CN111244999A - Hybrid energy consumption device and control method thereof - Google Patents

Abstract

The invention relates to a hybrid energy consumption device and a control method thereof, wherein the hybrid energy consumption device comprises a centralized energy consumption device and a distributed energy consumption device which are connected in parallel at a direct current line end; the centralized energy consumption device and the distributed energy consumption device can be put into operation independently or simultaneously. The invention inherits the stable direct current voltage of the distributed energy consumption device during the fault period, reduces the current-resistant through-current capacity of the semiconductor device of the distributed energy consumption device by introducing the centralized energy consumption device, and reduces the cost of the energy consumption device.

Description

Hybrid energy consumption device and control method thereof

Technical Field

The invention relates to the technical field of high-power electronic current transformation, in particular to a hybrid energy consumption device and a control method thereof.

Background

The flexible direct current transmission system has self-turn-off capability, does not need additional commutation voltage, overcomes the fundamental defect that the receiving end of the traditional high-voltage direct current system must be an active network, and becomes an excellent solution for island power transmission and offshore wind power transmission. In a flexible direct current transmission system, after an alternating current system fault occurs in a receiving end system, the power of a sending end system cannot be sent out during the fault, so that the voltage of a direct current line is increased, and the insulation level of the equipment of the whole system is seriously tested. The energy consumption device is used as important equipment of the flexible direct current transmission system, and plays a role in consuming energy which cannot be borne by a receiving end system so as to protect the equipment of the whole system.

At present, energy consumption devices are divided into an alternating current energy consumption device and a direct current energy consumption device. The alternating current energy consumption device is mainly used for consuming surplus power by applying a braking resistor on an alternating current side when a direct current transmission line fails. When the scheme is applied to an offshore platform, great economic cost is increased, and the scheme is not suitable for an offshore flexible direct current transmission system. The direct current energy consumption device is mainly divided into a centralized energy consumption device and a distributed energy consumption device. The centralized energy consumption device consists of energy consumption branches and energy consumption resistors, and the energy consumption resistors are switched after the DC voltage is detected to be increased to bear surplus power consumption, but the centralized energy consumption device cannot keep the stability of the DC voltage in the switching stage; the distributed energy consumption device can still keep the stability of direct current voltage at the input stage of the energy consumption device and has high performance, but the distributed energy consumption device is composed of a large number of sub-modules, each sub-module contains a semiconductor IGBT device, and the cost of the distributed energy consumption device is increased to a certain extent due to the high price of the IGBT.

Disclosure of Invention

In view of the above, an objective of the present invention is to provide a hybrid energy consumption device and a control method thereof, which inherit that a distributed energy consumption device can stabilize a dc voltage during a fault period, and reduce a current-resistant current capacity of a semiconductor device of the distributed energy consumption device by introducing a centralized energy consumption device, thereby reducing a cost of the energy consumption device.

The invention is realized by adopting the following scheme: a hybrid energy consumption device comprises a centralized energy consumption device and a distributed energy consumption device which are connected in parallel at a direct current line end; the centralized energy consumption device and the distributed energy consumption device can be put into operation independently or simultaneously.

Furthermore, the centralized energy consumption device is composed of energy consumption branches and energy consumption resistors, and the energy consumption branches are formed by connecting at least one energy consumption submodule in series in the same direction.

Furthermore, the distributed energy consumption device is composed of a plurality of voltage-sharing energy consumption modules (energy consumption sub-modules), the voltage-sharing energy consumption modules are connected in series, and each energy consumption sub-module is composed of an energy consumption unit, an energy storage unit and a controllable switch.

Further, the designed rated power of the distributed energy consumption device is larger than 2/3 rated power of the system, and the designed rated power of the centralized energy consumption device is larger than 1/3 rated power of the system.

The invention also provides a control method of the hybrid energy consumption device, when the voltage of the direct current line is higher than a preset value, the hybrid energy consumption device is preferentially selected to be put into the distributed energy consumption device; when the distributed energy consumption device can not completely consume the redundant energy, the centralized energy consumption device is simultaneously put into use.

Further, the method comprises the following steps:

step S1: real-time detection of DC line voltage U_dlWhen the receiving end AC system is in fault, the voltage of the DC line rises, and surplus power P consumed by the energy consumption device is calculated_loss；

Step S2: when the DC voltage U is detected_dlWhen the operation threshold value is increased and is larger than the action threshold value of the distributed energy consumption device, the distributed energy consumption device is put into the distributed energy consumption device according to the surplus power;

step S3: judgment of P_lossRated power P of system₀If P is a relationship between_loss/P₀<2/3, only the distributed energy consumption devices need to be put into use; if P_loss/P₀>2/3, the distributed energy consuming devices and the centralized energy consuming devices are simultaneously put into operation.

Further, the voltage of the direct current line is monitored in real time, when the voltage of the direct current line is normal, the distributed energy consumption device is precharged, and after the precharging is completed, the distributed energy consumption device is in a hot standby state.

Furthermore, when the most common single-phase fault occurs in the receiving-end alternating-current power grid, only the distributed energy consumption devices are put into use; when a serious alternating-current two-phase fault or three-phase fault occurs in a receiving-end alternating-current power grid, a distributed energy consumption device and a centralized energy consumption device are simultaneously put into use, and the centralized energy consumption device can bear energy which needs to be consumed.

Compared with the prior art, the invention has the following beneficial effects:

1. the device and the method adopt a method of combining the distributed energy consumption device and the centralized energy consumption device, the device inherits that the distributed energy consumption device can stabilize direct-current voltage during the fault period, and the current-resistant through-current capacity of the semiconductor device of the distributed energy consumption device is reduced by introducing the centralized energy consumption device, so that the cost of the energy consumption device is reduced;

2. the control method of the device distinguishes different input modes aiming at different types of alternating current system faults, reduces the current endurance capacity of the distributed energy consumption device by utilizing the rapid energy consumption characteristic of the centralized energy consumption device, and greatly reduces the cost of the energy consumption device.

Drawings

FIG. 1 is a schematic diagram of a system according to an embodiment of the present invention.

Fig. 2 is a common sub-module topology of a distributed energy consumption device according to an embodiment of the present invention.

Fig. 3 is a centralized energy consumption device topology according to an embodiment of the invention. In the figure, 1 is an energy consumption branch, 2 is an energy consumption module, 3 is an energy consumption resistor, 4 is a bypass switch, 5 is a charging bypass resistor, 6 is a charging switch, and 7 is an isolating switch.

Detailed Description

The invention is further explained below with reference to the drawings and the embodiments.

It should be noted that the following detailed description is exemplary and is intended to provide further explanation of the disclosure. Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs.

It is noted that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of example embodiments according to the present application. As used herein, the singular forms "a", "an" and "the" are intended to include the plural forms as well, and it should be understood that when the terms "comprises" and/or "comprising" are used in this specification, they specify the presence of stated features, steps, operations, devices, components, and/or combinations thereof, unless the context clearly indicates otherwise.

As shown in fig. 1, the present embodiment provides a hybrid energy consumption device, which includes a centralized energy consumption device and a distributed energy consumption device connected in parallel to a dc line; the centralized energy consumption device and the distributed energy consumption device can be put into operation independently or simultaneously.

In this embodiment, as shown in fig. 3, the centralized energy consumption device is composed of an energy consumption branch 1 and an energy consumption resistor 3, and the energy consumption branch is formed by connecting at least one energy consumption submodule 2 in series in the same direction. An auxiliary isolating switch 7 and a charging bypass resistor 5 are additionally included; the energy consumption branch 1 is composed of a plurality of energy consumption modules 2, and two ends of each energy consumption module are also connected with a bypass switch 4 in parallel.

In this embodiment, as shown in fig. 2, the distributed energy consumption device is composed of a plurality of voltage-sharing energy consumption modules (energy consumption sub-modules), the voltage-sharing energy consumption modules are connected in series, and each energy consumption sub-module is composed of an energy consumption unit (resistor Rb), an energy storage unit (capacitor C) and a controllable switch (semiconductor device IGBT).

In this embodiment, the designed rated power of the distributed energy consumption device is greater than the 2/3 rated power of the system, and the designed rated power of the centralized energy consumption device is greater than the 1/3 rated power of the system.

The embodiment also provides a control method of the hybrid energy consumption device, wherein when the voltage of the direct current line is higher than a preset value, the hybrid energy consumption device is preferentially selected to be put into the distributed energy consumption device; when the distributed energy consumption device can not completely consume the redundant energy, the centralized energy consumption device is simultaneously put into use.

In this embodiment, the method comprises the following steps:

step S1: real-time detection of DC line voltage U_dlWhen the receiving end AC system is in fault, the voltage of the DC line rises, and surplus power P consumed by the energy consumption device is calculated_loss；

Step S2: when the DC voltage U is detected_dlWhen the operation threshold value is increased and is larger than the action threshold value of the distributed energy consumption device, the distributed energy consumption device is put into the distributed energy consumption device according to the surplus power;

step S3: judgment of P_lossRated power P of system₀If P is a relationship between_loss/P₀<2/3, only the distributed energy consumption devices need to be put into use; if P_loss/P₀>2/3, the distributed energy consuming devices and the centralized energy consuming devices are simultaneously put into operation.

In this embodiment, the voltage of the dc line is monitored in real time, when the voltage of the dc line is normal, the distributed energy consumption device is precharged, and after the precharge is completed, the distributed energy consumption device is in a hot standby state.

In this embodiment, when the most common single-phase fault occurs in the receiving-end ac grid, only the distributed energy consumption device is put into use; when a serious alternating-current two-phase fault or three-phase fault occurs in a receiving-end alternating-current power grid, a distributed energy consumption device and a centralized energy consumption device are simultaneously put into use, and the centralized energy consumption device can bear energy which needs to be consumed.

Specifically, the present embodiment is described by taking a specific system as an example. The DC rated voltage of the system is assumed to be 500kV, and the transmission rated power is 500 MW. Supposing that the earth fault of the receiving end alternating current single-phase system is detected at a certain moment, the direct current voltage rises at the moment, and the surplus power calculation formula is P_loss＝P_send-P_dc，P_sendTransmitting power of 500MW, P to the current DC system_dcThe actual power of the receiving end converter station is about 330MW during the fault period, and the surplus power is about 170MW at the moment, P_loss/P_send<2/3, only the distributed energy consumption devices are needed to be put in, and the number of the energy consumption submodules is determined by the surplus power; supposing that a three-phase earth fault of a receiving end alternating current system occurs at a certain moment, the transmitting section transmits power of 500MW at the moment, the receiving end receives power of 0MW, surplus power generated at the moment is 500M, and P is obtained at the moment_loss/P_send>2/3, the distributed energy consuming devices are used for stabilizing the DC voltage, and the centralized energy consuming devices are used for consuming surplus power.

The foregoing is directed to preferred embodiments of the present invention, other and further embodiments of the invention may be devised without departing from the basic scope thereof, and the scope thereof is determined by the claims that follow. However, any simple modification, equivalent change and modification of the above embodiments according to the technical essence of the present invention are within the protection scope of the technical solution of the present invention.

Claims (8)

1. A hybrid energy consumption device is characterized by comprising a centralized energy consumption device and a distributed energy consumption device which are connected in parallel at a direct current line end; the centralized energy consumption device and the distributed energy consumption device can be put into operation independently or simultaneously.

2. A hybrid energy consuming device as claimed in claim 1, wherein the centralized energy consuming device is composed of energy consuming sub-modules and energy consuming resistors, and the energy consuming sub-modules are connected in series in the same direction.

3. A hybrid energy consumption device as claimed in claim 1, wherein the distributed energy consumption device is composed of a plurality of voltage-sharing energy consumption modules, and the voltage-sharing energy consumption modules are connected in series.

4. The hybrid energy consumption device as recited in claim 1, wherein the distributed energy consumption device has a design power rating greater than 2/3 power rating of the system, and the centralized energy consumption device has a design power rating greater than 1/3 power rating of the system.

5. The method for controlling the hybrid energy consumption device as claimed in claims 1 to 4, wherein the distributed energy consumption device is preferentially selected to be put into use when the DC line voltage is higher than a preset value; when the distributed energy consumption device can not completely consume the redundant energy, the centralized energy consumption device is simultaneously put into use.

6. The method of controlling a hybrid energy consuming device as recited in claim 5, comprising the steps of:

step S1: real-time detection of DC line voltage U_dlWhen the receiving end AC system is in fault, the voltage of the DC line rises, and surplus power P consumed by the energy consumption device is calculated_loss；

Step S2: when the DC voltage U is detected_dlWhen the operation threshold value is increased and is larger than the action threshold value of the distributed energy consumption device, the distributed energy consumption device is put into the distributed energy consumption device according to the surplus power;

step S3: judgment of P_lossRated power P of system₀If P is a relationship between_loss/P₀<2/3, only the distributed energy consumption devices need to be put into use; if P_loss/P₀>2/3, the distributed energy consuming devices and the centralized energy consuming devices are simultaneously put into operation.

7. The method as claimed in claim 5, wherein the distributed energy consuming device is pre-charged when the dc line voltage is normal, and the distributed energy consuming device is in a hot standby state after the pre-charging is completed.

8. The control method of the hybrid energy consumption device according to claim 5, wherein only the distributed energy consumption device is put into operation when a single-phase fault occurs in the receiving-end AC power grid; when an alternating current two-phase fault or a three-phase fault occurs in a receiving end alternating current power grid, the distributed energy consumption device and the centralized energy consumption device are simultaneously put into use.

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