RU106381U1 - DEVICE FOR MEASURING THE SPEED OF A THROWBAR FROM LEAD AND ITS ALLOYS - Google Patents

Abstract

 1. A device for measuring the speed of a projectile made of lead and its alloys, mainly pneumatic small arms, including a measuring unit with two inductors, a supporting element in the form of a tube for flying a missile projectile, on which two inductors are spaced apart at a basic distance along the path flight, pulse shapers, time interval meter and calculator, characterized in that the device is made in the form of a single unit located in the housing, and is equipped with co-frequency generator - highly stable in both frequency and amplitude, indicating unit and power supply, the measurement unit is made in the form of two parallel-connected oscillatory circuits with a natural resonance frequency close to the frequency of the generator signal supplied to the circuit, each oscillatory circuit contains a coil connected in series inductance and capacitor, and is connected in parallel to the generator and to two pulse shapers of the span of the projectile, while the coil is a means of recording that the projectile, and each pulse generator is in the form of the amplitude detector. ! 2. The device according to claim 1, characterized in that it has a fastener made in the form of a thread on the end of the tube for projectile projectile passage, with the possibility of attaching to it an adapter sleeve for fastening the device to the barrel of an air gun. ! 3. The device according to claim 1, characterized in that the power supply is made autonomous, built-in inside the housing or external. ! 4. The device according to claim 1, characterized in that the display unit is made in the form of light with

Description

The utility model relates to measuring equipment, and more specifically, to a device for measuring the speed of flight of a projectile of lead and its alloys, operating on the principle of interaction of the magnetic field of eddy currents induced by the high-frequency (HF) field of the coil in the projectile, with a resonant circuit, and can be used for measuring the speed of a projectile of pneumatic small arms.

A known resonant metal detector comprising a sinusoidal voltage generator, an amplitude detector, a low-pass filter, a pulse amplifier and an actuator connected in series, a sinusoidal voltage generator assembled on an operational amplifier, the negative feedback circuit of which includes a parallel oscillatory circuit and a first resistor connected in series , and the positive feedback circuit consists of a second resistor and a potentiometer connected in series, as well as an amplitude limiter connected in parallel, moreover, the inverting input of the operational amplifier is connected to the connection point of the parallel oscillatory circuit and the first resistor, the non-inverting input of the operational amplifier is connected to the middle output of the potentiometer, the output of the operational amplifier is connected to the connection point of the parallel oscillating circuit and the second resistor, the amplitude limiter connected to the connection point of the second resistor and potentiometer [1].

A disadvantage of the known device is that it uses a parallel LC circuit operating in resonance mode, which is a frequency-determining element of the oscillator. In this case, the sensitivity of the device is low.

The closest in technical essence to the proposed one is a known device for measuring the flight speed of a bullet and a projectile, containing two ring magneto-induction sensors, the signal windings of which are covered by a coil of magnetically soft material, spaced apart at the base distance along the flight path, pulse shaping circuit, one-shot, inverter, meter time intervals and calculator. In order to increase the reliability and accuracy of measurements, a normalizing amplifier, a zero-organ, a second one-shot and a matching circuit are introduced into it, while the signal windings of the magnetic induction sensors are connected to the input of the first one-shot through a normalizing amplifier and a zero-organ, and the output of the first one-shot is connected to the first input of the time interval meter, with the second input of the second one-shot and with the first input of the matching circuit, the second input of which is connected to the output of the second one-shot, and the output coincidence circuits through an inverter are connected to the second input of the time interval meter, the output of which is connected to the computer, the output of which is connected to the installation input of the time interval meter, magneto-inductive sensors are mounted on a pipe of non-magnetic and non-conductive material and placed in a metal casing, and the case of each of them is made of insulating material, the turns of the signal windings of the sensors are isolated from the housings by a gasket of elastic non-conductive material [2].

The disadvantages of the known device include a limited measurement range due to its design due to the fact that the excitation of eddy currents in the projectile occurs as a result of the rapid movement of the projectile in an inhomogeneous constant magnetic field. In this case, the signal that occurs in the signal winding depends on the speed of flight of the projectile, which makes the device not applicable at low speeds.

The utility model has the task of improving the device for measuring the projectile’s flight speed, in which, due to a different design and principle of its operation, the measurement range is expanded by measuring at any projectile speed, as well as increasing the sensitivity of the measurement unit, which allows to accelerate the measurement process .

This object is achieved in that in a device for measuring the speed of a projectile made of lead and its alloys, mainly pneumatic small arms, including a measurement unit with two inductors, a supporting element in the form of a tube for a missile projectile, on which two inductors are mounted, spaced at a basic distance along the flight path, pulse shapers, a time interval meter and a computer, according to a utility model, the device is made in the form of a single of the block located in the housing and equipped with a high-frequency generator - highly stable in both frequency and amplitude, an indication unit, and a power supply, the measurement unit is made in the form of two parallel-connected oscillatory circuits with a natural resonance frequency close to the frequency supplied to the circuit generator signal, each oscillating circuit contains a series-connected inductance coil and capacitor, and is connected in parallel to the generator and to two pulse shapers of the projectile span, while coil means is a registration of the projectile flight, and each pulse generator is in the form of the amplitude detector.

In addition, in some cases, the proposed device is characterized by the following features: - it has a fastener made in the form of a thread on the end of the tube for projectile projectile passage, with the possibility of attaching an adapter sleeve for attaching the device to the gun barrel; - the power supply is autonomous, built-in inside the case or external; - the display unit is made in the form of a seven-segment light three-digit LED indicator located on the panel of the housing in the window for the indicator.

As a result of using the claimed utility model, a technical result is obtained consisting in expanding the measurement range due to the possibility of measurement at any velocity of the projectile, as well as increasing the sensitivity of the measurement unit.

The specified technical result is achieved due to the fact that the proposed device uses a different principle of exciting eddy currents in the projectile, not constant as in the prototype, but by the RF magnetic field created by the coil, which ensures a constant amplitude signal level in the signal coil of the inductance, regardless projectile flight speed. The device is supplemented by a highly stable RF generator, and the signal inductance coil is used to radiate an RF magnetic field, and is also included as a coil in a series resonant circuit tuned in frequency from the generator, which in turn significantly increased the sensitivity of the measurement unit. At the same time, a quick response to external excitation and a significant signal are provided. In General, the distinguishing features of the claimed device are essential and necessary to achieve a new technical result.

According to the information available to the applicant, the set of essential features characterizing the essence of the claimed utility model is not known from the prior art, which allows us to conclude that the utility model meets the criterion of "novelty." The inventive utility model can be repeatedly implemented and manufactured by well-known in industry, including in measuring equipment, methods using known means, which allows us to conclude that it meets the criterion of "industrial applicability". Thus, the claimed utility model meets all the conditions of its patentability.

The proposed utility model is illustrated by drawings, where Fig. 1 is an electrical block diagram of a device, and Fig. 2 schematically shows its measurement unit.

In the drawings, the following is indicated. In figure 1. indicated: 1 - high-frequency generator; 2 - sequential oscillatory circuit L1 C1; 3 - sequential oscillatory circuit L2 C2; 4,5-shaper impulses span projectile; 6 - meter time intervals; 7 - calculator; 8 - display unit. Figure 2 designated: 9 - inductor L1; 10 - a supporting element in the form of a tube through which the projectile passes; 11 - inductor L2.

A device for measuring the speed of a projectile of lead and its alloys, mainly pneumatic small arms, is made in the form of a single unit placed in a housing (for example, in a plastic box). The device includes a measurement unit with two inductors, a supporting element 10 in the form of a tube for a missile projectile, on which two inductors are spaced apart at a basic distance along the flight path, pulse shapers 4, 5, a time interval meter 6 and a calculator 7. Proposed the device is equipped with a high-frequency generator 1 - highly stable in both frequency and amplitude, an indication unit 8, and a power supply unit (not shown in the drawing). The measurement unit is made in the form of two parallel-connected oscillatory circuits 2, 3 with a natural resonance frequency close to the frequency of the generator signal supplied to the circuit. Each oscillating circuit 2, 3 contains a series-connected inductor and capacitor, and is connected in parallel to the generator 1 and to two pulse shapers of the projectile span 4, 5. In this case, the coil is a means of recording the projectile span. And each pulse shaper 4, 5 is made in the form of an amplitude detector.

In addition, the device may have a mount, made in the form of a thread on the end of the tube for the passage of a projectile, with the possibility of attaching to it an adapter sleeve for mounting the device on the barrel of an air gun. The power supply unit (not shown in the drawing) can be made stand-alone, built-in inside the case, or external. The display unit 8 can be made in the form of a seven-segment light three-digit LED indicator located on the panel of the housing in the window for the indicator.

Before use, the supporting element 10 — the tube through which the projectile passes, is fixed on the barrel of an air gun using a fastener in the form of a thread on the end of the tube 10 with the possibility of attaching a transition sleeve to it.

The device is turned on by briefly pressing the “On” button on the case, after which a greeting is displayed, for example, “741”. Then a horizontal bar starts flashing in the center of indicator 8, signaling the possibility of starting measurements.

A device for measuring the speed of flight of a projectile works as follows. The device is based on the principle of detecting changes in the amplitude of HF oscillations on a capacitor in a series resonant circuit as metal objects approach the coil of the resonant circuit. An RF signal from a generator 1, highly stable both in frequency and amplitude, is supplied to a series oscillatory circuit 2, 3. The frequency of the generator 1 does not coincide with the resonant frequency of the oscillatory circuit. The natural resonance frequency of the measurement unit, made in the form of two parallel-connected oscillatory circuits 2, 3, is close to the frequency of the signal of the generator 1 supplied to the circuit. The frequency of the generator 1 differs from the resonant frequency of the circuit so that the amplitude of the oscillations on the circuit capacitor is approximately two times less than the amplitude at resonance, that is, in the middle of the slope of the known resonance curve for a given circuit. The choice of the operating point, that is, the settings of the oscillatory circuit 2, 3 relative to the frequency of the generator 1, determines the level of the signal supplied to the pulse shaper 4, 5 (sensitivity) and the nature of the change in this signal. The signal of the generator 1 creates an electromagnetic high-frequency (HF) field in the coil, which excites eddy currents in the material of the projectile. In this case, the coil is a means of registering projectile span (that is, it acts as a signal winding), since it interacts with the eddy currents that arise in the material of the projectile (lead and its alloys). An electromagnetic rf field arising in the coil induces eddy currents in the material of the projectile, which in turn leads to a change in the inductance of the coil and a change in the amplitude of the rf oscillations on the capacitor. The useful signal is removed from the capacitors C1 and C2 of the oscillatory circuits 2, 3 and fed to the pulse shapers of the projectile span 4 and 5. Each pulse shaper 4, 5 is an amplitude detector that forms the envelope of the RF signal on the corresponding capacitor of the oscillating circuit 2, 3. During the span projectile through the coil, a dip or an increase in amplitude occurs on the envelope (depending on the type of projectile material), which is the control signal for measuring time intervals 6. The shape of the envelope and thereon bursts are control signals for the meter slots 6. The measured time interval is supplied to the calculator 7, wherein the known base between the coils is calculated projectile velocity. According to the time interval and the known base (the distance between the coils), the calculator 7 gives the value of the velocity of the projectile. After the passage of the projectile, for 5 seconds, the indicator 8 displays the velocity of the projectile in m / s. The measurement can be carried out by indicating a flashing horizontal bar of indicator 8 or by displaying the measured speed value. Thus, the proposed device allows you to measure the speed of flight of a projectile from lead and its alloys at any speed of the projectile. INFORMATION SOURCES.

1. Certificate of the Russian Federation No. 19329 for utility model, IPC 6 G01P 3/66, decl. 03/07/2001, publ. 08/20/2001.

2. RF patent No. 2089917 for the invention, IPC 6 G01P 3/66, decl. 03/15/1991, publ. 09/10/1997 (prototype).

Claims (4)

1. A device for measuring the speed of a projectile made of lead and its alloys, mainly pneumatic small arms, including a measuring unit with two inductors, a supporting element in the form of a tube for flying a missile projectile, on which two inductors are spaced apart at a basic distance along the path flight, pulse shapers, time interval meter and calculator, characterized in that the device is made in the form of a single unit located in the housing, and is equipped with co-frequency generator - highly stable in both frequency and amplitude, indicating unit and power supply, the measurement unit is made in the form of two parallel-connected oscillatory circuits with a natural resonance frequency close to the frequency of the generator signal supplied to the circuit, each oscillatory circuit contains a coil connected in series inductance and capacitor, and is connected in parallel to the generator and to two pulse shapers of the span of the projectile, while the coil is a means of recording that the projectile, and each pulse generator is in the form of the amplitude detector. 2. The device according to claim 1, characterized in that it has a fastener made in the form of a thread on the end of the tube for projectile projectile passage, with the possibility of attaching to it an adapter sleeve for fastening the device to the barrel of an air gun. 3. The device according to claim 1, characterized in that the power supply is made autonomous, built-in inside the housing or external. 4. The device according to claim 1, characterized in that the display unit is made in the form of a seven-segment light three-digit LED indicator located on the panel of the housing in the window for the indicator.