Remanence Compensation of Maglev Planar Motor Based on Digital Twin Model
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摘要:
为提升磁浮平面电机发生退磁故障后的控制性能,提出一种针对永磁体阵列的剩磁补偿方法,并通过数字孪生模型对所提方法进行有效性验证. 首先,构建基于数字孪生五维模型的磁浮平面电机数字孪生框架,明确5层架构的组成部分;其次,利用磁荷节点模型探讨动子周围磁场与剩余磁化强度的关系,获得剩磁反演表达式,并在运动解耦过程中引入反演获得的剩磁数据,得出剩磁补偿后的控制电流;最后,利用不同退磁分布的磁浮平面电机孪生体数据,反演得到剩磁数值,通过多组轨迹跟踪仿真实验,对比无退磁、忽视退磁影响、剩磁反演补偿3种情况下的运动模拟. 研究结果表明:与忽视退磁影响相比,采用剩磁反演补偿方法,水平方向上进行斜坡轨迹跟踪的均方根误差减小56.5%,最大误差减小40.9%;平面运动阶跃响应稳定时间减少41.3%,超调量减少15.7%;圆轮廓跟踪时,轮廓误差的均方根减小85.0%,最大误差减小38.9%.
Abstract:A remanence compensation method for permanent magnet arrays was proposed to enhance the control performance of maglev planar motors after demagnetization faults, and the effectiveness of the proposed method was verified by a digital twin model. Firstly, a digital twin framework for maglev planar motors based on a five-dimensional digital twin model was constructed, and the components of the five-layer architecture were clarified. Secondly, the relationship between the magnetic field around the mover and the residual magnetization intensity was explored by using a magnetic charge node model to obtain a remanence inversion expression. Then, the inverted remanence data were introduced into the motion decoupling process to derive the control current after remanence compensation. Digital twin data of maglev planar motors with different demagnetization distributions were used to obtain remanence values through inversion. Multiple trajectory tracking simulation experiments were conducted to compare motion simulations under three conditions: no demagnetization, neglecting demagnetization effects, and remanence inversion compensation. The results show that compared with neglecting demagnetization effects, the remanence inversion compensation method reduces the root mean square error of horizontal ramp trajectory tracking by 56.5% and the maximum error by 40.9%. The setting time in planar motion step response is decreased by 41.3%, and the overshoot is reduced by 15.7%. When a circle contour is tracked, the root mean square of contour error is decreased by 85.0%, and the maximum error is reduced by 38.9%.
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Key words:
- maglev planar motor /
- digital twin /
- remanence compensation /
- trajectory tracking
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图 3 磁浮平面电机结构及磁荷节点分布
Figure 3. Structure of maglev planar motor and distribution of magnetic charge nodes
表 1 磁浮平面电机结构参数
Table 1. Structural parameters of maglev planar motor
参数 数值 永磁体尺寸
$ {L_m} $,$ {W_m} $,$ {H_m} $/ mm40,10,10 动子质量$ m $/ kg 2.37 线圈尺寸
$ {L_c} $,$ {W_c} $,$ {H_c} $,$ {R_c} $/ mm60,10,10,10 线圈匝数$ {N_{{\text{coil}}}} $/匝 300 转动惯量
$ {I_\alpha } $,$ {I_\beta } $,$ {I_\gamma } $/ (kg•m2)9.38 × 10−3,9.38 × 10−3,1.87 × 10−2 
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表 2 永磁体退磁率分布
Table 2. Demagnetization rate distribution of permanent magnets
阵列 基本无退磁 轻度退磁 重度退磁 阵列1 2,3,4,5,7,8,9,10,11,12 1 6 阵列2 1,2,4,5,6,7,10,11,12 3,8,9 阵列3 1,2,3,5,6,7,8,10,11,12 9 4 阵列4 1,2,3,4,5,7,9,10,12 6,8,11
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表 3 剩磁反演误差分析
Table 3. Error analysis of remanence inversion
erms/T emap/% R2 0.011 0.67738 0.99549
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表 4 气隙磁感应强度误差分析
Table 4. Error analysis of air gap magnetic flux density
阵列位置 条件 erms/T emap/% 阵列1 条件1 0.016939 45.1079 条件2 0.001293 3.6183 阵列3 条件1 0.015386 28.4291 条件2 0.001790 3.9413
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表 5 斜坡轨迹跟踪控制性能
Table 5. Control performance for ramp trajectory tracking
速度/(mm·s−1) 性能指标 方向 ${{C}}_{{\mathrm{ideal}}} $ ${{C}}_1 $ ${{C}}_2 $ 40 erms x 0.00099 0.00586 0.00265 y 0.00089 0.00616 0.00268 emax x 0.00527 0.02266 0.01344 y 0.00551 0.02436 0.01440 10 erms x 0.00074 0.00171 0.00079 y 0.00070 0.00160 0.00091 emax x 0.00224 0.00699 0.00236 y 0.00221 0.00702 0.00223
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表 6 阶跃响应性能指标
Table 6. Performance metrics for step response
性能指标 方向 Cideal C1 C2 响应时间/ms x 24 63 37 y 27 63 39 超调量/mm x 0.7327 0.9007 0.7758 y 0.7077 0.9034 0.7616
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表 7 圆轮廓跟踪性能
Table 7. Performance of circular contour tracking
性能指标 Cideal C1 C2 εrms/mm 0.0015 0.0113 0.0017 εmax/mm 0.0156 0.0275 0.0168
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