3 dB桥误差对能量倍增器性能的影响

根据能量倍增器的工作原理,对3 dB桥误差引起的能量倍增器性能变化进行了理论分析,并对BEPC和BEPCⅡ直线加速器所使用能量倍增器的3 dB桥误差进行了讨论,为判断焊接后3 dB桥桥臂波导变形提供了理论参考。结果表明:无论是功率分配不平衡,还是相位关系偏离,都会使部分功率反射回速调管。功率分配不平衡和微波相位关系偏离值越大,则功率倍增因子下降得越多。     

BEPCⅡ直线加速器微波系统

BEPCⅡ直线加速器微波系统要求的技术指标比旧系统有了大幅度的提高, 为此老系统的许多部件需要重新研制和改造. 本文首先介绍了关键部件的改造研制情况, 它包括能量倍增器、加速管、大功率波导阀门、大功率干负载及其中功率和高功率波导衰减/移相器; 其次简要介绍了微波系统高功率运行情况.     

一种耦合度可调节的微波脉冲压缩装置设计及实验

针对有源能量倍增器法(SLED)脉冲压缩实验中对储存能量阶段和释放能量阶段耦合度调节的需求,利用支臂短路波导H-T的调配功能,设计了一种耦合度可调节的SLED脉冲压缩装置。基于散射矩阵理论,分析了支臂短路波导H-T对SLED脉冲压缩装置耦合度的调节能力。利用大功率波导环形器代替3 dB耦合器,进行了基于单储能腔的无源SLED脉冲压缩实验,实验结果表明,支臂短路波导H-T对耦合度的调节能力与理论分析相吻合。     

用于长脉冲多束团直线加速器的SLED系统

根据长脉冲多束团直线加速器对输入微波波形的要求,系统研究了带有SLED的微波系统,由SLED基本理论推导了输出RAMP波形和平顶波形脉冲时SLED所需的输入波形,给出SLED的参数优化方法.用冷测实验对所发展的理论进行了验证,第一次用SLED产生了RAMP波形和平顶波形的RF脉冲.     

BEPCⅡ直线加速器的双脉冲加速研究

 为了将BEPCⅡ直线加速器的正电子注入速率提高到单脉冲运行时的两倍左右, 提出了双脉冲产生和加速的方案。对BEPCⅡ直线加速器双脉冲加速的束流动力学进行了模拟, 首次给出了双脉冲的模拟方法。此外, 还在BEPCⅡ直线加速器上进行了双脉冲加速的初步实验研究, 为以后BEPCⅡ直线加速器的进一步改造提供了参考。     

C波段能量倍增器的研制

C波段(5712 MHz)能量倍增器——SLED是我国研制的首台C波段能量倍增器。简述了利用三维电磁场仿真软件HFSS和CST对C波段能量倍增器的高品质因数储能腔、耦合孔、3 dB桥等进行优化设计的情况,对加工的能量倍增器做了射频低功率测试,实验测试和理论计算的一致性很好,测试结果表明所有技术参数指标均达到了设计要求。     

基于FPGA的能量倍增器相位翻转系统的研制

介绍了基于可编程逻辑门阵列(FPGA)的能量倍增器(SLED)相位翻转系统。该系统主要由微波IQ调制器、FPGA和高速DAC组成。在FPGA的控制下,DAC输出两路双极性脉冲电平信号,加载于调制器的IQ端,将微波连续波输入信号转变为4μs脉冲输出信号,并且在3μs时刻微波相位发生180°跳变。经测试,相位翻转精度为180°±2°,翻转相位的长期稳定度优于±0.5°;相位翻转系统驱动的6台SLED的输出功率增益均超过7dB,最高达到7.54dB,增益的长期稳定度达到±0.1dB。     

BEPCⅡ电子枪系统测试与运行

2004年7月BEPCⅡ新电子枪系统在测试台进行了测试, 同年11月投入BEPCⅡ直线加速器运行. 描述了新电子枪系统的测试与运行状态. 电子枪设计电流10A, 脉宽1ns,重复频率50Hz, 脉冲高压200kV, 提供单脉冲和双脉冲运行模式. 通过实验获取了一些重要的关系曲线, 同时进行了初步的双脉冲测试. 流强及发射度测量等测试结果表明设计阶段的计算机模拟数据与实际情况基本相符. 从电子枪实际运行状况来看, 其设计与制造是成功的.     

能量倍增器法微波脉冲压缩

为了开展S波段能量倍增器脉冲压缩实验,对能量倍增器进行了冷测和热测工作,主要包括对能量倍增器的指标、参数的测量以及在高功率下对能量倍增器的输出功率、功率增益等参数的测量。实验中,完成了微波固态源系统的改造,研制了同步信号控制器,研究了输入输出脉冲宽度对输出峰值功率的影响,并对实验中可能的射频击穿问题进行了研究。在输入功率5 MW时,得到了功率增益7.122,输出脉宽260 ns,输出峰值功率35.35 MW。     

(BEPC)1.1/1.4GeV电子直线加速器的250MeV段

在北京正负电子对撞机(BEPC)1.1/1.4GeV电子直线加速器的安装阶段,对起始的250MeV段共安排了四次调束试验,1987年5月达到电子束脉冲流强760mA,能量为250MeV;以150MeV、785mA电子束打转换靶,获得能量99MeV、脉冲流强2.5mA的正电子.检验各项技术指标,都符合设计要求,达到国外同类加速器的水平.     

A New Type of Detuning System of RF Compressors (SLED)

In our SLAC type of RF pulse compressor (SLED), the detuning device works not as well as expected. It happend that the detuning needles sticked to the sleeves when working at detuning mode. Due to this reason, we can not measure its energy multiplication factor. To solve the sticking problem of SLED needles, a prototype of the new SLED detuning system has been developed and it has been operated with high power successfully on BEPC Linac.     

Microwave System for BEPCⅡ-Linac

Specifications of microwave system for BEPCⅡ-Linac were enhanced by a wide margin in comparison with those of the microwave system for BEPC-Linac. For this reason many RF components must be developed and improved. This paper introduces the developments of SLED detuning system, accelerating section, high power waveguide valve, high power dummy-load, and medium & high power waveguide attenuator/phase shifters. High power operation of the microwave system has been carried out.     

Error and jitter effect studies on the SLED for the BEPC Ⅱ-linac

An RF pulse compressor is a device used to convert a long RF pulse to a short one with a much higher peak RF magnitude. SLED can be regarded as the earliest RF pulse compressor to be used in large-scale linear accelerators. It has been widely studied around the world and applied in the BEPC and BEPC linac for many years. During routine operation, error and jitter effects will deteriorate the performance of SLED, either on the output electromagnetic wave amplitude or phase. The error effects mainly include the frequency drift induced by cooling water temperature variation and the frequency/Q 0 /β unbalances between the two energy storage cavities caused by mechanical fabrication or microwave tuning. The jitter effects refer to the PSK switching phase and time jitters. In this paper, we re-derive the generalized formulae for the conventional SLED used in the BEPC linac, and the error and jitter effects on SLED performance are also investigated.     

S波段高精度快速倒相开关设计

倒相开关是能量倍增器法(SLED)脉冲压缩系统中的关键器件,它的倒相精度和开关速度对脉冲压缩系统的性能有重要影响。设计了一种工作在S波段的精度可调、响应迅速的微带反射式倒相开关,并对其进行了理论分析,电路结构设计和仿真研究。对倒相开关的反射终端进行了改进设计,利用一个变容二极管来代替传统的并联枝节电路,通过调节变容二极管的偏置电压改变反射终端的反射系数,从而实现对倒相相位的精确调节。仿真结果表明,倒相开关响应时间约4 ns,且通过调节变容二极管偏置电压可以在一定范围内调节倒相精度。     

Design and simulation of a C-band SLED with mode converter

The transient response analysis of the SLED based on the equivalent circuit is described. Then, a C-band SLED using TE0,1,15 mode cylindrical cavity with TE10-TE01 mode converter has been designed. According to the main RF parameters of the accelerator, the coupling coefficient is optimized to obtain the maximum multiplication factor. The key components of the pulse compressor include a 3 dB directional coupler, a TE10-TE01 mode converter,and a cylindrical cavity, which are simulated and optimized using 3D electromagnetic field simulation software. In addition, the function defining the relation between the coupling factor and aperture size is derived by a mathematical fitting method.     

Modeling and analysis of SLED

SLED(SLAC Energy Doubler) is a crucial component for the C-band microwave acceleration unit of a soft X-ray Free Electron Laser(SXFEL). To study the behavior of SLED, a mathematical model is commonly built and analyzed. In this paper, a new method is proposed to build the model of SLED at the Shanghai Institute of Applied Physics. With this method, the parameters of the two cavities can be analyzed separately. Also it is suitable to study parameter optimization of SLED and analyze the effect from the parameters variations. Simulation results of our method are also presented.     

常温直线加速器RF系统的建模

为了研究针对RF系统的新的控制方法,用Matlab软件为常温直线加速器的RF系统建立了一个数学模型。模型包括了速调管、SLED和行波加速管等一些典型的微波器件。RF系统模型被用于研究系统在不同输入信号下的输出情况,并用于确定SLED的相位翻转时间和RF系统的工作点。一种新的控制算法,自适应前馈控制算法,也在RF系统模型上得到了验证,并取得了良好的结果。这些都证明所建立的RF系统模型是有效的。     

Switching speed effect of phase shift keying in SLED for generating high power microwaves

SLAC energy doubler(SLED) type radio-frequency pulse compressors are widely used in large-scale particle accelerators for converting long-duration moderate-power input pulses into short-duration high-power output pulses. Phase shift keying(PSK) is one of the key components in SLED pulse compression systems. Performance of the PSK will influence the output characteristics of the SLED, such as the rise-time of the output pulse, maximal peak power gain, and energy efficiency. In this paper, a high power microwave source based on power combining and pulse compression of conventional klystrons is introduced. The effects of nonideal PSK with slow switching speed and PSK without power output during the switching process are investigated, and the experimental results with nonideal PSK agree well with the analytical results.