DE47747C - Electrical rangefinder based on resistance measurement - Google Patents

Description

IMPERIAL

PATENT OFFICE

CLASS -42: Instruments.

The. Invention consists in a novel apparatus for determining the distance or the Location of a distant object and is based on determining the angular movement of a about an axis moving body by measuring the electrical resistance of a Head of. between the initial and End positions of said body extends.

With the exception of FIG. 4, the accompanying drawings are electrical designs drawn without any particular scale and provide a schematic representation of the invention. In Fig. 1, a bridge (Wheatstone) is illustrated, in one link α an arch and an arm intersecting the same are arranged. In Fig. 2 a Wheatstone bridge is shown, which in two members (a and b) has arches and movable arms. In Fig. 3, a Wheats Tone bridge is illustrated, in which arcs are connected to each other abutting members, such as α c and bc, and movable arms that move over these arcs are connected to the battery. 4 shows the method observed when determining the angle. Fig. 5 shows an arrangement of the range finder in connection with a galvanometer and Fig. 6 with a telephone.

In Fig. Ι abcd denote the four members of an ordinary Wheatsone's bridge and g the cross member in which the galvanometer g ^{l is} inserted. A battery / is also connected to the bridge in the usual way .; In members c and d , the constant resistances c ¹ and d ¹ and in member b the variable resistance b ^{l are} also arranged as usual. A wire from battery f , however, is connected to the end of link c and also to pivot / swing arm i . The end of the arm i moves in electrical contact over a sheet h of conductive material, one end j of which is connected to the link a of the bridge. It can be seen that when the arm i is in the position shown in full lines in Fig. 1, the current must then flow through the entire arc h , and that when the arm is in the punctured position, the arc h is switched off and the current passes directly into the term α.

Assuming now that the arc h is made of such a material and of such dimensions that its electrical resistance to a current flowing through it is proportional to that between the contact end k of the arm i. and the junction j of the link α and the arc enclosed arc length. The resistance incorporated in the link α of the bridge is therefore related to the angle j I k , and if this resistance is known, the angle is also known.

Let it now be assumed that the galvanometer g ¹ and the variable resistance b ¹ are at a point remote from the movable arm i , from which the arm 'would be invisible or inaccessible. It is then clear that an observer standing at the galvanometer g ¹ and resistance b ^{1 can} , by examining the galvanometer and adjusting the resistance, find that any position of the arm i on the arc h

Determine the resistance offering equilibrium and thus find the angle of inclination of the said arm. Or the observer, after having set the resistance b ¹ to a certain value, by reading the galvanometer or with the aid of some other display device for sight or hearing, can determine whether the arm i is at a desired angle corresponding to the set resistance is set, and this display device can of course be at the point where the movable arm is, so that the observer located there can in this way know whether he has brought the arm to the previously determined point, or the device can be are at the remote location so that the observer who has the resistance b ¹ under him can know that the arm has been properly adjusted, or two display devices in the same circuit can give the observer signs in the above manner at the same time.

Various practical ways of using this apparatus are readily apparent to the expert. Thus, for example, the elevation to be given to a gun can be determined from a distance, with the axis of the gun corresponding to the arm i , or the latter can be the needle or the pointer of any actuated apparatus, such as the pointer of a manometer, in which case the angular movement of the pointer can be proportional to the pressure, so that the determination of the resistance at the distant point indicates the pressure, or that the adjustment of the resistance at a certain point results in the pointer activating an alarm device when a certain angle is assumed Action.

From Fig. 2 it can be seen that instead of the variable resistance b ¹ in the link b, an arc h ¹ and an oscillating arm i ¹ are arranged. The bow h ¹ is connected at one end j ¹ to link b and the swinging arm ¹ makes contact with the bow at one end k ¹ and is connected at its pivot I ¹ to link d . The arrangement and construction of the bow h ¹ and arm i ¹ are the same as those of the bow h and arm i and consequently when setting the arm i to a certain point on the bow h, the arm ζ ^{1 must be set} to the corresponding point on the bow h ¹ to determine the resistance of the arc lengths hh ¹ between point k and point h respectively. equalize between point k ¹ and point h ^1. Therefore, if the arm k is set at a certain angle, the observer can recognize this angle at the arm k ¹ by observing the position of the arm k ¹ and the galvanometer as above.

As will be noticed, however, the effect resulting from the movement of the arm i over the arch h is actually that of a lengthening or shortening or the inclusion of more or less resistance in the link α of the bridge ' ^{1 produced} an equal success in link b . The resistances or lengths of the links c and d remain unchanged.

In Fig. 3 an arrangement is shown which forms the basis for the special embodiment of the invention described in more detail below. The arch h is here at its ends j J with the limbs and the arch h ¹ in the same way at j ¹ J ¹ with the limbs bd . The battery wires connect to the pivot pins I l ^{l of} the arms ii ¹ as above. If the arm i is now moved from its central position on the arch towards j , less resistance is created in the limb α and more resistance in the limb c , while the reverse takes place when the arm is moved in the opposite direction. The same effect is produced by the displacement of the arm i ¹ , and accordingly the resistance offered by all four members of the bridge (instead of that offered by only two members) can be influenced, and differential results can be obtained, as from the following Description of a range finder, for example one for guns, becomes clearer.

Let it be in FIG. 4 T the position of the object whose distance from point A is to be determined. AB denotes some short baseline. Now draw the line AC at a right angle to BT, the line EA parallel to BT and extend AT to D.

Trigonometric is now
AC = AT sm ATC AT = AC cosec ^ l TC AC = AB sin ABC, and consequently
AT = AB sin ABC cosec ATC.

AB as the measured baseline is known and the angle ABC at the observation point can easily be determined, so that one only needs to find the angle ATC. But ATC = DAE, and DAE is measured by the arc G H. Arc G H is = arc j H - arc j G and arc _; ' H = arc j ¹ k. It is therefore arc G H = arc j ¹ k - arc j G.

In Fig. 5 the designs of Figs. 3 and 4 are combined and ii ¹ are, as before, the swinging arms, which the arches hh ¹ through.

cut, and the connections abcd of the bridge are also present. The arms i and i ¹ represent telescopes which are both aimed at the same object T. Since the arcs j G and j ¹ k are not the same, they form unequal resistances in the bridge; the latter is made equal, however, when the telescope i is brought in the direction of the line EA . The extent of this movement of the telescope, however, corresponds to the arc G H, and its length can be read from the arc h itself.

It also turns out that the distance BT can be found by means of a simple trigonometric calculation. Since the base line AB and the lines AT and BT are known, the position of the object T can easily be determined so that the apparatus can be used in the manner described not only to determine the distance but also to determine the position of an object .

The procedure observed when determining the distance AT. is very easy. The observers at the respectively. Telescopes i and z ¹ aim the latter at the object. The observer at i notes the angle j AG or the arc length j G. Then he moves the telescope i until the galvanometer g ¹ , which is set up close enough to hand, shows no deviation, and notes the angle j AH or the arc length j H. The difference between the arc j G and j H is equal to the arc GH, from which the angle A TB results, as previously described.

The last-described arrangement (FIG. 5) assumes the determination of the angle A TB and consequently the distance AT by the observer on the arm i or, in other words, on the base line. The arrangement of the apparatus according to which an observer can immediately read the distance AT from a suitable scale at a point distant from that base line will now be described.

The links α b of the bridge are connected in Fig. 6 to the opposite ends of the rod m η made of conductive material and the links cd to the ends of an identical and parallel rod op. On the rods ο ρ and m η there is an adjustable slide rr ¹ , which has a middle part s made of insulating material, so that the current coming, for example, from the rod m η cannot flow through the slide rr ^l away to the rod op , but through the wire g continues to the telephone g " , which here takes the place of the galvanometer g ^{1 of} the earlier figures. In the battery wire at t an automatic circuit breaker of any shape is switched on, which has the purpose of producing an audible tone in the telephone g" .

It is now assumed that the telescopes i and i ¹ are directed towards the distant object T as before and the slide rr ¹ is located at the center point 1 of the parallel rods m η and op. As can be seen, the resistances in the bridge are not the same and the sound of the device when t is in the telephone g "into place. It has been already explained in Fig. 5 as i by movement of the telescope, the resistors can be compensated to the point H, and if this is shown in in Fig. 6 If an arrangement were to be made, the telephone would not emit any more tones as a result. Assume, however, that the telescope i is not moved after it has been adjusted to the object T or, in other words, that the observers at the two telescopes i and i ¹ simply set your instruments in line with T. Apparently the distance on the bridge from r to G (link a) is less than the distance from r to k (link b), namely by the arc length G H. I In the same way, the distance on the bridge by the arc length G H is greater from r ¹ to G (link c) than the distance from r ¹ to k (link d).

Now make the resistance for a unit length of the rods mn ο ρ equal to the resistance per unit length of the arch hh ¹ or bring it into a certain ratio with the latter resistance and measure a distance r ³ on the rod m η and a distance on the rod op r ¹ 3, which distances are such that the resistance resulting therefrom is equal to that of the arc G H. It is clear that, when the end r of the slide in the position 2 on the rod m η is shifted, extended the term α and the member will be shortened b, namely by the distance r 2, which has a half of the resistor of the arc G H presents a corresponding resistance, and that when the end r ^{1 of} the slide is moved to position 2 on the rod op , the link c will be shortened and the link d will be lengthened by the distance r ¹ 2, which also has a resistance equal to half the arc G H; since both ends of the slide move simultaneously, it follows that when the ends are adjusted in position 2, the bridge is balanced with regard to the resistances and the telephone stops ringing.

In order to use this in practice, one provides the rods m η ο ρ with a suitable graduation from r to η and from r ¹ to p. After the two telescopes i and i ^{1 are} pointed at the object, the person in question listens

distant observer on the telephone g " and moves the slide rr ¹ over the rods m η and op until the tone stops. The graduation on the rods then gives an indication of the arc length G H by means of a corresponding note.

To demonstrate the practical utility of the apparatus, the following examples are given. The telescopes ii ¹ , suitably attached to their bows hh ^1, are handed over to two observers, who use them to advance to the rifle line or another advanced post and, after having chosen a base line of a certain length, adjust their instruments to the front of the enemy works or columns . The observers indicate that this is accomplished by flags or electrical signals. One can assume that the observer on the telephone g "is stationed near a battery of guns which is about to open fire. As soon as the signal has been given that the telescopes are adjusted, the observer on the telephone turns the slide rr ¹ , so that the sound in the instrument ceases, and then determines the distance after division on the rods m η ο ρ, whereupon the guns are directed accordingly.

The invention is, however, particularly applicable to pneumatic (wind or gas) guns which are used to throw grenades charged with strong explosives. A gun of this type is set up at the bow of a ship with a certain elevation, for example 18 °, and the throwing range of the projectiles is regulated by changing the wind supply to the gun. It is therefore of the utmost importance to determine the range of the target with the greatest possible accuracy. The two telescopes ii 'are set up on opposite sides of the ship's upper deck and the latter's beam length is assumed, for example, as a known baseline, while the telephone g " can conveniently be placed under the gun's wind control valve. The observers on the upper deck set up their telescopes the object to be inscribed and the observer on the telephone determines the distance in the manner already described and adjusts the valves according to this determination.

Claims (3)

Patent claims: ι. A device for determining distance and the position of an object, which is based on the measurement or balancing of the electrical resistance is based on the one between the starting and ending angular positions of the opposite ends of a baseline from on the removed object. straightened telescopes enclosed ladder is offered. 2. A device for determining the distance and location of an object, which which includes rotatable radial telescopes attached to opposite ends of a Baseline are arranged and stretched over sheets of conductive material that are a known Possess measures of electrical resistance per unit length, move, in connection with a source of electricity, circuit connections and display or signaling devices. 3. A device for determining the distance, distance and position of an object, characterized by the connection of the four links abcd of a Wheatstone bridge, the two arches hh ^{1 connected} between the links α c and bd , the two rotatably deflected radial arms or telescopes ii ^l, the free ends to travel over said arc, and thus preserve the electrical contact upright, a Elektricitätsquelle, one pole of which is connected to one of said arms and their 'on the other pole with the other arm, one between said Elektricitätsquelle and a circuit breaker connected to one of the said arms, two rods of conductive material connected between the members α b and cd , contact pieces adjustable on each of these rods, a line of a telephone connected with their ends to these contact pieces in this line.