TH72245B - Dynamometer control device And a method for estimating the moment of inertia using that device - Google Patents

Abstract

To provide dynamometer control equipment Consequently, stimulation control can be implemented so that resonant behavior does not occur. Even when the moment of inertia of the engine Mai 'is known Dynamometer 6 controls are provided along with the generating unit. Excitation 61 for generating a random fluctuating excitation signal. Or, in turn, a 62-speed regulator for generating an input signal to the dynamometer. Hence the speed of rotation The dynamo is matched to the rotational speed from the predetermined dynamo instruction, the torque compensator from shaft 64, for generating an input signal to the dynamometer. For this reason the vibration of The shaft for connecting the engine and dynamometer can also be demolished by using the sensing value of Shaft torque sensor and 65 boost for generating torque current command signal by adding The input signal is produced by the speed regulator 62 and the torque compensator from shaft 64 to the excitation signal.

Claims (5)

Disclaimer (all), which will not appear on the advertisement page: Amendments 28 Oct. 2019 No disclaimers. -------------------------------------------------- ------------------------ 1. A dynamometer control device that generates a torque command signal to the dynamometer that is connected to the specimen via a shaft. Which the dynamometer control device includes Rotational speed detector, which detects the rotational speed of a dynamometer, shaft torque sensor, which detects the torque from the shaft acting on the shaft, the excitation signal generating unit, which produces the excitation signal. A stimulus that fluctuates randomly or amalgamated at the speed regulator. Which produces an input signal to the dynamometer In such a way that the value of The gyroscope detection sensor is matched with the speed of rotation from a predetermined command, the shaft torque compensator, which produces an input signal to the dynamometer in such a way that it vibrates. The shaft has also been wrinkled using a torque sensor sensing value from the shaft. And the booster, which produces the torque command signal by adding the input signal that is generated by the speed controller and the torque compensator from the shaft, to the excitation signal. 2. The dynamometer control device according to claim 1, where the torque compensator from the shaft produces an input signal to the dynamometer. By passing the shaft torque sensor sensing signal through a high-pass filter or a band-pass filter Where the pass-band of the high-pass filter or the pass-band filter includes the resonance frequency of the mechanical system including the specimen and dynamometer. 3. The dynamometer control device according to claim 1 or 2, where the control device is further integrated with a low-pass filter that attenuates the resonant frequency component of a mechanical system including the test specimen and the dynamometer. From the speed controller output signal 4. The dynamometer control device according to claim 3, where the speed regulator will generate an input signal to the dynamometer. It is in accordance with the characteristic IP regulation with Kp axial gain and integral gain Ki, where the rotational speed and rotational speed sensing value from the command is sent in where The low-pass filter has been optimized. Especially by the frequency that has been eliminated C0LPF / 271 where Kp proportional gain, Ki integral gain, and C0LPF / 27T truncated frequency. Bounded to comply with the subsequent formula and where in the subsequent formula J is the sum of the moment of inertia of the dynamometer and the specimen. Or the estimated value of that and C0C is a positive real number Kp = J-coc, Ki = (J-oxr) / 3, coLPF = 3coc. 5. Method of Moment of Inertia Estimation Method for estimating the moment of inertia of an engine using a test system, including a dynamometer, which is connected to the engine acting as a test operator via a shaft. Dynamometer, which controls the output of the dynamometer, engine control device, which controls the output of the shaft torque sensing engine, which detects the torque from the shaft acting on the shaft. And the gyroscope, which detects the rotational speed of the dynamometer, which the assembly method is Procedure for excitation control for the actuation of the dynamometer output torque by means of the dynamometer control device. While maintaining the engine rotational speed with a predetermined target rotational speed by means of the engine control device The data acquisition procedure for obtaining the axle torque sensor and the rotational speed senser for a predetermined time frame. While performing the actuation control procedure, the calculation of the transfer function for calculating the transfer function is performed. At 1 which torque From shaft as input and rotational speed as output By using the information that has been obtained in the process of obtaining information And an approximation procedure for estimating the moment of inertia of the engine using the transfer function calculated in the transfer fission calculation procedure where In the process of controlling arousal Stimulation control is performed using Control equipment according to any of Clause 1 to 4 It is a dynamometer control device.