RU189818U1 - High Speed Solid Microparticle Accelerator - Google Patents

Abstract

The utility model relates to the field of accelerator technology and can be used to simulate micrometeorites and man-made particles. The accelerator of high-speed solid microparticles contains an injector, induction sensors, a linear accelerator, a source of a fixed high voltage, cylindrical electrodes, a speed selector, a selector of specific charges, a power supply unit electrodes, generator of time-varying frequency and pulse duration in a pack, interface unit, electronic computer, effort A spruce variable-pulse pulse train, a cascade generator, a target consisting of a phosphor deposited on glass, a CCD array, each induction sensor consists of two large electrodes and two small electrodes attached to a dielectric insert, a shielding ring attached to a ring holder that is attached to the dielectric insert, the screen located on top of the dielectric insert, with the introduction of amplifiers of small electrodes and large electrodes, decisive devices. The advantages of this detector ra compared with other similar devices is to improve the accuracy of measuring the speed of microparticles through the use of a single amplifier. 2 Il.

Description

The invention relates to the field of accelerator technology and can be used to simulate micrometeorites and man-made particles.

A high-speed solid particle accelerator is known, based on the Sloan-Lawrence accelerating system, consisting of an injector, a linear accelerator, two induction sensors, cylindrical electrodes, a fixed voltage source, amplifiers, a speed selector, a controlled frequency generator and a target (Sletteri, Becker, Hamermensch, Roy Linear accelerator for micrometeorite modeling. (Instruments for scientific research., 1973, v. 44, No. 6.).

The disadvantages of this invention:

1. this accelerator has large dimensions, since each subsequent drift tube is longer than the previous one;

2. This accelerator has a narrow range of specific charges of particles to be accelerated, since the voltage on the drift tubes is a function of the particle velocity at the accelerator input, and the specific particle charge is included in the computational model as a constant;

3. Due to the unevenness of the gain factors of the charge-sensitive amplifiers (their gain factors have an error of tuning), the speed of the microparticles is also measured with a large error.

Known accelerator of high-speed solids with auto-tuning of the distribution function of particles along the radius (Patent for invention No. 2451434 published 20.05.2012). The high-speed solid particle accelerator contains an injector, induction sensors, amplifiers, a linear accelerator, a fixed high voltage source, cylindrical electrodes, a speed selector according to the invention, four parallel electrodes are installed between the second pair of induction sensors and each connected to a voltage supply unit on the electrodes, the target is made of glass, on the surface of which a phosphor film is applied, and on its back side a CCD is installed - m Atric connected to the data processing unit with a CCD sensor that controls the unit supplying voltage to the electrodes.

The disadvantages of this invention is the differences in the gains of the charge-sensitive amplifiers (their gains have a tuning error), the speed of the microparticles is also measured with a large error.

The closest prototype is an accelerator of high-speed solids with speed vector correction (Patent for invention №2593594 published 08.10.2016). The high-speed solid particle accelerator contains an injector, induction sensors, amplifiers, a linear accelerator, a fixed high voltage source, cylindrical electrodes, a speed selector, a specific charge selector, an electrode voltage supply unit, cylindrical electrodes, a generator of time-varying pulses in a bundle, interface unit, electronic computer, variable-pulse pulse amplifier, cascade generator, target, according to the invention in an accelerator A control unit and a coordinate selector are entered, and the control unit is connected to the coordinate selector, which is connected to the generator of the time-varying frequency and pulse duration in the packet.

The disadvantage of this invention is that induction sensors are used to measure the speed of an accelerated microparticle, the signals from which are measured by two different amplifiers, and this can lead to errors in measuring the speed of the microparticle.

The task is to eliminate the differences in the parameters of amplifiers connected to induction sensors, which will reduce the error in measuring the speed of microparticles, improve the accuracy of voltage formation on the drift tubes and increase the efficiency of the accelerator.

The task is achieved by the fact that an accelerator of high-speed solid microparticles containing an injector, induction sensors, a linear accelerator, a source of a fixed high voltage, cylindrical electrodes, a speed selector, a specific charge selector, a voltage supply unit to the electrodes, a generator of time-varying pulses in time bundle, interface unit, electronic computer, variable-pulse pulse amplifier, cascade generator, target consisting of phosphor a, applied to glass, a CCD array according to the invention; each induction sensor consists of two large electrodes and two small electrodes attached to a dielectric insert, a shielding ring attached to a ring holder that is attached to a dielectric insert, a screen located over the dielectric insert, at the same time, additional amplifiers for small electrodes and large electrodes, decisive devices, each large electrode of inductive sensors are connected to the input of the corresponding amplifiers. I large electrodes, small electrodes of one induction sensor are connected by common wire to the input of the small electrode amplifier, the outputs of the amplifiers of the large electrodes and the small electrode amplifier of the induction sensor are connected to the solvers, the output of the decision devices connected to the amplifiers of the first induction sensor the output of the resolvers connected to the amplifiers of the second induction sensor is connected to the specific charge selector and the speed selector; the output is third The inductive sensor is connected to a generator of time-varying frequency and pulse duration in a pack.

The invention is illustrated by drawings:

in fig. 1 shows a general view of the accelerator in conjunction with the service equipment;

in fig. 2 shows the design of the induction sensor.

The device contains an injector 1, induction sensors 2, amplifiers of small electrodes 3, amplifiers of large electrodes 4, decisive device 5, linear accelerator 6, fixed high voltage source 7, four parallel electrodes 8, speed selector 9, specific charge selector 10, voltage supply unit on electrodes 11, cylindrical electrodes 12, a generator of time-varying frequencies and durations of pulses in a pack 13, an interface unit 14, an electronic computer 15, an amplifier of a pack of pulses of variable duration 16, scad generator 17, data processing unit with a CCD matrix 18, a target consisting of a phosphor 19 deposited on glass 20, a CCD matrix 21. This inductive sensor 2 consists of large electrodes 22, a metal screen 23, a dielectric insert 24, small electrodes 25 , shielding ring 26, ring holder 27.

Each large electrode 22 of induction sensors 2 is connected to the input of a corresponding amplifier of large electrodes 4, small electrodes 25 of one induction sensor 2 are interconnected and are connected with a common wire to the input of an amplifier of small electrodes 3. The outputs of amplifiers of large electrodes 4 and the amplifier of small electrodes 3 of one induction sensor connected to the decisive devices 5, the output of which is connected to the input of the speed selector 10, the output of the speed selector 10 and the output of the specific charge selector 9 are connected to the inputs of the generator and time-varying frequency and pulse duration in bundle 13; generator output; time-varying frequency and pulse duration in bundle 13 is connected to the first input of a variable pulse width amplifier 16 whose outputs are connected to cylindrical electrodes 12, the output of the cascade generator 17 is connected to the second input of an amplifier of a pulse train of variable duration 16, a generator of time-varying frequency and pulse duration in the packet 13 is connected to the input of an interface unit 14, which is connected to an electronically calculated using the machine 15.

The device works as follows. Injector 1 generates charged particles in a given mass range with a frequency of about 1 Hz. The charged particle successively passes the first induction sensor 2, the linear accelerator 6, the second induction sensor 2, cylindrical electrodes 12, the third induction sensor 2 and enters the phosphor 19. The first pair of induction sensors 2 and the linear accelerator 6 are designed to determine particle parameters (specific charge Q / m and initial velocity V ₀ ). When a high-speed microparticle of an induction sensor passes, a charge is induced on the large and small electrodes according to the Ramo-Shockley theorem, while a single amplifier is used to amplify the signal from small electrodes, which allows to receive a voltage pulse in the form of a two-vertex signal at the output of the small electrode, In this case, each of the signal vertices corresponds to a passage by a microparticle of the middle of a small electrode. In order for a high-speed microparticle not to charge at the same time on both small electrodes and both large electrodes a shielding ring 26 is used. The distance on the time scale between these two vertices will be inversely proportional to the speed of the microparticle. In order to further divide this signal into two different inputs, decisive devices 5, operating according to the AND scheme, are used, one of the inputs of which receives a signal from the amplifier of small electrodes 3, and a signal from one of the amplifiers of large electrodes to the second input 4. On arriving from induction sensors of signals, the speed selector 9 and the specific charge selector 10 form at their outputs a digital code of the initial velocity of the particle and a code of its specific charge. In the speed selector 9, the time intervals of the passage by a particle of induction sensors are measured. After passing through a linear accelerator 6, the particle is incremented by speed. According to the codes of the initial velocity and specific charge in the generator of the time-varying frequency and pulse duration in the pack 13 a pack of pulses is formed, which creates an accelerating field between each pair of electrodes 12. This field changes with time according to the position of the particle in the accelerating path. Bundle parameters are selected from a series of data to form pulses preset in the generator of time-varying frequency and pulse duration in bundle 13 with a computer 15. A pulse train of variable duration 16 amplifies the pulses of time-varying pulse frequency and duration in a burst 13 of pulses. The amplified pulses arrive at the cylindrical electrodes 12. Then the accelerated particle hits the target and the whole process repeats. The computer 15 collects experiment statistics and dynamic accelerator control. The impact of a microparticle on a target consisting of phosphor 19 causes a glow at the site of impact, which is recorded using a CCD matrix 21. According to the information obtained from a CCD, control pulses are generated in the data processing unit with CCD 18, and the voltage on four electrodes is changed using a block supply voltage to the electrodes 11, according to the formula:

where U1, U2, U3, U4 are the potentials applied to the four electrodes, k ₁ , k ₂ are constant coefficients, U ₀ is the DC voltage on the electrodes, ΔX is the deviations along the 0X axis of the point where the particle hits the target axis of the accelerator, developed The CCD data processing unit of the matrix 18, ΔY, is the deviations along the 0Y axis of the point where the particle hits the target center axis of the accelerator, developed by the CCD data processing unit of the matrix 18, where the 0X and 0Y axes are mutually perpendicular to each other and perpendicular to the accelerator center axis.

According to the data obtained from the third induction sensor 2, it is estimated by how much the particle velocity has increased relative to the particle velocity measured using the second induction sensor 2.

The adjustment ends when the particles start to hit the exact center of the target.

The technical result is to increase the efficiency of the accelerator by reducing the error in measuring the speed of microparticles by using one amplifier instead of two in induction sensors, and this leads to an increase in the accuracy of voltage formation on the drift tubes and an increase in the efficiency of the accelerator.

Claims (1)

High-speed solid microparticle accelerator containing an injector, induction sensors, a linear accelerator, a source of a fixed high voltage, cylindrical electrodes, a speed selector, a specific charge selector, a voltage supply unit to the electrodes, a generator of time-varying pulses in a pack, an interface unit, electronically - computational machine, variable-pulse pulse amplifier, cascade generator, target consisting of phosphor deposited on glass, CCD matrix, exc Due to the fact that each induction sensor consists of two large electrodes and two small electrodes attached to a dielectric insert, a shielding ring attached to a ring holder that is attached to a dielectric insert, a screen located over the dielectric insert, with additional amplifiers of small electrodes added and large electrodes, decisive devices operating according to the logical “AND” scheme, each large electrode of induction sensors is connected to the input of the corresponding amplifier bol Lower electrodes, small electrodes of one induction sensor are connected by a common wire to the input of an amplifier of small electrodes, the outputs of amplifiers of large electrodes and an amplifier of small electrodes of an induction sensor are connected to solvers, the output of decision devices connected to amplifiers of the first induction sensor is connected to a selector of specific charges, output solvers connected to amplifiers of the second induction sensor are connected to a specific charge selector and a speed selector; oystv connected to amplifiers third induction sensor is connected with a generator of variable frequency and time duration of pulses in the burst.

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