초록 ▼

A method estimates parameters for a self-energized brake mechanism having a moving part, a brake pad, a brake disc, a caliper, and a wedge profile. The method includes the following acts: applying the same actuator force to the brake mechanism and simultaneously to a dynamical model of the brake mec

A method estimates parameters for a self-energized brake mechanism having a moving part, a brake pad, a brake disc, a caliper, and a wedge profile. The method includes the following acts: applying the same actuator force to the brake mechanism and simultaneously to a dynamical model of the brake mechanism; calculating deviations based on measured state variables of the brake mechanism and simulated state variables of the dynamical model; and producing the estimated parameters by online minimization. A device is provided for executing the method.

대표청구항 ▼

1. A method for estimating parameters for a self-energized brake mechanism having a moving part, a brake pad, a brake disc, a caliper, and a wedge profile, the method comprising the acts of: applying a same actuator force to the brake mechanism and simultaneously to a dynamical model of the brake me

1. A method for estimating parameters for a self-energized brake mechanism having a moving part, a brake pad, a brake disc, a caliper, and a wedge profile, the method comprising the acts of: applying a same actuator force to the brake mechanism and simultaneously to a dynamical model of the brake mechanism;calculating deviations based on measured state variables of the brake mechanism and simulated state variables of the dynamical model; andproducing the estimated parameters by online minimization,wherein the parameters are a friction coefficient and an air gap of the brake pad and the brake disc,the act of calculating deviations comprises the acts of: calculating relative deviations: ɛva=vames-vasimvamax,⁢ɛxa=xames-xasimxamax,and calculating a summed weighted deviation: εc=(wxaεxa+wvaεva),the dynamical model is: [x.av.a]=[f1⁡(x)f2⁡(x,d)]+[g1g2]⁢uwhere state and input coordinate functions are as follows: f1⁡(x)=va,⁢f2⁡(x,d)=(k0⁢va⁢tan⁢⁢φw+s0⁡(xa⁢tan⁢⁢φw-δ))⁢(μ⁢⁢cos⁢⁢φw-sin⁢⁢φw)m1,⁢g1=0,⁢g2=1m1⁢cos⁢⁢φathe online minimization is provided by a proportional and an integral portion of the sum deviation: μn+1=(Pμεc+Iμ∫εcdt)+μ,δn+1=−(Pδδc+Iδ∫εcdt)+δn,where P and I are minimization parameters, andthe estimated parameters are adjusted alternately in time. 2. The method according to claim 1, wherein one of: (a) a speed of the moving part is measured, and (b) a position of the moving part is measured and the speed is reconstructed from the measured position. 3. The method according to claim 1, wherein the online minimization is provided by at least one of a gradient method and a simplex method. 4. The method according to claim 1, wherein the estimated parameters are fed back to the dynamical model. 5. A device for parameter estimation for a self-energized brake mechanism having a moving part, a brake pad, a brake disc, a caliper, and a wedge profile, the device comprising: a brake mechanism with one or more measuring devices for state variables;a dynamical model for calculating one or more simulated state variables, wherein the dynamical model is based on the equations: [x.av.a]=[f1⁡(x)f2⁡(x,d)]+[g1g2]⁢u where state and input coordinate functions are as follows: f1⁡(x)=va,f2⁡(x,d)=(k0⁢va⁢tan⁢⁢φw+s0⁡(xa⁢tan⁢⁢φw-δ))⁢(μcos⁢⁢φw-sin⁢⁢φw)m1,g1=0,g2=1m1⁢cos⁢⁢φa;a deviation unit for comparing the one or more measured state variables and the one or more simulated state variables, wherein calculated relative deviations are determined in accordance with the equations: ɛva=vames-vasimvamax,⁢ɛxa=xames-xasimxamax, and a summed weighted deviation is calculated in accordance with the equation: εc=(wxaεxa+wvaεva); anda minimization unit for providing estimated parameter values, wherein minimization is provided by a proportional and an integral portion of the sum deviation: μn+1=(Pμεc+Iμ∫εcdt)+μn,δn+1=−(Pδεc+Iδ∫εcdt)+δn, where P and I are minimization parameters, and estimated parameters are adjusted alternately in time, wherein inputs of the brake mechanism and the dynamical model are connected in parallel and outputs of the minimization unit are connected with the dynamical model for feed back,wherein the parameters are a friction coefficient and an air gap of the brake pad and the brake disc. 6. The device according to claim 5, wherein the brake mechanism comprises a reconstruction unit for reconstructing speed values from measured position values. 7. The device according to claim 6, wherein the reconstruction unit comprise one of a derivation unit and PLL-filters. 8. The device according to claim 5, wherein the device is part of a brake controller.