RU2538222C2 - Method to control flow rate of electroconducting liquid pumped by linear conduction pump - Google Patents

Abstract

FIELD: engines and pumps.

SUBSTANCE: highly coercitive permanent magnet 2 of cylindrical shape is placed inside a cylindrical shell 1 of a pump from ferromagnetic material. In the circular channel of the working zone of the pump they install a flat insulating plate 3 and tightly fixed to the shell 1 and the permanent magnet 2. The main pair 4 of DC electrodes is installed symmetrically on opposite sides of the flat insulating plate in the zone of a single pole of a magnet, and an additional pair 5 of DC electrodes - in the zone of the opposite pole of the magnet. A period of regulation of electroconducting liquid supply to a user is set, and the main and additional pairs of electrodes are connected to appropriate controlled sources 13 and 14 of DC voltage. DC voltage is supplied to the additional pair of electrodes in the form of pulses with a fixed period, which is smaller than the regulation period, and duty factor close to one. During a pause, using an additional pair of electrodes, they measure electromotive force in the electroconducting liquid, and on the basis of the electromotive force value they calculate the flow rate of the pumped fluid. The liquid flow rate is stabilised by means of correction of DC voltage value on the main pair of electrodes and/or on the additional pair of electrodes.

EFFECT: supply of electroconducting liquid to a user is carried out with continuous and accurate flow rate in each period of regulation.

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Description

The invention relates to MHD technology and can be used in pumping units for pumping electrically conductive liquids.

A known method of mixing liquid metal in the mold during continuous casting (RF Patent No. 2043839, B22D 11/10, 1992), comprising transmitting a constant electric current in a direction perpendicular to the axis of drawing of the ingot, and the effect of a constant magnetic field that is crossed with the direction of transmission electric current, and electric current is passed under the meniscus of the metal in the mold, and the magnetic field is created by magnets located above the meniscus of the metal.

The disadvantage of this method is the low accuracy due to the implementation of the process in an open control system and the lack of regulation.

Closest to the claimed method is "Methods using high-energy permanent magnets for electromagnetic injection, braking and dosing of molten metals supplied to casting machines" (RF Patent No. 2291028, B22D 11/10, Н02К 44/02, 2002), adopted for the prototype, which consists in using a highly coercive permanent magnet to create a magnetic flux in the working area in the direction perpendicular to the direction of movement of the pumped electrically conductive liquid, in the main location in the working area th pair of DC electrodes with the possibility of galvanic connection with the pumped conductive fluid to provide direct current in the conductive fluid in the perpendicular direction both with respect to the direction of magnetic flux in the working area, and with respect to the direction of movement of the pumped conductive fluid, as well as in the placement in the working area of an additional pair of DC electrodes with the possibility of galvanic connection with the pumped conductive fluid for n continuous measurement of the emf arising under the influence of magnetic flux in the pumped conductive fluid.

The disadvantage of this method is explained by the impossibility of ensuring the required accuracy of controlling the flow rate of the electrically conductive liquid in an open system, low efficiency, determined by the significant dispersion of the magnetic flux, as well as the complexity of implementation.

The technical result of the proposed method is to increase the efficiency and accuracy of controlling the flow of conductive fluid pumped by a linear conductive pump.

The technical result is achieved by the fact that in the method of controlling the flow rate of the electrically conductive fluid pumped by a linear conductive pump, including creating a magnetic flux in the pump working area in a direction perpendicular to the direction of movement of the pumped electrically conductive fluid by means of a highly coercive permanent magnet, placing the main pair of DC electrodes with the possibility of their galvanic connection with the pumped conductive fluid to ensure constant current in an electrically conductive fluid in a perpendicular direction both with respect to the direction of magnetic flux in the working area, and with respect to the direction of movement of the pumped conductive fluid, the placement in the working area of an additional pair of DC electrodes with the possibility of galvanic connection with the pumped conductive fluid for continuous Measurement of the emf arising under the influence of magnetic flux in the pumped conductive fluid using a highly coercive pos a thawed magnet of a cylindrical shape with a chemically inert heat-resistant insulating outer shell and a highly coercive permanent magnet is placed coaxially inside the cylindrical shell of the pump, which is made of ferromagnetic material and equipped with a chemically inert heat-resistant insulating shell on its inner surface, a flat insulating plate is introduced into the annular channel of the working area, placed it is in a plane bounded by the axis of the pump and the radius of the shell, and tightly attached to the shell and highly coercive for a permanent magnet, the main pair of DC electrodes is installed symmetrically on opposite sides of a flat insulating plate in the area of one pole of a high-coercive permanent magnet, and an additional pair of DC electrodes is installed symmetrically on opposite sides of a flat insulating plate in the area of the opposite pole of a high-coercive permanent magnet, the control period is set supplying the pumped conductive fluid to the consumer and connect the main steam DC electrodes and an additional pair of DC electrodes to the respective regulated DC voltage sources, and an additional pair of DC electrodes is supplied with a constant voltage in the form of pulses with a fixed period of less than the regulation period and a duty cycle close to unity, and during a pause, use an additional pair of DC electrodes for periodic measurement of the emf arising under the influence of magnetic flux in the pumped electric wire of the liquid, by the magnitude of the emf, the flow rate of the pumped conductive fluid is calculated and the flow rate of the pumped conductive fluid is stabilized by correcting the DC voltage on the main pair of DC electrodes and / or on the additional pair of DC electrodes, and the supply of conductive fluid to the consumer is carried out at a constant flow rate in each period control in the form of an impulse with a duration of less than or equal to the period for regulating the supply of pumped electric bottom of the liquid.

Figure 1 shows a block diagram of a device that implements the proposed method by the flow of conductive fluid pumped by a linear conductive pump.

 A cylindrical linear conduction pump contains an annular channel formed by a shell 1 and a cylindrical highly coercive permanent magnet 2, a flat insulating plate 3, a main pair of DC electrodes 4 and an additional pair of DC electrodes 5.

The shell 1 is made of ferromagnetic material for concentration and uniform distribution of magnetic flux in the annular channel.

The flat insulating plate 3 is placed in the annular channel in a plane bounded by the axis of the cylindrical linear conduction pump and the radius of the shell 1, and is tightly attached to the shell 1 and the cylindrical highly coercive permanent magnet 2, forming a longitudinal partition in the annular channel that prevents the flow of shunt currents between the electrodes as the main pairs of DC electrodes 4, and an additional pair of DC electrodes 5.

The main pair of DC electrodes 4 is mounted symmetrically on opposite sides of a flat insulating plate 3 in the area of one pole of a cylindrical highly coercive permanent magnet 2, for example, in the area of the north pole

An additional pair of electrodes 5 is mounted symmetrically on opposite sides of a flat insulating plate 3 in the area of the opposite pole of the cylindrical highly coercive permanent magnet 2, for example in the area of the south pole

The outer surface 6 of the cylindrical highly coercive permanent magnet 2 and the inner surface 7 of the shell 1 have a chemically inert heat-resistant insulating shell, and the length of the flat insulating plate 3 to minimize shunt currents between the electrodes of both the main pair of DC electrodes 4 and the additional pair of DC electrodes 5 should satisfy the condition

$$L_P>L_M+\pi \cdot D_O-{\delta }_P.\left(\mathrm{one}\right)$$

where L _P - the length of the flat insulating plate, m,

L _M - the length of the cylindrical highly coercive permanent magnet, m,

D _O - inner diameter of the shell, m,

δ _P - the thickness of the flat insulating plate, m

The control system of a cylindrical linear conduction pump contains a control unit 8, to the first input of which the first output of the driver unit 9 is connected, the second output connected through the correction unit 10 to the second input of the control unit 8. The first output of the computing unit 11 connected to the third input of the control unit 8 the second output with the second input of the correction unit 10, and the first output of the measuring unit 12 is connected to the input of the computing unit 11. The first output of the control unit 8 is connected to the input of the first control voltage source 13, and the second output of the control unit 8 is connected to the first input of the second adjustable DC voltage source 14, to the second input of which the second output of the measuring unit 12 is connected.

The electrodes of the main pair of DC electrodes 4 are connected to the corresponding outputs of the first regulated DC voltage source 13 by buses 15.

The electrodes of an additional pair of DC electrodes 5 are connected to the corresponding outputs of the second adjustable DC voltage source 14 by buses 16 and to the corresponding inputs of the measuring unit 12 by buses 17.

The method is as follows.

Since the direction of the magnetic flux generated by the opposite poles of the cylindrical highly coercive permanent magnet 2 in the zones of the poles is mutually opposite, the polarity of the voltage supplied to the main pair of electrodes 4 should be the opposite polarity of the voltage supplied to the additional pair of electrodes 5. In this case, the forces arising from the interaction of currents flowing in an electrically conductive liquid with a magnetic flux in the zones of different poles of a cylindrical highly coercive permanent magnesium and 2 will have the same direction.

At the beginning of each control period for the supply of the pumped conductive fluid to the consumer, the control unit 8 sets the required constant voltage values at the outputs of the first constant voltage source 13 and the second constant voltage source 14.

As a result, ring currents appear in the annular channel of the pump, which, when interacting with the magnetic flux, produce a tractive force acting on the electrically conductive fluid.

The presence of a flat insulating plate 3 and chemically inert heat-resistant insulating shells at the shell 1 and a cylindrical highly coercive permanent magnet 2 can significantly reduce the level of shunt currents between the electrodes of both the main pair of DC electrodes 4 and the additional pair of DC electrodes 5, which increases the efficiency of the pump .

The master unit 9 determines for the control unit 8 the necessary flow rate of the pumped conductive fluid, as well as its volume in each regulation period, controlled by the correction unit 10. The current values of the flow rate and volume of the pumped conductive fluid is calculated by the computing unit 11 from the information about the magnitude of the emf occurring in the moving the magnetic field of the electrically conductive liquid and controlled by the measuring unit 12.

To implement the process of measuring the emf, the measuring unit 12, acting on the second DC voltage source 14, provides its periodic short-term disconnection from the electrodes of an additional pair of DC electrodes 5, which allows the use of an additional pair of DC electrodes 5 for measuring the EMF, practically without reducing traction pump, since the duty cycle of the pulses of constant voltage at the outputs of the second source of constant voltage 14 is set close to unity.

The control unit 8 stabilizes the flow rate of the pumped conductive fluid by correcting the DC voltage on the main pair of DC electrodes 4 and / or on the additional pair of DC electrodes 5, and the correction unit 10 provides the required volume of conductive fluid in each regulation period, after which it stops DC voltage supply to the electrodes of the main pair of DC electrodes 4 and an additional pair of DC electrodes 5. In this case, the control unit Phenomenon 8 stores in memory the steady-state values of the supply voltage at the outputs of the first constant voltage source 13 and the second constant voltage source 14 until the start of the next period for regulating the supply of electrically conductive liquid to the consumer, after which the control process resumes.

In stationary mode, the pulse duration of the electrically conductive liquid supplied to the consumer is constant and cannot exceed the duration of the regulation period, and if necessary, monitor the technological parameters (for example, the air temperature in the room, where the cylindrical linear conductive pump can function as a circulation pump of the heating system), the pulse duration changes with a constant regulatory period. As a result, a conductive fluid with a stable flow rate and in the required volume, i.e. with high precision.

Control of technological parameters can be carried out using the master unit 9.

Thus, the implementation of the proposed method allows to provide high accuracy and control efficiency of a cylindrical linear conduction pump.

Claims (1)

A method of controlling the flow rate of an electrically conductive fluid pumped by a linear conductive pump, including creating a magnetic flux in the pump working area in a direction perpendicular to the direction of movement of the pumped electrically conductive fluid, by means of a highly coercive permanent magnet, placing in the working area the main pair of DC electrodes with the possibility of galvanic connection with the pumped conductive fluid to provide direct current in the conductive fluid in the perp in the direction both with respect to the direction of magnetic flux in the working area and with respect to the direction of movement of the pumped conductive fluid, the placement in the working area of an additional pair of DC electrodes with the possibility of galvanic coupling with the pumped conductive fluid for continuous measurement of the emf arising under the action magnetic flux in the pumped conductive fluid, characterized in that they use a highly coercive permanent magnet of the cylinder a shape with a chemically inert heat-resistant insulating outer shell and a highly coercive permanent magnet is placed coaxially inside the cylindrical shell of the pump, which is made of ferromagnetic material and equipped with a chemically inert heat-resistant insulating shell on its inner surface, a flat insulating plate is introduced into the annular channel of the working zone, placed in a plane bounded by the axis of the pump and the radius of the shell, and tightly attached to the shell and highly coercive permanent magnet about the main pair of DC electrodes is mounted symmetrically on opposite sides of the flat insulating plate in the area of one pole of the high-coercive permanent magnet, and an additional pair of DC electrodes is installed symmetrically on opposite sides of the flat insulating plate in the area of the opposite pole of the high-coercive permanent magnet, the period for controlling the flow of the pumped electrically conductive liquid is set to the consumer and connect the main pair of constant electrodes current and an additional pair of DC electrodes to the respective regulated DC voltage sources, and an additional pair of DC electrodes is supplied with a constant voltage in the form of pulses with a fixed period of magnitude shorter than the regulation period and a duty cycle close to one, and during a pause an additional pair is used DC electrodes for periodically measuring the emf arising under the influence of magnetic flux in the pumped conductive fluid other emfs calculate the flow rate of the electrically conductive fluid being pumped and stabilize the flow rate of the electrically conductive fluid being pumped by correcting the dc voltage on the main pair of dc electrodes and / or on the additional pair of dc electrodes, and the electrically conductive fluid is supplied to the consumer at a constant flow rate in each regulation period in the form of a pulse a duration less than or equal to the period for regulating the supply of the pumped conductive fluid.