RU2308144C2 - Method for controlling three-phased asynchronous electric motor of down-pump and system for controlling electric motor of down-pump - Google Patents

Abstract

FIELD: electric engineering, possible use for controlling three-phased asynchronous electric motors of down-pumps, used mainly for oil extraction.

SUBSTANCE: in the method for controlling the three-phased asynchronous electric motor of down- pump and in the system for controlling electric motor of down-pump in case of failure of frequency regulator or jamming of electric motor rotor, by means of mode switch, mode of direct launch from electric network is set. In that mode transfer of electric energy to electric motor occurs via chain: three-phased electric network - increasing voltage transformer - three-phased asynchronous electric motor. The control system contains a frequency control circuit and direct launch circuit, first key, connected to frequency controller and controlling feeding of power to it; input and output filters, second key, by means of which control modes are switched, third key, controlled by controller, and transformer which increased power voltage of electric motor.

EFFECT: increased efficiency.

2 cl, 4 dwg

Description

The invention relates to the control of three-phase asynchronous electric motors of submersible pumps, used mainly for oil production.

A widely used method of controlling three-phase asynchronous electric motors of submersible pumps, which consists in controlling a three-phase asynchronous electric motor using a frequency controller and allowing you to adjust the rotational speed of the rotor of the electric motor.

The described control method is implemented in the control station of three-phase asynchronous electric motors of the Elekton-05 series (see Fig. 1, 2 manufactured by ZAO Elektron, Raduzhny, Vladimir Region, TsTKD 065 RE), which contains a frequency controller and a control system. The frequency regulator allows you to adjust the frequency of rotation of the rotor of the electric motor. The control system allows you to set operating modes and control the operation of the frequency controller.

The closest analogue, shown in figure 2, contains the input terminals VhK for connecting a three-phase electric network, a circuit breaker K, which controls the power supply to the frequency controller of the PD and provides protection against short circuit in the circuit of the PD. The controller Counter1, which is included in the circuit, provides control of the frequency controller of the PD, as well as control of parameters such as the voltage of the three-phase electric network Uc and the current of the power circuit of the frequency controller. Controller Counter2 is designed to interact with the user; VykhK output terminals are designed to connect the device with a step-up transformer and further with a three-phase asynchronous motor.

The disadvantage of the described method and device for its implementation is the inability to control the motor in case of failure of the frequency controller or when it is impossible to start the motor using the frequency controller, for example, when the motor rotor is jammed.

The purpose of the proposed technical solution is to provide the ability to control a three-phase asynchronous motor using a frequency controller, as well as directly from the electric network while maintaining the ability to control when the frequency controller fails or the motor cannot be started using the frequency controller, while this method is easy to implement in the device.

This goal is achieved by the introduction of an additional motor control mode - direct start mode, directly from the electrical network.

The described mode is implemented in the device by including an additional direct-start circuit in the circuit, consisting of conductors that transmit electricity bypassing the frequency regulator and a three-phase induction motor control mode switch, by which either the control mode using the frequency regulator or the direct start mode is set.

A method for controlling an induction motor is illustrated in FIG. In normal operation, using the control mode switch, the motor control mode is set using the frequency controller. In this mode, electric power is transferred to the electric motor through the circuit: three-phase electric network, frequency regulator 1, step-up voltage transformer 2, three-phase asynchronous electric motor 3. In the event of an emergency mode, for example, if the frequency regulator 1 fails or the rotor of the electric motor 3 is jammed, using the switch control modes 4 set the direct start mode from the mains. In this mode, electric power is transferred to the electric motor bypassing the frequency regulator along the circuit: three-phase electric network, step-up voltage transformer 2, three-phase asynchronous electric motor 3.

A device for implementing the above-described method for controlling a three-phase asynchronous electric motor — a submersible pump electric motor control system — is illustrated in FIG.

The device contains input terminals 5 for connecting a three-phase electric network, a key 6, which controls the supply of power to the frequency controller 1; an input filter 7, which serves to reduce the influence of the frequency controller 1 on a three-phase electrical network; output filter 8, which serves to protect the three-phase asynchronous motor 3 from high voltage spikes that occur during operation of the frequency regulator; circuit switch - key 4, used to switch control modes of a three-phase asynchronous motor; a key 9 controlled by the controller 10 and designed to turn off the electric motor in the event of an emergency; output terminals 11, designed to connect the device with a step-up transformer 2, designed to increase the voltage of the electric motor to 2.5 kV, and then with a three-phase asynchronous motor.

The device operates as follows.

In normal mode, the key 4 is set to the "Frequency control" position, and the key 6 is closed. In this mode, the motor is controlled through the frequency regulator. The controller sets the operating mode of the frequency controller, controls the electrical parameters - voltage of a three-phase electric network (Uc) and, using current sensors - the current consumption of the electric motor (Id), and also controls the key 9.

In case of failure of the frequency regulator or when it is impossible to start the electric motor through the frequency regulator, key 4 is set to the "Direct start" position, and key 6 is opened and the power supply to the frequency regulator is turned off. In this mode, the controller controls the electrical parameters - the voltage of the electric network (Uc) and the current consumption of the electric motor (Id), and also controls the key 9.

Claims (2)

1. A method for controlling a three-phase asynchronous submersible pump electric motor, including controlling the rotational speed of the electric motor in normal operation of the frequency regulator, characterized in that in the event of an emergency mode, the “direct start” position is set using the control mode switch, and the power supply to the frequency regulator is turned off and the mode is set direct start of a three-phase asynchronous electric motor from the mains. 2. A submersible pump electric motor control system containing a frequency regulator, a key controlling the supply of power to the frequency regulator from a three-phase electric network, increasing a voltage transformer of a three-phase asynchronous electric motor, characterized in that a key is entered for switching control modes of a three-phase asynchronous electric motor, which is normal operating mode provides electric power transmission along the circuit: three-phase electric network, frequency regulator, increasing t voltage descriptor, three-phase asynchronous motor, and in emergency mode, through the circuit: three-phase electric network, step-up voltage transformer, three-phase asynchronous electric motor, controller for opening the key that controls the power supply to the frequency controller, and disconnecting the three-phase asynchronous electric motor in emergency mode by means of the key, designed to turn off the electric motor.

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