DE2049926A1 - Automatic point counting system for shooting ranges - Google Patents

Description

"Automatic point counting system for shooting ranges" summary of the Revelation An automatic point counting system for shooting ranges based on the acoustic Shock wave is caused by a projectile such as a bullet or the like when it flies through a target area.

The system comprises several vertically extending acoustic energy directors, which lie next to the scope of the target, using multiple acoustic transducers connected to one end or to the ends of the target area, but no longer than one at each end to produce an electrical signal when the shock wave of the floor is transmitted by the corresponding control systems. Four Electrical signals are emitted in an electronic circuit entered to set the point of each hit on the target area, namely in rectangular coordinates, with a corresponding specification being made.

Background of the Invention Field of the Invention The invention relates to on a signaling device for point counting systems at shooting ranges and relates in particular to means for delivering an electrical signal in correspondence to a hit on the target, which gives information about the results of the Schütz.en become available at a distant point.

Description of the Prior Art Learning the operation and shooting a firearm, e.g.

of a rifle, is not just for military and police personnel, but also important for amateur shooters. Usually a shooting range is used, on which targets are movably arranged for each shooter. The guns and Shooting techniques have changed as technology has advanced, but the Target remains the same; if modern weapons are also available, they are old counting methods still widespread, but still ineffective.

One known technique uses target counters that are slow, inaccurate and are unreliable. Because of the time it takes to take each shot count, multiple shots are counted instead of individual rounds.

In addition, there is a quick succession of shots Counting round after round impossible. System unreliability can persist be made worse by a dishonest or lazy team. Since between shot and counting a distance must be both human labor as well as reducing training effectiveness and / or enjoyment. The lack of one Immediate feedback to both the shooter and the observer, if the volleys are fired limit the entire procedure.

If there are also automatic target counters, where the impact vibration when hitting a silhouette is measured, which is known reliability is particularly required. High-speed small caliber guns are not detected by the silhouette sensors, because the amplitude when vibrating after the ball impact is too low.

If you increase the sensitivity of the vibration sensors, then it increases only the risk of incorrect counting due to the effects of wind and the like. Electrical contact methods are also known, although these systems are pretty sensitive, but suffer from inaccuracy and vulnerability.

The following patents are believed to be typical of the prior art stated: 2,916,289 R. Zito 2,925,582 J.I Matteiu.a.

2,934,546 T. Mongello 2,973,964R. Zito 3,022,076 R. Zito 3, 217, 290 U. C. I. Siliman 3,392,979 M G. Wilsko 3, 479, 032 J.A.I Ohlund et al.

Summary Briefly, the invention aims at an improved, automatic point counting device for shooting ranges with a plurality of elongated ones Akustikenergieleiteinrichtungen from, each at right angles to each other around the circumference a target are arranged so that they are substantially parallel to their Edges run when the target has a square configuration and a forms common surface with the sensors. Four acoustic transducers are with the Acoustic energy guiding devices connected at their ends and selectively placed near the ends or corners of the target. The transducers are working in pairs and respond to the acoustic shock waves that hit the guiding devices are transmitted after the airborne acoustic shock wave emitted when a supersonic projectile flies through the target, with electrical signals which are connected to electronic circuit devices, showing the time relation between respective pairs of electrical signals from the Specify transducers and indicate the point where the hit was located, namely in the Distance from a selected point, such as the center of a target with rectangular coordinates.

Brief Description of the Drawings Figure 1 is a diagram, in part in block diagram form illustrating the preferred embodiment of the invention, Fig. 2 is a cross-sectional view of one embodiment of an acoustic energy conductor; as used by the invention, Figure 3 is a partial side elevation view of the embodiment of the acoustic energy conductor according to Fig. 2, Fig. 4 is a cross-sectional view a second embodiment of an acoustic energy conductor such as that of the invention is used, Fig. 5 is a cross-sectional view of yet another embodiment of an acoustic energy conductor used in the invention, and FIG. 6 is Fig. 3 is a diagram, partly in block diagram form, showing a second embodiment of the invention.

Description of the Preferred Embodiments The invention is based on the principle, whose projectile or ball with supersonic speed a creates acoustic shock wave extending away from the trajectory of the ball. As the ball moves, the shock wave appears as an expanding cone. This high energy produced by the ballistic shock wave front and referred to as the "N" wave, can be detected by acoustic transducers which include means such as piezoelectric devices so work that an electrical signal in correspondence to the impact of an acoustic Shock wave is emitted.

In the preferred embodiment of the invention, Fig. 1, a target 10 with a square shape in combination with first and second Acoustic energy guiding devices, in this embodiment a first and a second acoustic energy conductor 12 and 14 which have linear dimensions that are substantially equal to the width or length of Target 10 and are arranged next to the circumference, essentially parallel to the edges of the face of the target. The center point 16 of the target 10 defines the intersection of the X and Y axes of a right-angled coordinate system. The center point 18 of the conductor 12 coincides with the Y-axis, while the center point 20 of the conductor 14 coincides with the X-axis. A first and a second piezoelectric Transductor 22 and 24 are arranged at the ends of the acoustic conductor 12 while third and fourth piezoelectric transducers 26 and 28, respectively, at the ends of the acoustic conductor 14 are arranged.

Before describing the operation of the configuration according to the above Description is first referred to FIGS. 4 to 5, the three embodiments the acoustic power conductors 12 and 14 represent. Figures 2 and 3 disclose a first one Embodiment of the acoustic conductor 12, it being understood that the identical Explanation also applies to acoustic conductor 14. This first embodiment exists from a solid metal rod 30, for example made of stainless steel, aluminum or the like and is preferably centrally located in a plane through the target 10 is defined. This is shown in FIG. Around the metal bar 30 to protect against bullets or projectiles that are fired at the target 10 surrounds a pipe part 32 with a protective shield or metal deflector 33 partially the rod 30, while the part next to the target 10 remains free. The metal rod 30 is also removable in the pipe part 32 by means of acoustic insulating and damping material 34 held, which preferably consists of material available under the trade name "Velero" will be produced. This material is comfortable for a variety of uses known, but not as an acoustic damper.

This material is also detailed in the U.S. patent 2,717,437.

A second embodiment of a suitable acoustic conductor has simple a thin, flat metal strip 36, which in the plane of the target 10 is arranged in such a way that, for example, a surface with its larger Part with the edge of the target 10 is in a line, or turned towards her is. It should also be noted that the metal strip 36 is so mounted should that it lies in a suitable protective barrier in a manner similar to that of the embodiment of FIGS. 2 and 3 shown. If desired, the thin strip can 36 according to FIG. 4 in favor of a similarly arranged wire with a small diameter can be omitted. Another embodiment of acoustic guidance devices, suitable for use with the invention is shown in FIG a hollow tube 38 filled with acoustic energy conductive fluid 40.

The embodiments of the ladder according to FIGS. 2 and 4 are based on the fact that the speed of sound in metal is about 15 times greater than in the air. For example, the speed of sound in air is approximate 1130 feet per second, while the speed of sound in stainless steel is in on the order of 16.660 feet per second. The embodiment shown in FIG is based on the other hand on the fact that the selected liquid 40 also conducts acoustic energy at a relatively higher speed than air. Be like that the respective transducers hit by secondary shock waves of an acoustic type that run in the acoustic conductors before the primary acoustic shock wave arrives there.

In the preferred embodiment of the invention according to FIG. 1 the reference numeral 42 denotes a hit of a bullet or a projectile on target 10. The air primary acoustic shock wave "N" appears as an expanding one Circle extending radially outward from hit 42 in the plane of the target extends. In the exemplary embodiment shown, the wavefront first hits the Longitudinal acoustic ladder 14 at a distance H above the X axis. Faster moving secondary shock waves are generated in the conductor 14, the opposite directions move along the conductor and initially on the acoustic transducer 28 and then hit the acoustic transducer 26.

The difference between the times that the respective secondary Shock waves need to hit the transducers 28 and 26 is a measure of the distance of the hit above the X axis. If the corresponding secondary Shock waves hit the acoustic transducer 26 first, the hit is known to be lie below the X-axis. The N wavefront hits in a similar manner the horizontally aligned acoustic conductors 12 at a distance L from the Y-axis and thereby causes secondary acoustic shock waves which then become the two trans; move ductors 22 and 24. The time difference between the impact of the secondary shock waves on the transducers 22 and 24 resulting from the impingement of the N wave on the Rod 12 is a measured variable for the distance of the hit from the Y-axis. If you determine which acoustic transducer will be activated first, it will be accordingly determined which side of the Y-axis hit 42 was on.

The embodiment according to FIG. 1 additionally discloses an electronic one Circuitry associated with transducers 22, 24, 26 and 28, around the point of the hit in X-Y coordinates and the error distance both horizontally as well as vertically from the center point 16 of the target part 10, with further it is specified whether the hit 42 is above, below, left or right of the center point lay. This is effected by a circuit 44 consisting of a subordinate Circuit 46 for the Y-axis and an identical device 48 for the X-axis consists. The circuit for the Y-axis 46 is with the acoustic transducers 26 and 28 connected, which are below and above the center point 16, namely by means of corresponding signal preamplifiers 50 and 52. The signal preamplifier 50, which for the lower preamp applies is with one first level detector circuit 54 connected, which can for example be a Schmitt's circuit, while the output of the preamplifier 52 for the upper preamplifier into a second level detector circuit 56 is fed in. A level detector, such as a Schmitt circuit, is well known to those skilled in the art and operates to provide a constant level signal output is given when the input has a certain input amplitude level or a threshold exceeds, but no output is given for a signal whose amplitude is below a certain threshold. A level detector circuit 54 or 56 each has its outputs connected to a control circuit 58, which thereby is activated that in each case a level detector circuit 54 or 56 initially one Receives signal from respective transducers 26 and 28, and is deactivated, when the other level detector circuit connects its output to it. The control circuit 58 then acts as a "start-stop" circuit giving an indication and an output, whose rhythm width is a function of the difference in arrival times for the corresponding represents secondary acoustic impingement waves at transducers 26 and 28. The control circuit 58 additionally includes output circuit lines 60 and 62, connected to indicator lights 64 and 66 to indicate which of the outputs came first in time, whereby an indication is made whether the hit 42 above or was down with respect to the center point 16 of the target.

A crystal controlled timer or oscillator 68 does one Reference frequency with a corresponding output signal that is fed into an input of the clock grid circuit 70, which has a match grid, the other input of which is connected to the output of the control circuit device 58. As long as the grid signal from the control circuit 58 appears on the clock grid 70 will the reference frequency from the crystal controlled timing device 68 into a binary Opposite circuit 72 input which creates a signal, the Total number full cycles that occur in this interval is an accurate measure of the Distance H is. The output of the binary counter 72 is shown in a suitable display device 74 entered which is a visual indication of the numerical value of the distance H above or below the target center point. By changing the crystal frequency so chooses that the ratio of the speed of sound in the acoustic conductors to the crystal frequency is 1/5 or 1/50, etc., the numerical value on the indicator read directly in 0.1 inches or 0.01 inches, etc., without having to use a conversion unit or calculations are required. A manual stop button 76 is at a reference point attached to control circuit device 58 as well as binary Counter 72 and on the display device 74 to the circuit 46 for the next to prepare a firing volley. However, it should be understood that if an automatic Re-adjustment of the unit 46 is desired by simply changing the control circuitry 58 can take place, whereby a continuous indication for continuous rapid fire is created.

The distance H from the X axis can be represented by the following equation become: II = (T26 - T28) V / 2 where T26 T T28 is the difference in arrival times for the respective secondary shock waves at the transducers 26 and 28, V is the Speed of sound in the elongated acoustic conductors 14. It should be noted that the length of the rod does not appear in the equation, accordingly has an extension or contraction of the rod due to temperature changes has no effect on the accuracy, but what is important is the mechanical arrangement of the sound conductor 14 to the edge of the target 10, as the parallelism is important, as is the Reference frequency of the crystal controlled timepiece 68. If stainless steel is provided for the elongated sound conductor 14, the temperature-dependent moves Speed change at 100 C to 500 C in negligible orders of magnitude and the distance H. is only a function of the accuracy of the timing circuit.

Looking at the X-axis sub-switch unit 48, it can be said will be made to be similar to the Y subassembly 46 in so far as the circuitry is concerned are. It receives electrical signals from transducers 22 and 24 via the right and left signal preamplifiers 78 and 80. Timepiece 68 is also connected to the X-axis switch unit 48, the also has level detector circuits, furthermore a control circuit, such as it was described in the X-axis subassembly 46. The sub-unit 48 comprises in addition, a left and a right control lamp 82 and 84, which indicates which the acoustic transducers 22 and 24 only react to secondary sound shock waves, moving in the elongated conductor 12. A clock grid circuit and a binary, not shown counters are also in this circuit, the latter is connected to a visual indicator 86 which is a numerical indication of the distance of impact L creates from the center of the target. It should be pointed out that the visual indicators 74 and 86, respectively, can be of any configuration.

"Nixietl tubes can be used if so desired in order to obtain a digital, decimal indication of the X and Y coordinates of the hit 42. It should be noted, however, that the binary counter outputs of the Y and X subunits 46 and 48 into a corresponding DC voltage magnitude by means of an integration circuit Can be converted to a cathode ray tube display of X-Y coordinates as a single spot that is appropriately deflected from the center of the tube will. It is also possible to have this information printed out on paper or in Cards for computer calculations is punched.

In one aiming system, stainless steel poles were five feet length used as acoustic conductor 12 and 14, what one piezoelectric sensors with 1/4 Inch diameter and 1/2 inch length attached. A binary counter such as B. the Counter 72, which was operated by a crystal-controlled normal clock 68, whose Reference frequency was close to 1 Mflz, measured the time difference for the impact the acoustic shock wave on the two rods. Twenty shots from a 22 Magnum rifles were recorded at points over a 5 'square target portion. The automatic counting system according to FIG. 1 ranked within each scoring 0.050 inches in the area of actual hit on the paper target a. As noted above, this can further reduce this relatively small error be that one increases the reference frequency of the clock 68 and the reference frequency adapts to the speed of sound in the rod (ratio 1/5), still can improve the mechanical adaptation between the target and the metal bars.

A second embodiment of the invention is disclosed in FIG and differs from the embodiment according to FIG. 1 by the use of two elongated conductors 88 and 90 as the first acoustic guide devices and through two elongated conductors 92 and 94 as secondary acoustic energy directors, wherein transducers 94, 96, 98 and 100, respectively, are mounted at the ends thereof. The ladder 88 and 90 along with the corresponding transducers 94 and 96 are used first Pair used to determine the distance L along the X-axis while the ladder 92 and 94 together with the corresponding transducers 98 and 100 as a second pair act to determine the distance H to the Y axis.

Note that the first pair of transducers 94 and 96 is arranged along the upper edge of the target 10, while the second pair of transducers 98 and 100 along the right edge of the target 10 is arranged.

In operation, the first blast of air "N" expands from hit 42 the end to the outside and first hits the sound conductor 88, whereby a secondary sound wave is caused to energize the transducer 94 before the primary wavefront him can reach through the air. The electrical signal generated in this way is connected to the left Preamplifier 80 connected. A certain time it meets the primary, expanding Sound wave hits the ladder rod 90 and activates the transducer 96 so that a Signal is input to the "right" preamplifier 78, being the X-axis subunit 48 is caused to operate exactly as before with respect to the circuitry of FIG. The quantity V in the equation H = (T96 - T94) V / 2 is the speed of the shock wave in the air. The times of the secondary shock wave in rods 88 and 90 have of little importance, because they are the same and very much in the magnitude of the magnitudes much less than the time in the air. Similarly, it causes expanding Shock wave, which radiates from the intersection 42 of the ball with the target 10, a secondary shock wave which initially causes the acoustic conductor 94 over time causing a signal to be emitted from acoustic transducer 100, which is routed to the "upper" preamplifier 52, while some time later the primary wave hits the lower sound conductor 92 causing a signal from the transducer 98, which is then sent to the lower preamplifier 50. The signals which are initially emitted by the transducer 100 and then by the transducer 98, cause the Y-axis sub-unit 46, an indication of the distance and direction of the hit 42 to be delivered on the Y-axis of the target 10.

In both embodiments of the invention according to FIGS. 1 and 6 are Pairs of acoustic transducers for both the X and Y coordinate axes used in combination first with a single conductor and then with two conductors, to indicate the location of the hit 42 by noting which the transducers of each pair is activated first and by changing the distance thereby ascertaining that you can see the elapsed time between the Detects activation of one and the other transductor of the pair.

Another feature of the automatic point counting device according to the Disclosure of the invention is the possible short readjustment time and accordingly the quick evaluations that can be achieved. For example, by using a Four-foot square target is used, the acoustic disturbances are caused by the Hit by the sound acoustic ladder or poles in five to ten milliseconds to run. The acoustic oscillation of the conductors with self-damping, as shown and described with respect to Figure 2, will take approximately five milliseconds.

So the acoustic transducers are capable of firing shots or volleys register ten to fifteen milliseconds apart. By getting the circuits according to Fig. 1 and 6 changes so that an automatic readjustment takes place and thereby, that an additional data storage device is used, such as an electronic, digital movement register, 50 to 100 laps per second can be evaluated. A reliable estimate for fast evaluation capacity is then in the order of magnitude of 3000 rounds per minute.

The invention has been described in a number of details, while the method of using the automatic point scoring system is based on individual Will be based on needs. For example, a system that is designed to Evaluate competition shooting, in the data processing and counting of one Plant that is intended for basic training with silhouette goals be used. Similarly, it becomes a target for rapid-fire aircraft and cockpit layout may be dissimilar to a system used for gun testing and ammunition evaluation is used. Something must be said clearly1 namely that the fundamental Target surfaces and evaluation circuits as disclosed here when they also applicable to many areas, must be modified in order to everyone To meet consumer demand.

In addition, a fully automatic training shooting range is in prospect taken. The trainee starts with the system at a starting point of the distance and its actions, such as work speed, reaction time, score, etc. are recorded as the distance to the exit is increased. the For example, buttons along the shooting range activate an impact mechanism at the desired removal point. The targets could be along a jungle-like one Path and consist of a mechanism that consists in raise and lower a silhouette and two stationary sound guide rods, where one is vertical and one is horizontal and where the vertical rod is used as one Tree or post is camouflaged while the horizontal pole is below ground level is arranged. On top of that, the sound conductor is adjusted in such a way that it conforms to the silhouette in the upright position. An instructor could be a big one in a course Supervise number of trained people, while at the same time a certain individual Attention can be paid to each individual. The trainee would be Move along the path and shoot at targets as they appear. With everyone The goal is the reaction time, the number of shots> the "hit / miss" arrangement every shot is recorded and sent to a control tower. If necessary a fluorescent screen arrangement can return the hit information to the shooter, before moving to the next destination. By moving numbered lights could these are each used with red, yellow or green colors for illustration of missed, non-life-threatening and fatal shots. The life-threatening one If necessary, the triggering of the holding mechanism or the Cause the target to fall over.

In addition, rapid fire shots could be measured in real time will and the X-Y information is stored in a register will. The maximum number of shots would depend on the corresponding storage capacity depend. Missed shots would be recorded as top or bottom left or right will. The stored information would be read automatically and given to the operator to provide. The method of storing and reporting the hit information depends on the training situation. Three of the most common viewing methods are the paper printer, the cathode ray tube and the X-Y card memory. The X-Y coordinate data for each shot can be on a tape for manual evaluation or in the future for computer input. The printer is the cheapest storage medium but also the least informative for real time situations. The fastest Display is a memory / cathode ray system where the X-Y information is the beam deflects and where the hit is saved as a line through intensity modulation of the beam will. However, unless a photograph is taken of the surface, it is not permanent storage available. A second printer is used with the cathode ray tube needed. An X-Y interpreter is slower than a cathode ray tube, causes however, the same graphic representation and results in a permanent record. The evaluator can indicate the number of shots and thus a complete representation of the process give. The silhouette can be preprinted on graphic paper and for savings can establish a series of goals on a single sheet of evaluation paper to be recorded. At the end of the course, the trained person would immediately know how well he worked and he could discuss the mistakes with the instructor. template the course of the shot can indicate incorrect use of the weapon, which can be easily corrected could be. Constant bullets in one direction would result in the memory panels appear, because shots outside the target area are scored and the wrong direction is displayed.

What has been described here is accordingly a passive system, the is easy to use and has a linear X-Y readout creates, not only for the arrangement of the hit, but also for the distance from the center of the target without complicated circuitry. Selective reading creates a great deal of flexibility in the way the data is remotely located at one lying station can be represented.

Claims (18)

Patent claims: 1. An automatic point counting system for shooting ranges based on the airborne primary acoustic shock wave from a supersonic projectile reacts, about the hit of the projectile and its spatial arrangement on a target which comprises in combination: first (12) and second (14) elongated acoustic energy transmissions transmission means running along the perimeter of said target (10) in a substantially mutual perpendicular relationship along a first and second perpendicular Coordinate system with X and Y axes are arranged and essentially in one Plane, which is defined by the said goal (10), around which to the outside contacting expanding primary shock wave (N) of said projectile, wherein said transmission devices have a relatively higher speed secondary acoustic shock wave transmitted therein, starting from the contact point with said primary shock wave; a pair of acoustic transducers (22, 24, 26, 28), which at a certain distance from the respective first (12) and second (14) acoustic energy transmission part are mounted in a predetermined relationship with the stated goal, with each on the called higher speed of the secondary wave is responding to an electric Output signal after it hits, said electrical Output signal of each of the said transductor pairs has a time ratio that Function of the difference in arrival times of the named primary and secondary Waves at the respective acoustic transducers; first electrical circuit devices (7E 30, 4es) connected to a pair of acoustic transducers (22, 24) and respond to the said electrical signals that come from it be emitted in order to create a first signal which is a measure of said difference the arrival times of the said primary and secondary waves each to one Pair of sound transducers is; second electrical circuit means (50, 52, 46) connected to the other pair of sound transducers (26, 28), the react to the signals mentioned, which are emitted by it and a second Generate electrical output signal that is a measure of the said difference of Arrival times of the named primary and secondary waves along the genami s second coordinate axis is; and display means (86, 74) associated with the aforesaid first and second electrical circuit means are connected to a Indication of said hit on said target along a first and second To obtain coordinate axis. 2. The invention of claim 1, wherein said elongated acoustic energy transfer means (12, 14) have linear metal conductor devices (30), the center points (18 and 20) that substantially coincide with the center of the target. 3. The invention according to claim 2 and additionally projectile barrier devices (32, 33) which partially surround the said metallic guide devices (30), extending substantially in one axis for delivering projectiles thereto prevent hitting the said metal conductors and being an unobstructed Opening is turned towards the target. 4. The invention according to claim 3 and additionally acoustic insulation and damping material (34) between the metallic baffles (30) and said bullet barrier means (32,33). 5. The invention of claim 4, wherein said acoustic isolation the damping material (34) comprises "Velcro". 6. The invention of claim 4, wherein said metallic conductor (30) a circular cross-sectional shape according to FIGS. 2 and 5 with a certain diameter Has. 7. The invention of claim 4, wherein said metal conductor (30) has a rectangular cross-sectional shape, (36) FIG. 4. 8. The invention of claim 1, wherein said first and second elongated acoustic energy transmission devices (12, 14) tube parts (38), Fig. 5, of a predetermined length, which are made with liquids conductive to acoustic energy (40) are filled, the centers (18, 20) of said tubular Parts essentially coincide with the center of the said target. 9. The invention of claim 1, wherein said first and second elongated acoustic energy transmission means each a first (92, 88) and a second (94, 90) acoustic conductor component, each pair of acoustic transducers (98, 100, 94, 96) are mounted at the ends. 10. The invention of claim 1, wherein the first and second elongate Acoustic energy transmission devices each have first and second pairs of acoustic Having guide means (92, 94, 88, 90) and wherein a pair of acoustic transducers (98, 100, 94, 96) are each mounted on it in such a way that each acoustic transducer is mounted at one end of a corresponding line part. 11. The invention of claim 10, wherein each acoustic transducer (98, 100, 94, 96) arranged on the same end of a corresponding pair of conductor parts is. 12. The invention of claim 1, wherein said target (10) is a is of predetermined length and width and wherein said first (12) and second (14) elongated acoustic energy transfer means, first and second metal rod members (30), the lengths of which extend essentially as far as the called the length and latitude of the target and being arranged to be in the run substantially parallel to the target and wherein the center point (18, 20) is substantially coincides with the center (16) of said target (10). 13. The invention of claim 12, wherein said first (18, 80, 48) and second (50, 52, 46) electrical circuit devices each comprise: first (54) and second (56) level detection circuits each are connected to a pair of acoustic transducers (28, 26) which provide a control signal emit when an electrical signal occurs from the corresponding transducers that are associated with it; a control circuit (58) associated with said first and second level detection circuit is connected and on responds to the control signals emitted thereby, with a first output signal which indicates which control signal came first and a second Signal which is the time difference between the occurrence of said control signals indicates; a reference frequency signal source (68) a match screening circuit (70), the one with the aforementioned output signal of the control circuit and the aforementioned Reference frequency signal source is connected to a pulse of said reference frequency signals whose pulse width is proportional to the difference in arrival times said primary and secondary sound wave to said pair of acoustic Transducers, and circuit means (72) interposed between said conformance grid (70) and said indicator (74, 86) is connected to emit a control signal, which gives a visual indication of the difference on the indicated display device, which exists between the arrival times and accordingly an indication of the Position of said hit (42) with respect to the center (16) of said hit Target (10) delivered. 14. The invention of claim 13 and additionally a signal amplifier device (50, 52; 78, 80) between said pair of acoustic transducers and the said first (54) and second (56) flip-flop circuits. 15. The invention of claim 13, wherein said switching device (72) between said match grid (70) and said indicator (74, 86) has a counting circuit. 16. The invention of claim 13 and additionally manual adjustment devices (76) on said control circuit (58) and said indicators (74, 86) which are arranged in such a way that said control circuit after the occurrence of both Control signals can be reset. 17. The invention of claim 13, wherein said reference frequency (68) a predetermined ratio to the speed of sound in the said acoustic energy ex E rt ragun gs facilities. 18. The invention of claim 1, wherein said display device (74, 86) has first and second decimal numeric indicators to indicate the location said hit (42) along said first and second coordinate axes regarding of the center point (16) of said target (10). Blank page