). The magnitude of the spring force upon switching on the electric switches C3, C4 is set at 3-10 Newtons. The anti-skid plate (13) ensures that the electrical switches C3, C4 are engaged even when the hand is sliding on the sliding sword handle (17). The slit sleeve (8) is slit perpendicular to the longitudinal axis of the swords basket B3, B4 to ensure free movement of the sliding sword handle (17). Role of carcass (8): Even if the fencer improperly, but not irregularly, grasps the sword handle at carcass (8) or supports the vertical position of the sword at carcass (8) to control the spring force, 17) Sliding sword grip. The hand support plate (10) ensures that the sliding sword grip (17) cannot be accidentally or intentionally moved by the hand raised on the sword basket B3, B4.

Claims (5)

Claims 1. Apparatus for evaluating and displaying sword fencing hits, preferably for edge, degree, blade cutting and stabbing, with valid or invalid hits, having a right and left hit surface, right and left of swords, sword blades and sword handles has a sword on its side and is provided with a metal carpet, where the valid hit surface and the sword are connected to an evaluation display system, characterized in that in the sword basket (B3, B4) it is sensitive to the acceleration and frequency of mechanical vibrations (Cl, C2); (B3, B4) A vibration sensor (C1, C2) sensitive to the acceleration and frequency of mechanical vibrations and a puncture force sensor with a switch (C3, C4) in the sword grip. Vibration detector for evaluating and displaying hits during sword fencing, in particular for apparatus according to claim 1, having a series-connected electromechanical converter, a rectifier circuit and an electronic switch having an output or an output of a vibration sensor or an output of a diode bridge output of the oscillator. terminal, characterized in that a low cut filter (2) is connected between the electromechanical converter (1) and the rectifier circuit (3). Apparatus according to claim 1, characterized in that the puncture force sensor with the switch (C3, C4) is integrated in the sword handle by a socket (16) fixed on the sword blade (B1, B2) on which the switch (C3, C4) is secured, furthermore, a sliding sword grip (17) biased by a spring (14) on the fixed sleeve (16) is slidably arranged in the direction of the axis of the sword blade (B1, B2), wherein one end of the sliding sword grip (17) ), at the other end of which a carved sleeve (8) is fastened, while a hand-supporting plate (10) is attached to the carved sleeve (8). Apparatus according to Claim 1, characterized in that the left and right valid hit surfaces 10 (A1, A2) have inputs on the first and second interface circuits (II, 14) and on a resistor (R1, R8) or via a current generator (E1, E2) connected to one or the other corner (D1, D2) of the power supply source, and via 15 resistors (R2, R7) to one or the other corner (D2, Dl) connected, the left and right sword blade (B1, B2) is connected via a resistor (R5, R6) to the left and right basket 20 (B3, B4) and the vibration sensor integrated into the left and right swords (C1, C2) and one of the terminals (C3, C4) of the switch (C3, C4) integrated in the left and right sword grips, and the inputs of third and fourth interface circuits (12, 15); connected via a resistor (R3, R9) to a left or right power spun (Ul, U2), 30 the other terminal of the left and right vibration detector (C1, C2) is the left and right switch (C3, C4) it is connected to another terminal and to the inputs of the fifth and sixth interface circuits (13,16), and is connected via 35 resistors (R4, RIO) to one or the other corners (D1, D2) of the power supply, the first and the second the output of the interface circuit (II, 14) is a second and a first logic gate circuit (K2, 40, respectively) Connected to one of its inputs, the output of the third and fourth interface circuits (12, 15) is connected to one of the inputs of the third and fourth logic gate circuits (K3, K4), the output of the fifth and sixth interface circuits (13,16) connected via a second timing circuit (T1, T2) to the other input of the third and fourth logic gate circuits (K3, K4) and to a third input of a third timing circuit (T3) and to the second input of the first and second logic gate circuits (K1, K2) connected, the output of the third timing circuit (T3) is connected to the third input of the first and second logic gate circuits (K1, K2), the output of the first and second logic gate circuits (K1, K2) is connected to the first hit , or to the input of a second logic storage and drive circuit (S1, S2), or output from a hit indicator l connected to a lamp (L1, L2), the output of the third and fourth logic gate circuits (K3, K4) is connected to the input of the third and fourth logical storage and drive circuits (S3, S4) which overlap an invalid hit to the right or left fencer, respectively; their outputs are connected to a hit indicator lamp (L3, L4), and finally a carpet (M) which eliminates the puncture indication is connected to one of the terminals (D1, D2) of the power supply via an interposed resistor (R11, R12). Apparatus according to claim 4, characterized in that the resistance (R5 and R6) inserted between the sword blade (B1, B2) and the sword basket (B3, B4) is greater than that of the fifth and second adapter circuits (13, 14). ), and the resistance required to co-tilt the first and sixth adapters (II, 16) and less than the maximum value required to co-tilt the fifth and sixth adapters (13,16).