阅读说明：本技术 一种超导磁体的失超检测方法、装置、设备及存储介质 (Quench detection method, device and equipment for superconducting magnet and storage medium ) 是由 罗运松 李达义 薛曼玉 龚杰 于 2020-07-09 设计创作，主要内容包括：本申请公开了一种超导磁体的失超检测方法、装置、设备及存储介质,本申请按预置升流方法将励磁电流分段设定,并计算得出不同励磁电流对应的标准磁体回路电阻值,再根据不同的励磁电流与对应的标准磁体回路电阻值拟合出磁体回路电阻随励磁电流的变化曲线,根据变化曲线拟合出保护动作设定值曲线,判断当前磁体回路电阻值是否大于当前励磁电流对应的保护动作设定值,或当前磁体回路电阻值与历史磁体回路电阻值的差值是否大于预置阈值,若是,则触发失超后备保护动作,利用超导磁体的励磁系统实现失超检测以及失超后备保护,解决了现有通过电压仪表进行失超检测,需要额外增加硬件检测回路和检测设备,从而增加了失超检测成本的技术问题。(The application discloses a quench detection method, a device, equipment and a storage medium of a superconducting magnet, the application sets exciting currents in segments according to a preset current rising method, calculates standard magnet loop resistance values corresponding to different exciting currents, fits a change curve of magnet loop resistance along with the exciting currents according to the different exciting currents and the corresponding standard magnet loop resistance values, fits a protection action set value curve according to the change curve, judges whether the current magnet loop resistance value is larger than a protection action set value corresponding to the current exciting current or whether the difference value of the current magnet loop resistance value and the historical magnet loop resistance value is larger than a preset threshold value, if so, triggers a quench backup protection action, realizes quench detection and quench backup protection by using an exciting system of the superconducting magnet, and solves the problem that the quench detection is carried out by a voltage instrument, an additional hardware detection loop and detection equipment are required, so that the technical problem of the quench detection cost is increased.)

1. A quench detection method for a superconducting magnet, comprising:

gradually increasing the exciting current from 0 to rated exciting current according to a preset current increasing method;

calculating the resistance value of the standard magnet loop after each current rise according to the actual excitation output voltage, the actual alternating current input voltage, the actual excitation current and the actual delay trigger angle;

fitting a variation curve of the magnet loop resistance along with the exciting current according to the exciting current after each current rise and the standard magnet loop resistance after each current rise;

fitting a protection action set value curve according to the change curve, wherein the protection action set value curve comprises a plurality of protection action set values, and each protection action set value is a value which is larger than a preset proportion of the standard magnet loop resistance value corresponding to the exciting current after each current rise;

calculating to obtain the current magnet loop resistance value according to the current excitation output voltage, the alternating current input voltage, the excitation current and the delay trigger angle;

obtaining a historical magnet loop resistance value, and calculating a difference value between the current magnet loop resistance value and the historical magnet loop resistance value;

and judging whether the current magnet loop resistance value is larger than a protection action set value corresponding to the current exciting current or not, or whether the difference value is larger than a preset threshold value or not, and if so, triggering a quench backup protection action.

2. The method for detecting quench of a superconducting magnet according to claim 1, wherein the determining whether the current magnet circuit resistance value is greater than a protection action set value corresponding to a current excitation current or whether the difference value is greater than a preset threshold value, if yes, triggering a quench backup protection action includes:

judging whether the current magnet loop resistance value is larger than a protection action set value corresponding to the current exciting current or not, or whether the difference value is larger than a preset threshold value or not;

if so, calculating the duration that the resistance value of the current magnet loop is greater than the set value of the protection action or the difference value is greater than a preset threshold value;

and judging whether the duration time is greater than the preset time, and if so, triggering a backup protection action of quench.

3. The method for detecting quench of a superconducting magnet according to claim 1, wherein the gradually increasing the excitation current from 0 to the rated excitation current by a preset current-increasing method specifically comprises:

and gradually increasing the exciting current from 0 to the rated exciting current according to the current increasing step length of 5% of the rated exciting current.

4. A quench detection apparatus for a superconducting magnet, comprising:

the current rising unit is used for gradually rising the exciting current from 0 to the rated exciting current according to a preset current rising method;

the first calculating unit is used for calculating the resistance value of the standard magnet loop after each current rise according to the actual excitation output voltage, the actual alternating current input voltage, the actual excitation current and the actual delay trigger angle;

the first fitting unit is used for fitting a change curve of the magnet loop resistance along with the excitation current according to the excitation current after each current rise and the standard magnet loop resistance after each current rise;

the second fitting unit is used for fitting a protection action set value curve according to the change curve, the protection action set value curve comprises a plurality of protection action set values, and each protection action set value is a value which is larger than a preset proportion of the standard magnet loop resistance value corresponding to the exciting current after each current rise;

the second calculation unit is used for calculating the current magnet loop resistance value according to the current excitation output voltage, the alternating current input voltage, the excitation current and the delay trigger angle;

the acquisition unit is used for acquiring the resistance value of a historical magnet loop and calculating the difference value between the current resistance value of the magnet loop and the resistance value of the historical magnet loop;

and the triggering unit is used for judging whether the current magnet loop resistance value is larger than a protection action set value corresponding to the current exciting current or not, or whether the difference value is larger than a preset threshold value or not, and if so, triggering the quench backup protection action.

5. The quench detection apparatus of the superconducting magnet according to claim 4, wherein the trigger unit includes:

the first judgment subunit is used for judging whether the current magnet loop resistance value is larger than a protection action set value corresponding to the current exciting current or not, or whether the difference value is larger than a preset threshold value or not;

the calculation subunit is configured to calculate, if yes, a duration that the current magnet loop resistance value is greater than the protection action set value or the difference value is greater than a threshold value;

and the second judgment subunit is used for judging whether the duration time is greater than the preset time, and if so, triggering a backup protection action of quench.

6. The quench detection apparatus for a superconducting magnet according to claim 4, wherein the current rising unit is specifically configured to:

and gradually increasing the exciting current from 0 to the rated exciting current according to the current increasing step length of 5% of the rated exciting current.

7. A quench detection apparatus of a superconducting magnet, comprising a memory and a processor;

the memory is used for storing program codes and transmitting the program codes to the processor;

the processor is configured to execute the quench detection method of a superconducting magnet according to any of claims 1 to 3 according to instructions in the program code.

8. A computer-readable storage medium for storing program code for performing the quench detection method for a superconducting magnet according to any one of claims 1 to 3.

Technical Field

The present application relates to the field of superconducting technologies, and in particular, to a quench detection method, apparatus, device, and storage medium for a superconducting magnet.

Background

The superconducting current limiter is a short-circuit current limiting device, and can quickly limit the short-circuit current to an acceptable level when a short-circuit fault occurs, so that the serious damage of the short-circuit current in a power grid to the safe and stable operation of the power grid and electrical equipment is avoided; the superconducting phase modulator is a reactive compensation device, and can quickly respond and output reactive power to support voltage recovery when faults such as voltage sag and the like occur, and the stability of a power grid can be greatly improved and the reliability and the safety of power supply can be improved by two devices. The core components of the equipment all comprise superconducting magnets, any parameter of the temperature, the magnetic field and the current of the superconducting magnets exceeds a critical value, the superconducting magnets generate phase change to become constant conductors, and the process is called quench. The energy of the magnet released in the quenching process can quickly raise the local temperature of the magnet, and if the temperature is raised too high, the internal structure of the superconductor can be damaged, and the magnet can be burnt. Therefore, in order to avoid overheating and damage of the superconducting magnet, quench detection and protection of the superconducting magnet are required, and protection is provided for the magnet to prevent the magnet from being irrecoverable damage.

The existing quench detection method is to detect the voltage of the superconducting magnet through a precision instrument and judge whether quench occurs according to the voltage, however, the existing quench detection through the voltage instrument needs to additionally add a hardware detection loop and detection equipment, thereby increasing the quench detection cost.

Disclosure of Invention

The application provides a quench detection method, a quench detection device, equipment and a storage medium of a superconducting magnet, which are used for solving the technical problem that the quench detection cost is increased because a hardware detection loop and detection equipment are additionally added when the quench detection is carried out through a voltage instrument in the prior art.

In view of this, a first aspect of the present application provides a quench detection method for a superconducting magnet, including:

gradually increasing the exciting current from 0 to rated exciting current according to a preset current increasing method;

calculating the resistance value of the standard magnet loop after each current rise according to the actual excitation output voltage, the actual alternating current input voltage, the actual excitation current and the actual delay trigger angle;

fitting a variation curve of the magnet loop resistance along with the exciting current according to the exciting current after each current rise and the standard magnet loop resistance after each current rise;

fitting a protection action set value curve according to the change curve, wherein the protection action set value curve comprises a plurality of protection action set values, and each protection action set value is a value which is larger than a preset proportion of the standard magnet loop resistance value corresponding to the exciting current after each current rise;

calculating to obtain the current magnet loop resistance value according to the current excitation output voltage, the alternating current input voltage, the excitation current and the delay trigger angle;

obtaining a historical magnet loop resistance value, and calculating a difference value between the current magnet loop resistance value and the historical magnet loop resistance value;

and judging whether the current magnet loop resistance value is larger than a protection action set value corresponding to the current exciting current or not, or whether the difference value is larger than a preset threshold value or not, and if so, triggering a quench backup protection action.

Optionally, the determining whether the current magnet loop resistance value is greater than a protection action set value corresponding to the current excitation current, or whether the difference value is greater than a preset threshold value, if so, triggering a quench backup protection action, including:

judging whether the current magnet loop resistance value is larger than a protection action set value corresponding to the current exciting current or not, or whether the difference value is larger than a preset threshold value or not;

if so, calculating the duration that the resistance value of the current magnet loop is greater than the set value of the protection action or the difference value is greater than a preset threshold value;

and judging whether the duration time is greater than the preset time, and if so, triggering a backup protection action of quench.

Optionally, the gradually increasing the excitation current from 0 to the rated excitation current according to the preset current increasing method specifically includes:

and gradually increasing the exciting current from 0 to the rated exciting current according to the current increasing step length of 5% of the rated exciting current.

A second aspect of the present application provides a quench detection apparatus for a superconducting magnet, including:

the current rising unit is used for gradually rising the exciting current from 0 to the rated exciting current according to a preset current rising method;

the first calculating unit is used for calculating the resistance value of the standard magnet loop after each current rise according to the actual excitation output voltage, the actual alternating current input voltage, the actual excitation current and the actual delay trigger angle;

the first fitting unit is used for fitting a change curve of the magnet loop resistance along with the excitation current according to the excitation current after each current rise and the standard magnet loop resistance after each current rise;

the second fitting unit is used for fitting a protection action set value curve according to the change curve, the protection action set value curve comprises a plurality of protection action set values, and each protection action set value is a value which is larger than a preset proportion of the standard magnet loop resistance value corresponding to the exciting current after each current rise;

the second calculation unit is used for calculating the current magnet loop resistance value according to the current excitation output voltage, the alternating current input voltage, the excitation current and the delay trigger angle;

the acquisition unit is used for acquiring the resistance value of a historical magnet loop and calculating the difference value between the current resistance value of the magnet loop and the resistance value of the historical magnet loop;

and the triggering unit is used for judging whether the current magnet loop resistance value is larger than a protection action set value corresponding to the current exciting current or not, or whether the difference value is larger than a preset threshold value or not, and if so, triggering the quench backup protection action.

Optionally, the trigger unit includes:

the first judgment subunit is used for judging whether the current magnet loop resistance value is larger than a protection action set value corresponding to the current exciting current or not, or whether the difference value is larger than a preset threshold value or not;

the calculation subunit is configured to calculate, if yes, a duration that the current magnet loop resistance value is greater than the protection action set value or the difference value is greater than a threshold value;

and the second judgment subunit is used for judging whether the duration time is greater than the preset time, and if so, triggering a backup protection action of quench.

Optionally, the upflow unit is specifically configured to:

and gradually increasing the exciting current from 0 to the rated exciting current according to the current increasing step length of 5% of the rated exciting current.

A third aspect of the present application provides a quench detection apparatus of a superconducting magnet, including a memory and a processor;

the memory is used for storing program codes and transmitting the program codes to the processor;

the processor is configured to execute the quench detection method for a superconducting magnet according to any one of the first aspect of the present application according to instructions in the program code.

A fourth aspect of the present application provides a computer-readable storage medium for storing program code for performing the quench detection method of a superconducting magnet according to the first aspect of the present application.

According to the technical scheme, the method has the following advantages:

the application discloses a quench detection method of a superconducting magnet, which comprises the following steps: gradually increasing the exciting current from 0 to rated exciting current according to a preset current increasing method; calculating the resistance value of the standard magnet loop after each current rise according to the actual excitation output voltage, the actual alternating current input voltage, the actual excitation current and the actual delay trigger angle; fitting a variation curve of the magnet loop resistance along with the exciting current according to the exciting current after each current rise and the standard magnet loop resistance after each current rise; fitting a protection action set value curve according to the change curve, wherein the protection action set value curve comprises a plurality of protection action set values, and each protection action set value is a value which is larger than a preset proportion of a standard magnet loop resistance value corresponding to the excitation current after each current rise; calculating to obtain the current magnet loop resistance value according to the current excitation output voltage, the alternating current input voltage, the excitation current and the delay trigger angle; acquiring a historical magnet loop resistance value, and calculating a difference value between the current magnet loop resistance value and the historical magnet loop resistance value; and judging whether the current magnet loop resistance value is larger than a protection action set value corresponding to the current exciting current or whether the difference value is larger than a preset threshold value, and if so, triggering the quench backup protection action.

The method comprises the steps of setting exciting current in sections according to a preset current rising method, calculating to obtain standard magnet loop resistance values corresponding to different exciting currents, fitting a change curve of the magnet loop resistance along with the exciting current according to the different exciting currents and the corresponding standard magnet loop resistance values, fitting a protection action set value curve according to the change curve, wherein the obtained protection action set value is set in sections according to the different exciting currents and is not fixed, so that the protection action set value is more accurate, judging whether the current magnet loop resistance value is larger than the protection action set value corresponding to the current exciting current or not, or whether the difference value between the current magnet loop resistance value and the historical magnet loop resistance value is larger than a preset threshold value or not, if yes, triggering a quench backup protection action, adding a judgment method adopting redundant data, and comparing the current magnet loop resistance value with the historical magnet loop resistance value, the accuracy of quench detection and the reliability of quench backup protection are improved, quench detection and quench backup protection are realized by using an excitation system of the superconducting magnet, extra hardware loops and equipment are not needed, and the technical problem that quench detection cost is increased because extra hardware detection loops and detection equipment are needed for quench detection through a voltage instrument in the prior art is solved.

Drawings

Fig. 1 is a schematic flowchart of a first embodiment of a quench detection method for a superconducting magnet according to an embodiment of the present application;

fig. 2 is a schematic flowchart of a second embodiment of a quench detection method for a superconducting magnet according to an embodiment of the present application;

fig. 3 is a schematic structural diagram of an embodiment of a quench detection apparatus for a superconducting magnet according to an embodiment of the present application.

Detailed Description

The embodiment of the application provides a quench detection method of a superconducting magnet, which is used for solving the technical problem that in the prior art, quench detection is carried out through a voltage instrument, a hardware detection loop and detection equipment are additionally added, so that the quench detection cost is increased.

The excitation system is a power supply of the excitation current of the superconducting fault current limiter and is a general name of accessory equipment thereof, the excitation system comprises two main parts, namely an excitation power unit and an excitation regulator, the excitation power unit provides the excitation current for the superconducting fault current limiter, the excitation regulator controls the output of the excitation power unit according to an input signal and a given regulation criterion, and the excitation regulator of the excitation system can measure the voltage and the current.

In order to make the objects, features and advantages of the present invention more apparent and understandable, the technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present application, and it is apparent that the embodiments described below are only a part of the embodiments of the present application, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

Referring to fig. 1, an embodiment of the present application provides a quench detection method for a superconducting magnet, including:

and step S101, gradually increasing the exciting current from 0 to the rated exciting current according to a preset current increasing method.

Since the actual resistance value of the coil of the superconducting magnet changes at different currents, and the resistance of the magnet circuit also changes, the exciting current needs to be set in segments, and the exciting current is gradually increased from 0 to the rated exciting current by the exciting power unit.

And S102, calculating the resistance value of the standard magnet loop after each current rise according to the actual excitation output voltage, the actual alternating current input voltage, the actual excitation current and the actual delay trigger angle.

After the excitation current is increased from 0 to the rated excitation current, the actual excitation output voltage, the actual alternating-current input voltage, the actual excitation current and the actual delay trigger angle are obtained through the excitation regulator, and the standard magnet loop resistance after each current increase is calculated according to the actual excitation output voltage, the actual alternating-current input voltage, the actual excitation current and the actual delay trigger angle, for example, when the excitation current is increased from 0 to 10% of the rated excitation current, the standard magnet loop resistance is calculated when the excitation current is 10% of the rated excitation current.

And step S103, fitting a variation curve of the magnet loop resistance along with the excitation current according to the excitation current after each current rise and the standard magnet loop resistance after each current rise.

It should be noted that, the resistance value of the standard magnet circuit after each current rise is calculated, and a variation curve of the magnet circuit resistance with the excitation current is fitted according to the excitation current after each current rise and the resistance value of the standard magnet circuit.

And step S104, fitting a protection action set value curve according to the change curve.

It should be noted that the protection action set value curve includes a plurality of protection action set values, each protection action set value is a value of a preset proportion of a standard magnet circuit resistance value corresponding to the excitation current after each current rise, for example, the magnet current rises to 10% of a rated current, corresponding to a standard magnet circuit resistance value, the standard magnet circuit resistance value of the preset proportion is set as the protection action set value, the preset proportion may be set to 50% or 55%, and a person skilled in the art may set the preset proportion as needed.

And step S105, calculating the current magnet loop resistance value according to the current excitation output voltage, the current alternating-current input voltage, the current excitation current and the delay trigger angle.

It should be noted that the current excitation output voltage, the current alternating-current input voltage, the current excitation current and the delay firing angle are obtained through the excitation regulator, and the current magnet circuit resistance value is calculated according to the current excitation output voltage, the current alternating-current input voltage, the current excitation current and the delay firing angle.

And S106, acquiring the resistance value of the historical magnet circuit, and calculating the difference value between the current resistance value of the magnet circuit and the resistance value of the historical magnet circuit.

The method also needs to obtain the resistance value of the historical magnet circuit before a period of time, and calculate the difference between the current resistance value of the magnet circuit and the resistance value of the historical magnet circuit, wherein the difference is the maximum difference between the resistance values of all the historical magnet circuits in the period of time.

And S107, judging whether the current magnet loop resistance value is larger than a protection action set value corresponding to the current exciting current or not, or whether the difference value is larger than a preset threshold value or not, and triggering the quench backup protection action if the current magnet loop resistance value is larger than the protection action set value corresponding to the current exciting current.

It can be understood that if the resistance value of the magnet circuit is greater than the protection action set value corresponding to the current excitation current, or the difference between the current resistance value of the magnet circuit and the resistance value of the historical magnet circuit is greater than a preset threshold, the quench backup protection action is triggered. The quench back-up protection action comprises two conditions, wherein one condition is that an alarm is given and an excitation system is switched to a fixed-angle operation mode, and the other condition is that the operation is stopped and the output current of the excitation system is reduced to zero.

It should be noted that, when the resistance value of the magnet circuit is greater than the action set value of the protection corresponding to the current exciting current, the first quench backup protection action is triggered, that is, an alarm is given and the exciting system is switched to the constant angle operation mode. And when the difference value between the resistance value of the historical magnet loop and the current magnet loop is greater than a preset threshold value, triggering a second quench backup protection action, namely stopping operation, and reducing the output current of the excitation system to zero.

It should be further noted that the preset threshold is K times of the maximum difference, where K is a coefficient greater than 1, and a person skilled in the art may set the size of K according to actual situations.

In the embodiment of the application, the exciting current is set in sections according to a preset current rising method, the resistance values of standard magnet loops corresponding to different exciting currents are calculated, then a change curve of the magnet loop resistance along with the exciting current is fitted according to the different exciting currents and the corresponding resistance values of the standard magnet loops, a protection action set value curve is fitted according to the change curve, namely the obtained protection action set value is set according to different exciting current sections and is not fixed, so that the protection action set value is more accurate, whether the current magnet loop resistance value is larger than the protection action set value corresponding to the current exciting current or whether the difference value between the current magnet loop resistance value and the historical magnet loop resistance value is larger than a preset threshold value or not is judged, if yes, the quench backup protection action is triggered, a judgment method adopting redundant data is added, the current magnet loop resistance value is compared with the historical magnet loop resistance value, the accuracy of quench detection and the reliability of quench backup protection are improved, quench detection and quench backup protection are realized by using an excitation system of the superconducting magnet, extra hardware loops and equipment are not needed, and the technical problem that quench detection cost is increased because extra hardware detection loops and detection equipment are needed for quench detection through a voltage instrument in the prior art is solved.

The above is a detailed description of a first embodiment of a superconducting magnet quench detection method provided in the present application, and the following is a detailed description of a second embodiment of a superconducting magnet quench detection method provided in the present application.

Referring to fig. 2, an embodiment of the present application provides a quench detection method for a superconducting magnet, including:

step S201, gradually increasing the excitation current from 0 to the rated excitation current according to the current increase step of 5% of the rated excitation current.

It should be noted that the up-flow step may be 10% or 15%, and those skilled in the art can set the up-flow step according to actual needs.

Step S202, calculating the resistance value of the standard magnet circuit after each current rise according to the actual excitation output voltage, the actual alternating current input voltage, the actual excitation current and the actual delay trigger angle.

And S203, fitting a variation curve of the magnet loop resistance along with the excitation current according to the excitation current after each current rise and the standard magnet loop resistance after each current rise.

And step S204, fitting a protection action set value curve according to the change curve.

And S205, calculating the current magnet circuit resistance value according to the current excitation output voltage, the current alternating-current input voltage, the current excitation current and the delay trigger angle.

And S206, acquiring the resistance value of the historical magnet circuit, and calculating the difference value between the current resistance value of the magnet circuit and the resistance value of the historical magnet circuit.

Step S207, determining whether the current magnet loop resistance value is greater than the protection action set value corresponding to the current excitation current, or whether the difference value is greater than a preset threshold value.

And S208, if so, calculating the duration that the current magnet loop resistance value is larger than the protection action set value or the difference value is larger than a preset threshold value.

And S209, judging whether the duration time is greater than the preset time, and if so, triggering a backup protection action of quench.

It should be noted that the preset time set by the present application is 1s, and those skilled in the art can set the preset time as needed.

In the embodiment of the application, the exciting current is set in sections according to a preset current rising method, the resistance values of standard magnet loops corresponding to different exciting currents are calculated, then a change curve of the magnet loop resistance along with the exciting current is fitted according to the different exciting currents and the corresponding resistance values of the standard magnet loops, a protection action set value curve is fitted according to the change curve, namely the obtained protection action set value is set according to different exciting current sections and is not fixed, so that the protection action set value is more accurate, whether the current magnet loop resistance value is larger than the protection action set value corresponding to the current exciting current or whether the difference value between the current magnet loop resistance value and the historical magnet loop resistance value is larger than a preset threshold value or not is judged, if yes, the quench backup protection action is triggered, a judgment method adopting redundant data is added, the current magnet loop resistance value is compared with the historical magnet loop resistance value, the accuracy of quench detection and the reliability of quench backup protection are improved, quench detection and quench backup protection are realized by using an excitation system of the superconducting magnet, extra hardware loops and equipment are not needed, and the technical problem that quench detection cost is increased because extra hardware detection loops and detection equipment are needed for quench detection through a voltage instrument in the prior art is solved.

The above is a detailed description of a second embodiment of a superconducting magnet quench detection method provided by the present application, and the following is an embodiment of a superconducting magnet quench detection apparatus provided by the present application.

Referring to fig. 3, an embodiment of the present application provides a quench detection apparatus for a superconducting magnet, including:

and the current rising unit 301 is used for gradually rising the excitation current from 0 to the rated excitation current according to a preset current rising method.

The first calculating unit 302 is configured to calculate a resistance value of the standard magnet circuit after each current rise according to the actual excitation output voltage, the actual ac input voltage, the actual excitation current, and the actual delay firing angle.

The first fitting unit 303 is configured to fit a variation curve of the magnet circuit resistance with the excitation current according to the excitation current after each current rise and the standard magnet circuit resistance after each current rise.

And a second fitting unit 304, configured to fit a protection action set value curve according to the variation curve.

And a second calculating unit 305, configured to calculate a current magnet circuit resistance value according to the current excitation output voltage, the ac input voltage, the excitation current, and the delay firing angle.

The obtaining unit 306 is configured to obtain a resistance value of a historical magnet circuit, and calculate a difference between the current resistance value of the magnet circuit and the resistance value of the historical magnet circuit.

And the triggering unit 307 is configured to determine whether the current magnet loop resistance value is greater than a protection action set value corresponding to the current excitation current, or whether the difference value is greater than a preset threshold, and if so, trigger a quench backup protection action.

Further, the trigger unit 307 of the embodiment of the present application includes:

the first determining subunit 3071 is configured to determine whether the current magnet circuit resistance value is greater than a protection action setting value corresponding to the current excitation current, or whether the difference value is greater than a preset threshold value.

And the calculating subunit 3072 is configured to calculate, if yes, a duration that the current magnet circuit resistance value is greater than the protection action set value or the difference value is greater than the preset threshold value.

And the second judging subunit 3073 is configured to judge whether the duration is greater than the preset time, and if so, trigger a quench backup protection action.

Further, the current step-up unit 301 is specifically configured to gradually increase the excitation current from 0 to the rated excitation current according to a current step-up of 5% of the rated excitation current.

The embodiment of the application also provides quench detection equipment of the superconducting magnet, which comprises a processor and a memory, wherein the processor comprises: the memory is used for storing the program codes and transmitting the program codes to the processor; the processor is used for executing the quench detection method of the superconducting magnet according to instructions in the program codes.

The present embodiments also provide a computer readable storage medium for storing program code for implementing any one of the above-mentioned quench detection methods for a superconducting magnet.

It is clear to those skilled in the art that, for convenience and brevity of description, the specific working processes of the network, the apparatus and the unit described above may refer to the corresponding processes in the foregoing method embodiments, and are not described herein again.

In the several embodiments provided in the present application, it should be understood that the disclosed apparatus and method may be implemented in other ways. For example, the above-described device embodiments are merely illustrative, and for example, the division of the units is only one logical functional division, and other divisions may be realized in practice, for example, a plurality of units or components may be combined or integrated into another grid network to be installed, or some features may be omitted or not executed. In addition, the shown or discussed mutual coupling or direct coupling or communication connection may be an indirect coupling or communication connection through some interfaces, devices or units, and may be in an electrical, mechanical or other form.

The units described as separate parts may or may not be physically separate, and parts displayed as units may or may not be physical units, may be located in one place, or may be distributed on a plurality of network units. Some or all of the units can be selected according to actual needs to achieve the purpose of the solution of the embodiment.

In addition, functional units in the embodiments of the present application may be integrated into one processing unit, or each unit may exist alone physically, or two or more units are integrated into one unit. The integrated unit can be realized in a form of hardware, and can also be realized in a form of a software functional unit.

The integrated unit, if implemented in the form of a software functional unit and sold or used as a stand-alone product, may be stored in a computer readable storage medium. Based on such understanding, the technical solution of the present application may be substantially implemented or contributed to by the prior art, or all or part of the technical solution may be embodied in a software product, which is stored in a storage medium and includes instructions for causing a computer device (which may be a personal computer, a server, or a network device) to execute all or part of the steps of the method according to the embodiments of the present application. And the aforementioned storage medium includes: various media capable of storing program codes, such as a usb disk, a removable hard disk, a Read-only memory (ROM), a Random Access Memory (RAM), a magnetic disk, or an optical disk.

The above embodiments are only used for illustrating the technical solutions of the present application, and not for limiting the same; although the present application has been described in detail with reference to the foregoing embodiments, it should be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions in the embodiments of the present application.