RU2498351C1 - Pulsed electromagnetic drive for seismic vibrator - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: electromagnetic drive has a capacitive storage and a power electromagnet, the excitation coil of which is dual-section. A current switching circuit enables rapid change of duration of the force generated by the electromagnet and recuperation of energy from the magnetic field into the capacitive storage, which improves process and operational characteristics of the seismic vibrator.

EFFECT: improved functional capabilities of the device.

3 dwg

Description

The invention relates to the field of pulsed electromagnetic drives used in pulsed seismic sources intended for seismic exploration, and can be used in other industrial technological objects when it is required to create pulsed or periodically repeating force effects on the working fluid.

A known seismic source pulse drive containing an electromagnet with an excitation winding, an electric capacitor is an energy storage device with a charger, a controlled switching device, such as a thyristor, for discharging a capacitor to an excitation winding of an electromagnet that is shunted by a diode (Ivashin V.V., Ivannikov N.A. Pulsed electromagnetic seismic sources: features and prospects for improvement // Instruments and systems for exploration geophysics. - Saratov: 2005. - No. 2. - p. 9-13).

As a result of the discharge of the capacitor through the thyristor, a magnetic flux is created in the electromagnet, and the diode provides shunting of the electromagnet winding. The drive provides the formation of the duration of the force, determined by the time of choosing the gap between the armature and the inductor of the electromagnet.

The disadvantage of the analogue is the impossibility of operational control of the duration of the force generated by the drive, which does not allow you to control the duration of the mechanical effect of the seismic source on the soil and narrows the scope of its application. Thermal energy losses in the electromagnet winding reduce the force generated by the electromagnet and the conversion factor of the energy consumed from the charger into the mechanical energy generated by the electromagnet. In the time interval by which the electromagnet selects the gap due to losses in the winding, there is a decrease in the force created by the electromagnet. After choosing the gap, the energy remaining in the magnetic field is released in the excitation winding, which increases its heating and reduces the maximum value of the possible frequency of repetition of force effects.

Known adopted for the prototype pulse drive of an electromagnetic seismic source (patent No. 2398247 from 04.15.2009), containing a power electromagnet with an excitation winding, a shunt diode and a capacitor - energy storage device with a charger. The capacitor is connected to the field winding through a controlled switching device, such as a thyristor, and a inductor winding.

The principle of operation of the drives according to the analogue and prototype differs in that the inclusion in the circuit of the prototype of the inductor winding in series with the field winding and bypassing this winding with a diode can increase the average value of the force generated by the electromagnet and, consequently, increase the developed mechanical power.

The disadvantage of the prototype is the impossibility of operational control of the pulse duration of the force, large heat losses in the field winding and a low coefficient of conversion of energy consumed from the charger into the mechanical energy of the drive, which reduces the efficiency of the drive and the seismic capabilities of the seismic source.

The task to which the invention is directed is to increase the efficiency of the drive of an electromagnetic seismic source and expand the field of its practical application.

The technical result is the ability to quickly change the duration of the current pulse in the excitation winding of the electromagnet and the force it creates, reduce the power consumed by the seismic source from the primary power source, and make it possible to increase the maximum repetition frequency of the force pulses created by the drive.

The task is achieved in that the pulsed electromagnetic drive contains an electric capacitor - an energy storage device with a charger, a power electromagnet with an excitation winding located in the groove of its magnetic circuit and a controlled switching device with an inductor winding in the capacitor discharge circuit to the electromagnet excitation winding, the inductor and electromagnet windings are made two-section, one capacitor terminal is connected to a common point of the serially connected sections of the electromagnet winding, WTO A swarm of its output through a controlled switching device and one of the sections of the inductor winding is connected to the beginning of one of the sections of the electromagnet winding and through the first diode and the second section of the inductor winding is connected to the end of the second section of the electromagnet winding, and a second diode is connected in parallel to the capacitor.

Changing the time delay between the opening and closing moments of the controlled switching device allows you to change the pulse duration of the magnetic field of the electromagnet and the duration of the force generated by the drive, which increases the technical capabilities of the seismic source and its scope.

From the moment the controlled switching device is turned off, the magnetic field and the inductor are not converted into mechanical energy of the magnetic field and the inductor into the electric energy of the capacitor, which leads to a decrease in energy losses and heating of the excitation coil of the electromagnet and the necessary electric power consumed by the drive from the primary power source.

The invention is illustrated by drawings. Figure 1 shows a drive circuit with a power electromagnet, figure 2 shows the timing diagrams of its operation, and figure 3 - electrical equivalent circuit.

The pulse electromagnetic drive of the seismic source (figure 1) contains an electric capacitor 1 (energy storage) with a charger 2, a power electromagnet consisting of an armature 3 separated by a gap and an inductor magnetic circuit 4. Sections 5 and 6 of the field winding are placed in the groove of the magnetic circuit 4. The common point of the sections 5 and 6 connected in series is connected to the terminal of the capacitor 1, the second terminal of which is connected to the terminal of section 5 through the controlled switching device 7 and section 8 of the inductor winding, and through the section 9 of the inductor and diode 10 - with the conclusion of the section 6 of the excitation coil of the electromagnet (Fig.2 and 3). Parallel to the capacitor 1, a diode 11 is connected.

The drive operates as follows. In the initial state, the capacitor 1 is charged from the charger 2 to the nominal value of the indicated polarity and the necessary electric energy is stored in it. At time t _0, a controlled device 7, for example, a thyristor, opens from the control circuit (not shown in FIG. 1), and the capacitor is discharged through the device 7, the choke section 8 and the electromagnet field winding section 5. When this current 12 of the discharge of the capacitor increases, and the voltage 13 on the capacitor decreases (figure 2). The flow of current through section 5 of the winding and section 8 of the inductor is accompanied by the creation of the corresponding magnetic fluxes in the inductor and electromagnet. The magnetic flux generated during the passage of the discharge current 12 through section 5 passes through the gap 5 between the magnetic circuits 3 and 4 of the armature and the inductor, and an electromagnetic force is created between them

proportional to the decrease in the magnetic energy A _{δ of the} gap when it changes x. When the capacitor 1 is discharged, a reverse voltage is applied to the diode 10, equal to the sum of the voltage 13 on the capacitor and the voltage induced on section 6 when the discharge current of the capacitor 1 passes through section 5 located in the groove along with section 6. At time t ₁ , by reducing voltage across the capacitor 1 and section 6, the sign of the voltage on the diode 10 changes, and it opens, providing a short circuit of the series-connected sections 5 and 6 through sections 8, 9 of the inductor, diode 10 and device 7.

When decreasing the voltage 13 on the capacitor to zero, the diode 11 opens, which eliminates the possibility of changing the sign of the voltage 13 on the capacitor and ensures the closure of section 5 with a current of 12 in it through the diode 11 (Fig.3).

On the interval t ₁ -t ₂ there is a process of equalization of current 12 in section 5 and current 14 in section 6. The duration of the interval t ₁ -t ₂ depends on the resistances R ₁ and R _{2 of} sections 5 and 6 (figure 3), their scattering inductances and the EMF of the movement induced in sections 5 and 6 with a decrease in the gap δ between the armature 3 and the inductor 4 of the electromagnet. In the process of equalizing the currents 12 and 14 in sections, the current 15 in the diode 11 decreases to zero, and it closes.

By the time t _{k, the} gap δ of the electromagnet is completely selected. Moreover, the main part of the gap is selected during the time t _l -t _k when sections 5 and 6 are shorted through sections 5 and 6 of the inductor winding and devices 7 and 10.

The conversion of magnetic field energy A _δ into mechanical energy when choosing the gap δ is accompanied by a decrease in the total magnetizing force of the sections of the windings 5 and 6. In this case, part of the energy of the magnetic field of the inductor is transferred to the energy of the magnetic field of the electromagnet, which provides compensation for energy losses in the resistances R ₁ and R _{2 of the} sections 5 and 6 and an increase in the average value of the force 16 created by the electromagnet (FIG. 2).

With an increase in the discharge current of the capacitance in the interval t ₀ -t _{1, the} generated force P (t) is proportional to the quadratic value of current 12 and, accordingly, the quadratic value of magnetic induction in the gap δ. On the interval t _l -t _{k the} induction of the field in the gap and, accordingly, the generated force 16 are maintained at close to maximum level.

At time t _{k, the} device 7 is turned off by a signal from the control system. In this case, current 12 in section 5 decreases to zero, and current 14 of section 6 begins to flow through capacitor 1. From moment t _k , the recovery (transmission) of the energy of the magnetic field of the electromagnet to the capacitor 1 begins ending at the time t _{3 of the} closing of the diode 10 when the current 14 decreases to zero. The reduction of the recovery time and, accordingly, the trailing edge of the force pulse is provided by reducing the ratio of the number of turns w _{2 of} section 6 and the number of turns w _{1 of} section 5 of the electromagnet field coil. With decreasing w ₂ , the maximum value of the current 14 induced in section 6 when the current 12 in section 5 is turned off at time t _k is turned off. The ratio of the number of turns in sections 8 and 9 of the inductor winding is equal to the ratio of the number of turns in sections 5 and 6 of the electromagnet excitation winding.

The ability to control the duration of the force generated by the electromagnet 16 is achieved by reducing the delay t ₀ -t _k to close the device 7.

After the formation of the force pulse, the capacitor 1 is recharged from the voltage on it at the time t _{3 of the} end of the recovery to the nominal value, after which the drive is ready to create another force pulse.

Thus, the proposed pulse electromagnetic drive allows you to quickly, that is, during the operation of the seismic source, change the duration of the generated force, provide an increased average value of the generated force and reduce the electric power required for the seismic source to work, which increases the efficiency of the pulse seismic source drive and expands its application .

The drive provides energy recovery of the magnetic field of the power electromagnet to the capacitor 1 - capacitive energy storage, reducing the time of the trailing edge of the excitation current of the electromagnet and, accordingly, the force created by it. This feature allows you to increase the limit value of the repetition rate of the force and apply the drive in the design solutions of the code-pulse type seismic sources, which provide the use of more effective methodological methods for processing seismic information.

The use of the proposed drive, which allows you to create power effects with adjustable frequency and magnitude of force, can be effective in vibration-impulse devices for industrial applications, for example, in vibration compactors of concrete building products, and other cases.

Claims (1)

A pulse electromagnetic drive of a seismic source, containing an electric capacitor-energy storage device with a charger, a power electromagnet with an excitation winding located in the groove of its magnetic circuit and a controlled switching device with a choke winding in the capacitor discharge circuit to the excitation winding, characterized in that the choke and electromagnet windings are made of two sections , one terminal of the capacitor is connected to a common point in series sections of the electromagnet winding, its second terminal is through a controlled switching device and one of the sections of the inductor winding is connected to the beginning of one of the sections of the electromagnet winding and through the first diode and the second section of the inductor winding is connected to the end of the second section of the electromagnet winding, and a second diode is connected in parallel to the capacitor.