An Improved Method of the Energy Loss Calculation Considering the Volatility of Wind Power Generation

The energy loss of the power grid is one of the key factors affecting the economic operation of power systems. How to calculate the electric energy consumption accurately will have a great influence on the planning, operation and management of the power grid. Currently there is a mountain of theoretical methods to calculate the line loss of the power system. However, these methods have some limitation, such as less considering the volatility of wind power resources. This paper presents an improved method to calculate the energy loss of wind power generation, considering the fluctuations of wind power generation. First, data are collected to obtain the curve of the typical daily expected output of wind farms for one month. Second, the curve of the typical daily expected output are corrected by the average electricity and the shape factor to obtain the curve of the typical daily equivalent output of wind farms for one month. Finally, the power flow is calculated by using typical daily equivalent output curve to describe the energy loss for one month. The results in the 110 kV main network show that the method is feasible.

Research on Multi-Scale Modeling of Grid-Connected Distributed Photovoltaic Power Generation

The complexity of distribution network model mainly depends on the model scale of grid-connected distributed photovoltaic (PV) power generation. Therefore, the simulation performance of multi-scale PV model is the key factor of the simulation accuracy in the specific operating scenarios of distribution network. In this paper, a multi-scale model of grid connected PV distributed generation system is proposed based on the mathematical model of grid-connected distributed PV power generation. It is analyzed that differences of simulation performance, such as adaptability of simulation step size, accuracy of output and the effect on voltage profile of distribution network, between PV models with different scales in IEEE 33 node example. Simulation results indicate that the multi-scale model is effective in improving the accuracy and efficiency of simulation under different operating conditions of distribution network.

Power Ratio Gain Technique and General Integral Control

In conjunction with general integral control, and synthesizing Singular perturbation and Equal ratio gain techniques, this paper proposes a new control design technique, named Power ratio gain technique, and then by Lyapunov method, theorem to ensure regionally as well as semi-globally asymptotic stability is established in terms of some bounded information. The highlight point is that it not only inherits all the essences of Singular perturbation and Equal ratio gain techniques but also makes up for their shortcomings, and then the conservatism of control input can be improved by compromising the Power ratio coefficients. Theoretical analysis, design example and simulation results show that Power ratio gain technique is a simple, practical and powerful tool to deal with the uncertain nonlinear system.

Fabrication and performance evaluation of the thermoelectric generation and performance measuring system

A novel thennoelectric generating and performance measuring system （TGPMS） was designed and fabricated. TGPMS can not only achieve the function of thennoelectric generation, but also measure the thennoelectric performance parameters of the bismuth-telluride-based thennoelectric device accurately. These thennoelectric performance parameters mainly include the dependence of the Seebeck coefficient of the thennoelectric device on the device＇s temperature in the low temperature range （about 40 ~ 190~C ）, and the dependence of the power output and thermoelectric conversion efficiency on the temperature dif- ference or output load. With the optimum load, the optimal value of the power output is 3.39W when the temperature difference reaches 231.2~C, and the optimal value of the conversion efficiency is 3.22% when the temperature difference reaches 208.9~C. TGPMS provides an experimental foundation for the application of the thennoelectric generators in the space field.

Biomass energy cost and feasibility of gasifier based biomass power generation system

The present research work has been carried out on biomass based on 10 kW capacity gasifier power generation system installed at College of Agricultural Engineering and Technology,Dr.Panjabrao Deshmukh Agricultural University(Dr.PDKV),Akola Maharashtra,India.The main objectives were to evaluate various costs and benefits involved in the power generation system.The costs of energy per unit were calculated for the first year of operation.The economics of gasifier based power generation system and thereby the feasibility of the system was examined by estimating per unit cost,Net Present Value(NPV),Benefit Cost Ratio(BCR),Internal Rate of Return(IRR)and payback period.The discount cash flow method was used to find out the IRR.In the present analysis,three costs viz.,installed capital cost,operation and maintenance cost,and levelised replacement cost were examined for the evaluation of the power generation per unit.Discount rate on investment in case of subsidy(Case I)and in case without subsidy(Case II)for installation cost of system was considered as 12.75%.The BCR comes in Case I for operating duration of 22 h,20 h,and 16 h are 1.24,1.18,and 1.13,respectively.Similarly for Case II BCR comes 1.44,1.38,and 2.39.The IRR comes in Case I for operating duration of 22 h,20 h,and 16 h are 26%,22%,and 19%,respectively.Similarly for Case II,IRR comes 52%,44%,and 39%for operating duration of 22 h,20 h,and 16 h,respectively.The payback period in the present analysis was worked out.The payback period for biomass based gasifier power generation system was observed to be for Case I from three to four years and for Case II it was one to two years.

Current Situation and Prospects of the Development of China’s Natural Gas Industry

In 2018,China's natural gas market reached a new level of development,with apparent consumption of 280.3 billion m3,up by 18.1%over the same period in the previous year.Domestic production grew steadily,reaching 157 billion m3,up by 7.2%over the same period in the previous year.Natural gas imports grew rapidly,with imports of pipeline gas and LNG totalling 124.2 billion m3.In terms of trade types,imports of LNG continue to exceed those of pipeline gas.In 2019,there has been downward pressure on the macro economy,and the development of the main gas sector has slowed down.Driven by environmental protection policies,the natural gas market continues to maintain rapid growth.However,it is difficult for the levels of increment and growth to reach those of the previous two years,and the growth rate of market demand is predicted to reach 10.7%.

Inter-antenna and subblock shifting and inversion for peak-to-average power ratio reduction in MIMO-OFDM systems

In this article, an inter-antenna inter-subblock shifting and inversion （IASSI） scheme is proposed to reduce the peak-to-average power ratio （PAPR） in multi-input multioutput orthogonal frequency division multiplexing （MIMO- OFDM） systems. It exploits multiple antennas and subblocks to provide additional degrees of freedom to benefit the system. To reduce the implementation complexity of the proposed scheme, two simple suboptimal schemes are further presented based on the minimum current maximum criterion; one adopts sequential search and the other employs random binary grouping. The simulation results exhibit the effectiveness of these proposed schemes.

计及改进阶梯型碳交易和热电联产机组灵活输出的园区综合能源系统低碳调度

为了进一步降低园区综合能源系统(park-level integrated energy system,PIES)碳排放量,优化热电联产(combined heat and power,CHP)机组出力的灵活性,提出一种考虑改进阶梯型碳交易和CHP热电灵活输出的PIES低碳经济调度策略。首先,将遗传算法与模糊控制相结合,设计一种遗传模糊碳交易参数优化器,从而对现有阶梯型碳交易机制进行改进,实现该机制参数的自适应变化;其次,在传统CHP中加入卡琳娜(Kalina)循环与电锅炉(electricboiler,EB),构造CHP热电灵活输出模型,以同时满足电、热负荷的不同需求;然后,提出一种柔性指标——电、热输出占比率,进而计算出电、热输出占比率区间,以衡量CHP运行灵活性;最后,将改进阶梯型碳交易机制和CHP热电灵活输出模型协同优化,以系统运行成本和碳交易成本之和最小为目标,构建PIES低碳经济优化模型。算例分析表明,所提策略可有效降低经济成本和碳排放量,同时还可扩展CHP灵活输出调节范围,能够为PIES低碳经济调度提供参考。

绕组形式对空心杯电机功率的影响

空心杯电机具有体积小和高功率密度等显著优势,被广泛应用于舵机系统中。针对空心杯电机绕组形式的选择大多凭借经验的问题,以相同跨距、相同转速条件下空心杯电机的输出功率为目标,对绕组形式的选择展开了研究分析。计算建立了六边形和菱形绕组的输出功率数学模型,通过仿真和实物功率测试,验证了理论的有效性。结果表明,在相同转速、相同跨距时六边形绕组形式的电机输出功率高于菱形绕组,且随着长径比的增大,六边形绕组电机输出功率的增量高于菱形绕组,在长径比是1.5~2时,具有更高的输出功率。

一种用于传感器模拟前端的可编程增益放大器

基于华虹0.18μm CMOS工艺设计了一款用于传感器模拟前端的可编程增益放大器(PGA),其整体采用全差分结构来抑制传感器输出的共模噪声、直流分量以及供电电源的输出噪声。该电路由仪表放大结构轨对轨输入级、轨对轨自动调零全差分运算放大器、数字控制电路以及直流分量消除电路这四个部分构成,同时采用连续时间自动调零校准技术来降低其输入失调电压。PGA的放大倍数为5 bit调节,共12个档位,分别为1,2,4,8,…,1024,2048倍。在3.3 V电源电压下,PGA输入输出摆幅为0.2~3.1 V。在输入500 mV的直流分量条件下,在-40~125℃的温度范围内,可将直流分量抑制到47.6μV。通过Virtuoso软件进行电路设计、版图绘制以及仿真验证,后仿真结果表明,在进行100次蒙特卡罗仿真下,电源抑制比和共模抑制比在1 kHz处的平均值分别约为110.3 dB和116.1 dB,输入失调电压的1σ值约为21.3μV。

基于MSLM的MIMO-OFDM系统峰值平均功率比减小方案

提出了一种基于多选择性映射(MSLM)的多输入多输出-正交频分复用(MIMO-OFDM)系统的PAPR减小方法。该方法在MIMO-OFDM系统的发送端对发送数据进行等分分组扰码,分组扰码后可以降低PAPR,同时也减少了计算量。仿真结果表明,在没有误码率损失的前提下,当选择支路数为16、互补累积分布函数为10-3时,MSLM方法的PAPR优于传统的SLM(CSLM)方法1.3dB。

一种改进的降低MIMO-OFDM系统峰均比的联合算法

多输入多输出频分复用(MIMO-OFDM)技术是将OFDM与MIMO技术相结合的无线通信系统,它在继承OFDM与MIMO技术诸多优点的同时,具有OFDM系统存在的峰均比(PAPR)较高的问题。选择性映射法(SLM)和预留子载波保留算法(TR)具有很好地抑制PAPR的性能,但是把传统的TR或SLM方法直接运用到MIMO-OFDM系统中却难以达到很好地抑制PAPR效果。为了寻求在MIMO-OFDM系统中改善PAPR性能的同时降低算法实现复杂度,提出一种TR与SLM算法相结合的适合MIMO-OFDM系统的改进算法TR-SLM。通过理论分析与仿真结果表明,TR-SLM级联算法不仅能有效抑制MIMO-OFDM系统的PAPR,同时可减小算法的计算复杂度与系统实现的复杂度。

SFBC MIMO-OFDM系统中基于循环移位和盲检测的低复杂度SLM算法

为了降低空频分组编码的多输入多输出正交频分复用(Space Frequency Block Coding Multiple Input Multiple Output Orthogonal Frequency Division Multiplexing,SFBC MIMO-OFDM)系统中传统选择性映射(Selected Mapping,SLM)算法的计算复杂度,本文提出了结合时域信号的循环移位和等效SFBC编码来产生更多具有不同峰均功率比(Peak to Average Power Ratio,PAPR)的备选序列的方法.接收端通过比较反向旋转序列与最近星座点的距离来恢复出循环移位因子和相位旋转因子,从而实现接收信号的盲检测.仿真结果表明,本文提出方法能有效地抑制SFBC MIMO-OFDM系统的PAPR.另外,本文提出方法明显降低了传统SLM算法的计算复杂度,而且可以获得与传统SLM算法在已知边带副信息情况下相似的比特误码率(Bit Error Rate,BER)性能.

基于SFBC结构的MIMO-OFDM系统峰均比抑制方法

高峰均比已成为SFBCMIMO-OFDM系统推向实用的主要障碍。针对此问题,提出了一种SFBCMIMO-OFDM系统峰均比抑制的新方法,多相旋转交换PIP(polyphase inversion and permutation)方法。该方法将所有发射天线看作一个整体,通过对序列进行2次分割、旋转、交换,既充分利用了各天线子载波之间的共轭和圆周移位特性,又可以结合FFT的运算特性,最大程度上降低了算法复杂度。仿真结果证明了该方法的有效性。

一种降低SFBC MIMO-OFDM系统峰均功率比的新算法

为了降低SFBC MIMO-OFDM系统的峰均功率比,提出了二次部分传输序列(twice-partial transmit sequence,T-PTS)算法.该算法首先对序列进行相邻分割,再对每一个相邻分割子块进行交织分割,然后对相邻子块和交织子块进行两次相位旋转,从中选择具有最小峰均功率比的序列进行传输,以降低峰均功率比.为简化权值的搜索过程,利用SFBC的编码特性及IFFT的圆周移位特性和共轭特性,对T-PTS算法进行次优化处理,引出RT-PTS(reduced T-PTS)算法,旨在最大程度地降低运算复杂度.仿真结果表明,与传统抑制算法相比,RT-PTS算法可以在降低运算复杂度的同时,取得较好的峰均功率比抑制效果.

MIMO-OFDM系统Turbo接收机中的限幅非线性失真迭代对消法

在多入多出的正交频分复用系统中,常采用Turbo接收以保证系统性能。在正交频分复用系统中,限幅技术是常见的峰值平均功率比抑制技术,但限幅带来的非线性失真会造成带内失真和带外辐射,从而恶化系统性能。本文提出可以利用Turho接收机的先验信息进行限幅非线性失真的迭代对消,从而在引入少量复杂度的基础上,对抗限幅带来的影响。仿真结果表明,引入限幅非线性失真迭代对消算法可以有效提高系统性能,限幅门限越低效果越明显。

引入深度限幅技术的MIMO-OFDM系统PAPR抑制优化算法

针对多输入多输出正交频分复用(MIMO-OFDM)通信系统存在的峰值平均功率比(PAPR)较高的问题,将深度限幅技术和具有很好PAPR抑制性能的预留子载波保留(TR)算法进行了改进优化,提出了一种深度限幅优化的TR算法,并将该算法应用于MIMO-OFDM系统的PAPR抑制性能研究。该算法将系统中的一个天线深度限幅后的补充信号进行处理,然后再应用到其它天线上。通过理论分析与仿真结果表明,该算法不仅能有效抑制MIMO-OFDM系统的PAPR,同时可减小算法的计算复杂度和降低系统误码率。

降低MIMO-OFDM系统峰均比的分解并行选择映射算法

高峰均功率比(peak-to-average power ratio,PAPR)问题是多输入多输出正交频分复用(multiple-input multiple-output orthogonal frequency division multiplexing,MIMO-OFDM)系统实用化的主要障碍之一,针对这一问题提出了一种分解并行选择映射(decomposed concurrent selected mapping,D-CSLM)算法,进一步提高了算法的峰均比性能。所提算法将每根天线上OFDM符号分解为实部和虚部,分别采用相同的相位因子,在进行逆离散傅里叶变换(inverse discrete Fourier transform,IDFT)之后进行组合,选择使所有天线具有最小平均峰均比的信号进行传输。与原有的并行选择映射算法相比,所提算法具有更大的待选信号范围,峰均比降低性能更好。同时,利用实序列固有的共轭对称特性,使算法的计算复杂度保持不变。仿真结果证明,该算法在保持计算复杂度不变的前提下,显著改善了系统的峰均比性能。

基于SFBC MIMO-OFDM系统的峰均比抑制算法

与联合空时编码的多输入/多输出的正交频分复用(STBC MIMO-OFDM)系统比较,联合空频编码(SFBC)的MIMO-OFDM系统具有更优的抗多径时变衰弱信道能力,已被TD-LTE制式采用。针对SFBC MIMO-OFDM系统存在峰值平均功率比过高的问题,提出一种低复杂度的子块间空频变换算法。首先在频域上,对所有天线的空频分组码序列进行均等分块,对天线间相应子块进行交叉反向产生候选序列,并从候选序列中选择PAPR最小序列。然后,在时域上对各天线内子块同步进行逐次循环移位,进一步选择最优PAPR序列进行传输。通过结合IFFT特性和SFBC特性分析实现大幅度降低算法复杂度。仿真结果证明在保证SFBC正交性的基础上,算法具备有效性和可靠性。