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Người liên hệ : Wang Hong

Precise Injection And Stable Circulation: The Key Role Of High-voltage Doorknob Capacitors In The Pulsed Magnet Power Supply Of Synchrotron Radiation Light Sources

Nguồn gốc Tây An, TRUNG QUỐC
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Thông tin chi tiết sản phẩm
tiêu tan ≦0,0040 chịu được điện áp 1.5ur ● 1 phút
Điện trở cách nhiệt 1.0 × 105mΩ
Làm nổi bật

high voltage doorknob capacitors pulsed magnet

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synchrotron radiation capacitors stable circulation

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high voltage capacitors with warranty

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Mô tả sản phẩm

High-voltage doorknob capacitors in the pulsed magnet power supply of synchrotron radiation light sources

Drawing:

Precise Injection And Stable Circulation: The Key Role Of High-voltage Doorknob Capacitors In The Pulsed Magnet Power Supply Of Synchrotron Radiation Light Sources 0

Parameters:

No. Specification Dissipation Withstanding voltage Insulation resistance Dimension(mm)
1 20kV-2000pF








≦0.0040








1.5Ur 1min








≧1.0×105MΩ

D H L D M
2 20kV-10000pF 45 19 23 12 5
3 20kV-18000pF 65 15 19 12 5
4 30kV-1000pF 80 17 25 12 5
5 30kV-2700pF 45 24 32 12 4
6 30kV-12000pF 60 20 28 12 4
7 40kV-150pF 20 33 41 8 4
8 40kV-500pF 28 33 41 8 4
9 40kV-7500pF 80 24 29 12 6
10 40kV-10000pF 80 22 26 16 5
11 50kV-1000pF 50 30 34 12 4
12 50kV-1000pF 32 27 31 16 5
13 50kV-5600pF 80 31 35 16 5
14 60kV-1500pF 50 31 34 12 5
15 60kV-3000pF 65 32 35 16 5
16 100kV-500pF 50 54 58 12 5
17 100kV-2000pF 51 32 35 16 5
18 Insulator type 100kV-1500pF 68 36 40 16 5
19 150kV-820pF 65 95 100 12 5
20 200kV-600pF 50 90 94 16 5



Core Functions:

The leap in performance at synchrotron radiation sources is largely due to innovations in beam injection technology. In particular, innovative schemes such as on-axis displacement injection, employed by fourth-generation sources, place extremely stringent demands on pulsed magnet power supplies: they must instantly deliver massive pulsed currents to generate precisely controlled magnetic fields, effectively driving the electron beam into or out of its intended trajectory. High-voltage doorknob capacitors are the core guarantee for the high-precision and high-stability operation of these high-performance pulsed magnet power supplies.

Challenge:

Why are pulsed magnet power supply requirements so stringent?

Take the fourth-generation High Energy Synchrotron Source (HEPS) as an example. The bumper magnet used in its booster extraction system requires the pulsed power supply to output a half-sine wave with a bottom width of less than 1 millisecond, with peak current fluctuations controlled within ±0.3% and waveform consistency deviations less than 5%. Any distortion or jitter in the current waveform can lead to:

Electron beam trajectory deviation, resulting in reduced injection efficiency and impacting the stability of the storage circulation intensity.

Synchrotron radiation beam position drift, affecting the directivity and data quality of the light at downstream experimental stations.

Solution:

Perfect combination of LC resonant pulse circuit and high-performance capacitors

This type of pulse power supply often uses an LC resonant circuit topology. A high-voltage doorknob capacitor (C) and the pulse magnet inductor (L) form a resonant circuit. Switching (e.g., IGBT) control generates the required high-quality half-sine current pulses.

In this application, the performance of the doorknob capacitor directly determines the quality of the pulse waveform:

Low-inductance design ensures a sharp pulse front: The capacitor's low equivalent series inductance and the overall circuit inductance together determine the pulse rise speed. Our low-ESL doorknob capacitors effectively ensure a sharp pulse front, meeting fast response requirements.

Highly stable capacitance ensures waveform consistency: Long-term capacitance stability and low drift are key to ensuring consistent pulse waveforms from time to time. We use highly stable ceramic dielectrics to ensure minimal capacitance variation even under frequent charge and discharge cycles (e.g., 50Hz operating frequency), thereby ensuring high repeatability of the injection process.

Efficient energy recovery: To reduce energy consumption and heat load, advanced designs incorporate energy recovery circuits. The capacitor feeds back the remaining energy through the recovery circuit during the pulse interval, which not only improves the efficiency but also reduces the interference with the output pulse waveform. This also requires the capacitor to have high efficiency and fast charging and discharging capabilities.