RU2305379C1 - Generator of high voltage linearly increasing impulses of microsecond duration - Google Patents

Abstract

FIELD: acceleration equipment engineering, possible use for generating high voltage impulses, generating electronic or ionic beams of microsecond duration with high repetition frequency.

SUBSTANCE: generator of high voltage linearly increasing impulses contains a high voltage impulse transformer in form of a set of ferromagnetic inducers, circled by magnetization coils. On both sides of inducers, clamps of magnetization coils are electrically combined and connected to clamps of last compression links of two or more magnetic impulse generators, installed in parallel. Magnetic impulse generators represent a series of at least two compression links, consisting of capacitors and saturation throttles. Generation of high voltage output impulse of microsecond duration is realized due to serial discharge of capacitors of last compression links of magnetic impulse generators through windings of saturation throttles onto the primary winding of high voltage impulse transformer. Impulse feeding delay from various magnetic impulse generators is achieved by selection of interlinking values of saturation throttles of last compression links. To create a linearly increasing impulse of output voltage, capacities of capacitors of last compression links of magnetic impulse generators are compliant with expression: C_1N<kC_2N<...<kC_mN, where k=1,1-2 and following condition is fulfilled: C_1N·L_1N≈ C_2N·L_2N≈...≈C_mN·L_mN, where C_1N, C_2N,..., C_mN - capacities of capacitors of last compression links of magnetic impulse generators, L_1N, L_2N,..., L_mN - inductances of windings of saturation throttles of last compression links of magnetic impulse generators.

EFFECT: realization of serial discharge of capacitors of different capacity through windings of saturation throttles of last compression links of several magnetic impulse generators onto the primary winding of a high voltage impulse transformer.

1 cl, 1 dwg

Description

The invention relates to accelerator technology and can be used to generate high-frequency pulses of high voltage microsecond duration, to generate charged particle beams.

To obtain high voltage pulses, generate high-current electron or ion beams of nanosecond duration, linear induction accelerators (LIU) are used [Vintisenko II, Furman E.G. Linear induction accelerators. University News Physics. TSU Edition, 1998, No. 4, Appendix, pp. 111-119]. This device contains an induction system in the form of a set of ferromagnetic inductors covered by magnetization coils. Electrodes of the forming line are connected to the magnetization coils. An impulse of charging voltage, usually of positive polarity, with an amplitude of 30-250 kV, depending on the installation class, is supplied to one of the electrodes of the forming line from the power source. The second electrode is grounded. After turning on the switch of the forming line, which is a saturation inductor with a core made of ferromagnetic steel and installed in the gap of any of the electrodes, the single forming line is discharged to the turns of the induction system, forming a current along the turns of magnetization of the ferromagnetic inductors. This current causes an alternating magnetic flux, creating a vortex electric field that accelerates charged particles. The electric field strength along the axis of the induction system is defined as:

where N is the number of inductors; U (t) is the voltage applied to the magnetization coils (voltage of the forming line); L is the length of the induction system. The above describes the design of the accelerating section LIU. If a metal electrode is placed along the axis of the induction system, then a vortex EMF will be induced on it and the potential difference at the opposite ends of the electrode will be: U _o (t) = - NU (t). This design is used for injection (cathode or anode) sections of linear induction accelerators. It should be noted that the injection sections can be used independently as high-voltage pulse generators for powering relativistic magnetron or reflective triode devices.

The fundamental difference between a linear induction accelerator and other types of accelerators, for example a direct-action accelerator, is the use of a magnetic switch of the forming line. Such a switch is capable of commuting with an unlimited resource at a frequency of a few kilohertz currents of hundreds of kiloamperes. However, in this case, it is required to charge the forming line within a hundred nanoseconds from magnetic pulse generators, otherwise the dimensions, and therefore the inductance of such a switch, become unacceptably large. Magnetic pulse generators are used to charge the forming lines, which are a sequence of N compression links (LC circuits with increasing natural frequency). Each compression unit contains a condenser with lumped parameters and a saturation choke. The capacitances of the capacitors of the compression units C ₁ , C ₂ , ... C _N are equal to each other and equal to the capacitance C _{fl of the} single forming line. Each subsequent saturation inductor L _i , compared with the previous L _i-1, has a lower winding inductance when the core is saturated. Therefore, the processes of energy transfer from one compression link to the next link occur in a shorter time interval than provides energy compression to charge the forming line in a short period of time (hundreds of nanoseconds).

Such linear induction accelerators can operate with a pulse repetition rate of a few kilohertz. Their main disadvantage is the short pulse duration of the output voltage (no more than 200 ns). This is connected: 1) with the use of forming lines with a limited length, 2) with the use of magnetic switches capable of charging the forming lines with an electric length of 0.5-1 μs, only with a significant mass of ferromagnetic material, 3) using a ferromagnetic induction system capable of transforming a voltage pulse for a limited time until the moment of saturation of the ferromagnetic inductors. The permissible time interval Δt from the moment of applying a rectangular voltage pulse with amplitude U to the moment of saturation of the inductors is determined by the following formula:

where Ψ = ω · S · ΔВ is the flux linkage of the induction system, ω is the number of turns of magnetization of the ferromagnetic inductors of the induction system, S is the cross section of the steel of the ferromagnetic inductors, ΔB is the magnitude of the magnetic induction in the steel of the inductors. To obtain an output pulse of a rectangular shape or close to it, induction systems are made with one coil of magnetization of inductors. An increase in the number of turns of magnetization to two leads to an increase of approximately 4 times the inductance of the discharge circuit formed by the capacitance of the forming line and the inductances of the magnetic switch and turns of magnetization. At the same time, the duration of the output voltage pulse is 2 times longer with a proportional decrease in its amplitude parameters (the maximum power in the pulse is reduced 2 times). The output voltage pulse of the induction system takes on a bell-shaped form. In the case of using a linear induction accelerator for the formation of charged particle beams, one should expect a large energy spread of the particles. The increase in flux linkage of the induction system is limited by the size of the produced ferromagnetic inductors, and ΔB is limited by the properties of the ferromagnetic material. Based on the foregoing, linear induction accelerators are manufactured to form pulses of the output voltage of nanosecond duration.

The closest technical solution is the design of a linear induction accelerator [Vintizenko II Linear induction accelerator. RF patent №2265973, IPC Н05Н 5/08, publ. 12/10/2005, bull. No. 34]. To generate high-voltage pulses of microsecond duration, a linear induction accelerator is used, containing an induction system in the form of a set of ferromagnetic inductors covered by magnetization coils. The conclusions of the magnetization coils on each side of the inductors are interconnected and connected to the terminals of the last compression links of several (m) parallel magnetic pulse generators. A magnetic pulse generator is a sequence of N≥2 compression links with increasing natural frequency, each of which consists of a condenser with lumped parameters and a saturation inductor.

, где U_iN - напряжение на конденсаторах последних звеньев сжатия i-го магнитного импульсного генератора, L_iN - индуктивность обмоток дросселей насыщения последних звеньев сжатия, C_iN - емкость конденсаторов последних звеньев сжатия. Значение 0.5 соответствует включению i-го магнитного импульсного генератора в максимуме импульса тока разряда предыдущего (i-1)-го магнитного импульсного генератора. В этом случае формируется выходной импульс с формой, близкой к прямоугольной. Значение 1 соответствует включению i-го магнитного импульсного генератора в момент окончания импульса тока разряда предыдущего магнитного импульсного генератора. При этом значении выходной импульс, формируемый индукционной системой, имеет максимальную длительность.The magnitude of the flux linkages of the saturation chokes of the last compression links of each magnetic pulse generator differ from each other (Ψ _1N <Ψ _2N <... <Ψ _mN ) by a range value equal to:

where U _iN is the voltage across the capacitors of the last compression links of the i-th magnetic pulse generator, L _iN is the inductance of the windings of the saturation chokes of the last compression links, C _iN is the capacitance of the capacitors of the last compression links. The value 0.5 corresponds to the inclusion of the i-th magnetic pulse generator at the maximum of the discharge current pulse of the previous (i-1) -th magnetic pulse generator. In this case, an output pulse is formed with a shape close to rectangular. The value 1 corresponds to the inclusion of the i-th magnetic pulse generator at the end of the discharge current pulse of the previous magnetic pulse generator. With this value, the output pulse generated by the induction system has a maximum duration.

With this method of generating high voltage pulses, it is possible to use inductors of the induction system with multi-turn magnetization coils, which can significantly (in the number of turns used times) reduce the weight and size and cost parameters of the induction system. Naturally, in this case, to maintain the transformation coefficient of the induction system, usually equal to the number of inductors, it is necessary to use a multi-turn secondary winding. Moreover, to obtain higher values of the output voltage, the number of turns of the secondary winding may exceed the number of turns of magnetization of the inductors. In this case, the LIU induction system is converted into a linear high-voltage pulse transformer. Similar constructions are described, for example, in [Vdovin S.S. Design of pulse transformers. Leningrad, Energoatomizdat, 1981, p.178-180]. In such systems, the use of several series-mounted inductors (magnetic circuits) of relatively small size according to the principle of the LIU induction system eliminates the use of large magnetic cores that cannot always be manufactured. In addition, the use of a set of inductors reduces the inductance of the discharge circuit of the last compression links by the number of inductors used, thereby reducing the duration of the leading edge of the output pulse and reducing the energy spread of the beam particles.

The task of the invention is to provide a generator of high-voltage linearly increasing pulses of microsecond duration. The need for the formation of pulses with similar characteristics is caused by the fact that often the injection sections of linear induction accelerators are used as high-voltage generators to power explosion-emitting diodes, relativistic magnetrons, reflective diodes, and vircators. In such systems, the expansion of the cathode and anode plasma causes a change in the accelerating gap during the action of the high voltage pulse. Typically, there is a decrease in the impedance of the diode and, as a consequence, a decrease in the amplitude of the output voltage during the pulse. This leads to a decrease in the energy of the beam particles. To correct the voltage drop, the proposed generator can be used to stabilize the voltage level on the diode, i.e. to form beams of charged particles of the same energy at different angular momenta.

The technical result is the sequential discharge of capacitors of different capacities through the windings of saturation chokes of the last compression links of several (two or more) magnetic pulse generators to the primary winding of a high voltage pulse transformer. Moreover, the capacitance of the capacitors and inductance of the windings of the saturation chokes are in a certain relationship with each other.

To solve this problem, the generator of high-voltage linearly increasing pulses of microsecond duration, like the prototype, contains a high-voltage pulse transformer in the form of a set of ferromagnetic inductors. Ferromagnetic inductors are covered by magnetization coils, the conclusions of the magnetization coils of all inductors exiting from each side of the inductors are interconnected and are electrically connected to the terminals of the last compression units m of magnetic pulse generators. Magnetic pulse generators have N≥2 compression links formed by capacitors and saturation chokes, while magnetic pulse generators are connected in parallel and have saturation chokes of the last compression links with different values of flux linkage.

In contrast to the prototype in the proposed generator for generating an output voltage pulse with an increasing amplitude of the capacitors of the last compression links of the magnetic pulse generators are in the following relation: C _1N <kC _2N <... <kC _mN , where k = 1.1-2, moreover, the condition must be fulfilled: C _1N · L _1N ≈C _2N · L _2N ≈ ... ≈C _mN · L _mN , where L _1N , L _2N , ..., L _mN are the inductances of the saturation chokes of the last magnetic pulse compression units generators.

A schematic diagram of a generator of high-voltage linearly increasing pulses of microsecond duration is shown in the drawing, where it is indicated: 1 - a high-voltage pulse transformer consisting of several series-mounted inductors (four inductors are shown in the drawing), 2 - magnetization coils of the inductors forming the primary winding of a high-voltage pulse transformer, 3 - a first magnetic pulse generator consisting of a capacitor C ₁₁ -C _1N and the saturation inductors L ₁₁ -L _1N, 4 - second magnetic pulse first generator consisting of the capacitors C ₂₁ -C _2N and saturation inductors L ₂₁ -L _2N, 5 - m-th magnetic pulse generator consisting of a capacitor C _m1 -C _mN and the saturation inductors L _m1 -L _mN, 6 - secondary winding high-voltage pulse transformer loaded with non-linear dynamic load resistance 7.

The generator of high-voltage linearly increasing pulses of microsecond duration contains a high-voltage pulse transformer 1 of sequentially installed ferromagnetic inductors. Ferromagnetic inductors are covered by magnetization coils having conclusions 2. The number of magnetization coils may exceed one. The conclusions of the magnetization turns coming out on each side of the inductors are electrically connected. The magnetization coils of the inductors together with their terminals form the primary winding of the high-voltage pulse transformer. The conclusions of the magnetization turns 2 are connected to the last compression links of the magnetic pulse generators 3, 4, 5 with a total number m. Magnetic pulse generators 3, 4, 5 have the same electrical circuit and principle of operation, consist of sequential LC compression links. The secondary winding of a high-voltage pulse transformer covers all inductors and is connected to a load resistance 7 (for example, an electronic or ion diode).

The generator of high-voltage ramp pulses of microsecond duration works as follows. Initially, external sources (not indicated) demagnetize the cores of saturation chokes L ₁₁ -L _{1N of the} first magnetic pulse generator 3, the cores of saturation chokes L ₂₁ -L _{2N of the} second magnetic pulse generator 4, the cores of saturation chokes L _m1- L _mN m-th magnetic pulse generators 5 and inductors of a high-voltage pulse transformer 1. From an external power source (not specified), for example, a capacitor bank is discharged through a high-voltage transformer when an ignitron or ristornogo switch is performed simultaneously charge the capacitor C ₁₁ of the first link of the first magnetic compression pulse generator 3, a capacitor C ₂₁ of the first link of the second magnetic compression pulse generator 4, the capacitor C _m1 of the first compression unit m-th magnetic pulse generator 5. Consider the processes occurring in the magnetic elements pulse generators on the example of a magnetic pulse generator 3, since in all magnetic pulse generators occur similar processes.

When the charge C ₁₁ at the terminals of the saturation inductor L ₁₁ appears the potential difference U _C11 , causing the magnetization current to flow through the winding and the magnetization reversal of the core of the saturation inductor L ₁₁ . The flux linkage of the saturation inductor L ₁₁ is: ψ ₁₁ = ω ₁₁ S ₁₁ ΔB, where ω ₁₁ is the number of turns, S ₁₁ is the cross section of the inductor steel, ΔB is the induction span (for example, ΔВ = 2.5 T for permalloy 50 NP), and is selected so that the core of the throttle is saturated at the end of the charge With ₁₁ . When the core is saturated, its magnetic permeability decreases from μ = 10 ⁵ to μ = 1 and the saturation inductor turns into a conventional air inductance. The discharge C ₁₁ and the charge C ₁₂ begin through the winding of the inductor L ₁₁ in the time interval:

The duration of the charge process C _{12 is} limited by the magnitude of the flux linkage of the saturation inductor L ₁₂ . When the capacitor C _{12 is} charged, the potential difference begins to be applied to the winding of the saturation inductor L ₁₂ :

, U_C11 - амплитуда зарядного напряжения конденсатора С₁₁. Среднее значение напряжения на витках дросселя насыщения в интервале времени [0, π] составит:Where

, U _C11 - the amplitude of the charging voltage of the capacitor C ₁₁ . The average value of the voltage at the turns of the saturation inductor in the time interval [0, π] will be:

, где ψ₁₂=ω₁₂S₁₂ΔB - потокосцепление дросселя насыщения (ω₁₂, S₁₂ - число витков и сечение стали сердечника дросселя насыщения L₁₂, ΔB - размах индукции в стали).This voltage causes a magnetization reversal magnetization saturation L ₁₂ and its transition to a state with μ → 1. therefore

where ψ ₁₂ = ω ₁₂ S ₁₂ ΔB is the flux linkage of the saturation inductor (ω ₁₂ , S ₁₂ is the number of turns and the cross section of the core steel of the saturation inductor L ₁₂ , ΔB is the induction span in steel).

At saturation inductor L ₁₂ starts discharge of the capacitor C ₁₂ and C ₁₃ charge the capacitor through the saturable reactor winding ₁₂ L. The time interval of this process is limited by the magnitude of the flux linkage of the saturation inductor L ₁₃ :

(ω₁₃, S₁₃ - число витков обмотки и сечение стали сердечника дросселя насыщения L₁₃),

Where

(ω ₁₃ , S ₁₃ - the number of turns of the winding and the steel section of the core of the saturation inductor L ₁₃ ),

Similar to the previous reasoning:

where ω _1N , S _1N is the number of turns and the steel section of the saturation reactor of the last compression link of the first magnetic pulse generator 3. Using relations (3) - (7), the parameters of the elements of the magnetic pulse generators are calculated. Usually, in their manufacture, C ₁₁ = C ₁₂ = ... = C _{1N is} chosen and in this case <U ₁ > = <U ₂ > = ... = <U _N-1 > == 1 / 2U _C11 = 1 / 2U _C12 = 1 / 2U _C1N-1 = 1 / 2U _C1N , where U _C11 , U _C12 , ... U _C1N are the amplitudes of the charging voltage of the capacitors of a magnetic pulse generator. Similarly choose: C ₂₁ = C ₂₂ = ... = C _2N , C _m1 = C _m2 = ... = C _mN and <U ₁ > = <U ₂ > = ... = <U _N-1 > = = 1 / 2U _C11 = 1/2 U _C12 = ... = 1/2 U _C1N-1 = 1/2 U _C1N = 1/2 U _C21 = 1/2 U _C22 = ... = 1/2 U _C2N-1 = 1 / 2U _C2N == 1 / 2U _Cm1 = 1/2 _{U Cm2} = ... = 1/2 _{U CmN-1} = 1/2 _{U CmN} . Note that in the general case, the capacitances of the first C ₁₁ = ... = C _1N , second C ₂₁ = ... = C _2N and mth C _m1 = ... = C _mN magnetic pulse generators may not be equal between by myself.

In order for energy compression to occur, the flux linkage of the saturation reactor of the next compression link must be less than the flux linkage of the saturation reactor of the previous link: Ψ _1N <Ψ _1N-1 <... <Ψ ₁₂ <Ψ ₁₁ , (Ψ _2N <Ψ _2N-1 <. .. <Ψ ₂₂ <Ψ ₂₁ , Ψ _mN <Ψ _mN-1 <... <Ψ _m2 <Ψ _m1 ), which is achieved by the appropriate choice of parameters of the chokes (number of turns of the winding, dimensions and material of the cores, number of cores).

To ensure a delay time of the discharge of the capacitors of the last compression links C _1N , ..., C _mN to the magnetization coils of the inductors through the windings of the chokes L _1N , ..., L _{mN, the} saturation chokes have a flux linkage increasing with the number of the magnetic pulse generator: Ψ _1N <Ψ _2N <... <Ψ _mN . This is done: 1) by increasing the number of turns of the windings, 2) by increasing the cross section of the steel of the ferromagnetic cores, 3) by selecting the material of the cores with different magnitudes of the magnetic induction in steel, 4) by a combination of these methods.

The difference from the known technical solution is the application for the formation of the output ramp pulse voltage of the capacitors of the last compression links of magnetic pulse generators of different capacities: C _1N <kC _2N <... <kC _mN , where k = 1.1-2.

The discharge current pulse of the capacitor C _{1N of the} last compression link of the first magnetic pulse generator through the inductance of the winding of the saturation inductor L _1N and the inductance of the primary winding L _uc has a bell-shaped form. The flux linkage of the saturation inductor L _{2N of the} last compression link of the second magnetic pulse generator is selected so that the core saturation occurs at the maximum (or close to maximum) of the discharge current pulse of the first magnetic pulse generator. The magnitude of the flux linkage of the saturation inductor L _{mN of the} last compression link of the mth magnetic pulse generator is selected so that the core saturation occurs at the maximum (or close to maximum) of the discharge current pulse of the (m-1) th magnetic pulse generator. The superposition of the discharge current pulses of the capacitors of the last compression links of all magnetic pulse generators allows the formation of a high voltage transformer of a microsecond voltage pulse at the load.

The use of capacitors of different capacities in the last stages of compression of magnetic pulse generators and their discharge through the corresponding inductances of the windings of saturation chokes and the inductance of the primary winding of a high voltage pulse transformer leads to the formation of discharge currents of various amplitudes. Moreover, the fulfillment of the condition С _1N · L _1N ≈С _2N · L _2N ≈ ... ≈С _mN · L _mN allows for approximately equal duration of the discharge pulses of all magnetic pulse generators. The value of k determines the rate of growth of the output voltage during the pulse. At k = 1, a quasi-rectangular voltage pulse is formed (this case corresponds to the parameters of the elements of the prototype device), and for k> 2, the output voltage pulse of the generator has significant oscillations.

In the general case, the value of the discharge current of the capacitors of the last compression links through the windings of saturation chokes and the primary winding of the transformer for the ohmic load is determined by the following relation:

where L _iN is the inductance of the discharge circuit, including the inductance of the saturation inductor of the last compression link of the i-th magnetic pulse generator, the inductance of the magnetization coils of the inductors of the high-voltage pulse transformer, C _iN is the capacitance of the capacitor of the last compression link of the i-th magnetic pulse generator, U _CiN is the discharge capacitor voltage C _iN , R _load = R / N ² is the reduced load resistance, where N is the transformer transformation coefficient, R is the load resistance.

The duration of the discharge pulse With _iN through the inductance of the winding of the saturation inductor L _iN and the inductance of the magnetization coils of the inductors L _uc is:

For the generator to generate a voltage pulse with the smallest oscillation amplitude, it is necessary to ensure an approximate equality of the duration of the discharge pulses of individual magnetic pulse generators. This leads to the necessity of fulfilling the condition: С _1N · L _1N ≈С _2N · L _2N ≈ ... ≈C _mN · L _mN (follows from formula (9), and taking into account L _uc ≪L _1N , L _2N , ... , L _mN , which usually takes place in practice).

An example of a specific implementation of the invention is a generator of high-voltage ramp pulses of microsecond duration, made of three parallel-connected magnetic pulse generators. Magnetic pulsed generators consist of two compression links with the following element parameters: C ₁₁ = C ₁₂ = 0.123 · 10 ^-6 F, C ₂₁ = C ₂₂ = 0.188 · 10 ^-6 F, C ₃₁ = C ₃₂ = 0.282 · 10 ^-6 F. Thus, we choose the coefficient k = 1.5. Capacitors C ₁₁ , C ₁₂ , C ₂₁ , C ₂₂ , C ₃₁ , C ₃₂ with lumped parameters such as K75-74. Saturation chokes L ₁₁ , L ₂₁ , L ₃₁ have identical cores made of N ₁ = 2 rings with outer D _outer diameter 360 mm and inner D _inner diameter 150 mm, width h = 25 mm, wound from permalloy tape 50 NP 0.02 thick 0.02 mm

The high-voltage pulse transformer contains 14 ferromagnetic inductors with dimensions: external and internal diameters of 360 and 150 mm, width h = 25 mm, made of permalloy tape 50 NP 0.01 mm thick. A metal pipe is located along the axis of the inductors, on which the vortex EMF is summed. Inductors are covered by a single-turn primary winding. All elements of the generator are placed in a cylindrical stainless steel case with an inner diameter of 670 mm. Capacitors C ₁₁ , C ₂₁ , C ₃₁ are charged to U _C11 = U _C21 = U _C31 = 50 kV (<U> ≈25 kV for all compression links) from an external power source for a time interval Δt ₀ = 2 μs. In order to exclude the processes of energy transfer between the capacitors of the last compression units of magnetic pulse generators (to electrically decouple them), the number of compression units should be at least two. The magnitude of the flux linkage saturation chokes L ₁₁ , L ₂₁ and L ₃₁ should be:

The cross section of the steel cores of the saturation chokes L ₁₁ , L ₂₁ , L ₃₁ is:

where K = 0.8 is the fill factor of the core volume with steel, N ₁ = 2 is the number of rings from which the core of the saturation inductor is assembled.

To fulfill the equality in formula (10), i.e. to achieve complete energy transfer from the primary storage device to the capacitors of the first compression units, the number of turns in the windings of the saturation chokes L ₁₁ , L ₂₁ and L ₃₁ should be ω ₁₁ = 5. In this case, the inductance of the windings of the chokes L ₁₁ , L ₂₁ and L ₃₁ in the saturated state of the cores are equal to:

where a ₁₁ = 80 mm is the linear size of the winding, D _ext. = 380 mm, D _int. = 140 mm - the outer and inner diameters of the windings of saturation chokes.

The duration of the discharge time from C ₁₁ to C ₁₂ , C ₂₁ to C ₂₂ , C ₃₁ to C ₃₂ will be in accordance with (3): Δt ₁₁ = 0.49 μs, Δt ₂₁ = 0.61 μs, Δt ₃₁ = 0.75 μs.

The flux linkage of saturation chokes L ₁₂ , L ₂₂ and L ₃₂ should be:

where 0.3 μs and 0.6 μs is the delay in switching on the second and third magnetic pulse generators to the primary winding of the transformer.

If we use one core (N ₁₂ = 1) from a ring with an outer D _outer diameter of 180 mm and an inner D _inner diameter of 75 mm, a width of h = 25 mm, with a fill factor of steel core volume K = 0.8, wound to the core saturation inductor L ₁₂ , wound from permalloy tape 50 NP with a thickness of 0.02 mm, the cross section of the core steel will be:

To fulfill the equality on the left side of the first formula (13), the number of turns in the winding of the saturation inductor L ₁₂ must be at least ω ₁₂ = 5. The inductance of the inductor winding L ₁₂ in the saturated state of the cores is equal to:

where a ₁₂ = 40 mm is the linear size of the winding, D _ext. = 220 mm, D _int. = 50 mm - the outer and inner diameters of the winding of the saturation inductor.

The duration of the discharge pulse C ₁₂ through the inductance of the winding of the saturation inductor L ₁₂ and the inductance of the magnetization coils of the inductors L _uc (approximately 0.015 μH) will be:

The flux linkage of the saturation throttle L ₂₂ must exceed the flux linkage of the saturation throttle L ₁₂ to delay the discharge of the capacitor of the last compression link of the second magnetic pulse generator. If we use 3 ferromagnetic rings with the dimensions: outer and inner diameters of 180 and 75 mm, a width of 25 mm and apply a three-turn winding for the manufacture of a saturation inductor L ₂₂ , it allows you to delay the discharge pulse of the capacitor C ₂₂ by: Δt = 0.3 μs (see second equation (13)).

Thus, the second magnetic pulse generator is connected to the magnetization coils of the transformer inductors at about the maximum of the discharge current pulse of the first magnetic pulse generator.

The inductance of the inductor winding L ₂₂ in the saturated state of the cores is equal to:

where a ₂₂ = 90 mm, D _ext. = 220 mm, D _int. = 50 mm.

The duration of the discharge pulse C ₂₂ through the inductance of the winding of the saturation inductor L ₂₂ and magnetization turns L _uc will be:

i.e. approximately equal to Δt ₁₂ (formula (15)).

The third magnetic pulse generator increases the duration of the output pulse by another 0.3 μs. For this, the saturation inductor of the last compression link of the third magnetic pulse generator has increased flux linkage and is made of 6 ferromagnetic rings with a two-turn winding.

The inductance of the winding of the inductor L ₃₂ in the saturated state of the cores is equal to:

where a ₃₂ = 180 mm, D _ext. = 220 mm, D _int. = 50 mm.

The duration of the discharge pulse With ₃₂ through the inductance of the winding of the saturation inductor and the magnetization turns L _uc will be:

i.e., it is approximately equal to Δt ₁₂ and Δt ₂₂ (formulas (15) and (17)).

Thus, by choosing the parameters of saturation chokes (the number of cores and the number of turns of the windings) of the last compression links of the parallel-switched magnetic pulse generators, it is possible to delay their switching on to the primary winding of a high-voltage pulse transformer, as well as to realize different discharge inductance for an approximate equality of the duration of discharge processes . The use in the proposed generator of high voltage pulses of microsecond duration of capacitors of different capacities in the last compression links of magnetic pulse generators provides a different amplitude of the discharge current, which allows to obtain output pulses of a linearly increasing shape.

The calculation of the parameters of the output pulse of the generator with the parameters of the elements corresponding to those given in the example of a specific design was performed using the software product "Electronic Workbench". As a result of the successive discharge of the capacitors of the last compression links of three magnetic pulse generators at a load of 100 Ohms, a linearly increasing pulse is formed with an amplitude of 345 kV, a current of 3.45 kA, a duration of 1.5 μs at the base, with a leading edge of 0.9 μs and a trailing edge of 0.5 μs.

The number of magnetic pulse generators used in the generator of high-voltage linearly increasing pulses of microsecond duration is limited as follows. At the end of the discharge of the capacitor of the last compression link of the first magnetic pulse generator 3, the core of the saturation inductor L _1N is in a saturated state. When the second and third magnetic pulse generators 4.5 are turned on to the primary winding of the high-voltage pulse transformer through the winding of the saturation inductor L _1N , the demagnetizing current begins to flow under the influence of the potential difference at the terminals of the primary winding. The duration of the process of magnetization reversal of the throttle is limited by the magnitude of its flux linkage. In the considered example of a specific embodiment of the generator, the duration of the reverse magnetization reversal process depends on the shape of the voltage pulse at the terminals of the primary winding and is ~ 1.4 μs. Therefore, in the considered example of the generator, no more than three magnetic pulse generators (m≤3) can be connected.

Thus, the proposed generator of high-voltage linearly increasing pulses of microsecond duration implements an original idea related to the supply to the primary winding of a high-voltage pulse transformer of discharge pulses from several magnetic pulse generators switched on with the necessary time delay. To form linearly increasing pulses, capacitors of different capacities are used in the last compression links. In this case, the capacitance of the capacitors and the inductance of the windings of the saturation chokes of the last compression links must satisfy the condition: C _1N · L _1N ≈С _2N · L _2N ≈ ... ≈С _mN · L _mN .

Claims (1)

A generator of high-voltage linearly increasing pulses of microsecond duration, containing a high-voltage pulse transformer in the form of a set of ferromagnetic inductors covered by magnetization coils, the conclusions of the magnetization coils on each side of the inductors are interconnected and are electrically connected to the terminals of the last compression links m of magnetic pulse generators having N≥2 links compression formed by capacitors and saturation chokes, magnetic pulse generators are connected in parallel and have chokes saturation of the last compression links with different values of flux linkage, characterized in that the capacitors of the last compression links of the magnetic pulse generators are selected from the relation C _1N <kC _2N <... <kC _mN , where k = 1.1-2 and satisfy the condition C _1N · L _1N ≈C _2N · L _2N ≈ ... ≈C _mN · L _mN , where L _1N , L _2N , ..., L _mN are the inductances of the saturation chokes of the last compression links of the magnetic pulse generators.