Abstract
The article provides a brief classification of electromechanical dampers in vehicle suspensions. As investigated version of design of electromechanical shock absorber is suggested model with ball-screw drive of generator as investigated version of design of electromechanical shock absorber. The main components of the damping force are indicated: the force of inertia and the force of electromagnetic resistance. The given resistance forces are expressed taking into account the drive parameters. Presented mathematical model of electromechanical suspension damper of vehicle wheels considers parameters of motion as vehicle speed and height, and length of overcome irregularity is taken into account. Suggested model makes it possible to determine kinematic parameters of movable elements of electromechanical damper values of inertial and electromagnetic components of damping force and also generated electric energy, on conditions of vehicle movement and connected external load. Due to the presented dependencies, it was revealed that when determining the power of the generator for operation as part of an electromechanical damper, the most significant parameters are the rotation speed and efficiency of the generator, which in turn depend on the rotation speed of its rotor and the load connected to the stator outputs. The interrelationships presented in the work make it possible to investigate the influence of mass size and electromagnetic parameters of elements of electromechanical dampers on their operating characteristics, to use them as recommendations when designing electromechanical dampers.
Access provided by Autonomous University of Puebla. Download conference paper PDF
Similar content being viewed by others
Keywords
1 Introduction
When moving the vehicle, the energy of mechanical vibrations in damping devices of wheel suspensions, which is significant, can be recovered into electric and then used in the onboard vehicle network, thereby reducing fuel consumption of cars with ICE operating on hydrocarbon fuel or increasing the range for electric vehicles. [1,2,3] Several embodiments of the electromechanical shock absorber are known [4,5,6]:
-
Electromechanical shock absorber with hydraulic drive [10];
-
Electromechanical shock absorber with mechanical drive [11, 12];
-
Electromechanical shock absorber driven by ball-screw transmission, etc. [13, 14].
To study the effect of various design parameters of the electromechanical shock absorber on its performance, a physical model of the most promising damper equipped with a ball-screw drive and a rotary type generator is proposed (Fig. 1).
The principle of electromechanical shock absorber operation with a ball-screw drive consists the following: reciprocating movements of wheels relative to vehicle body perceived by eyelet, housing, and nut of ball-screw drive are converted into rotary movement of ball-screw drive shaft, which in turn drives generator rotor.
2 Methods and Equipment
When evaluating the damping and recuperative properties of the electromechanical shock absorber, two main components should be taken into account: mechanical, depending on the design parameters of the electromechanical shock absorber, and electromagnetic, depending on the operating characteristics of the generator and the external electrical load connected.
Inertial components include the force of inertia (N) in the case of reciprocating motion and the inertial moment (N m) of resistance in the case of rotational motion of electromechanical shock absorber elements, including the generator rotor, determined by formulae (1) and (2), respectively.
where m—weight, kg; a—acceleration of the body, m s2.
where J—moment of inertia of the rotating body, kg m2; ε—angular acceleration of a body, radian/s.
Moment of inertia of the rotating body, kg m2:
where r—distance from axis to elementary mass dm, m; dV—elementary volume occupied by dm, m; ρ—body density at the point where dm is, kg/m3.
Electromechanical component can be estimated by moment of resistance on generator rotor shaft, N m:
where Ne—generator electric power at ω, W; ηg—efficiency of the generator at ω and Ne; ω—angular speed of generator rotor rotation, radian/s.
The reduced force from the moments of the inertial and electromagnetic resistance elements to the nut of the ball-screw drive (bsd) is expressed taking into account the parameters of the drive expressed by Eq. (5), H:
where M—driven moment, (N m); P—ball-screw transmission pitch, (m); Ηbsd—efficiency of ball-screw transmission.
The ratio of the rotation angle of the ball-screw gear shaft to the amount of movement of its nut is determined by the dependence:
where x—nut movement, m; k—number of ball-screw gear thread starts.
To assess the effect of electromechanical shock absorber on suspension operation as a whole, a mathematical model of vehicle suspension with electromechanical damper has been compiled (Fig. 2).
Figure 3 shows the model of the vehicle suspension with disturbing effect and without taking into account the stiffness of tires and ground C(t+g), so the ground and tire of the wheel are accepted as absolutely solid bodies.
Fe—elastic force of springs, N; Fd—the strength of the damping, N; X—mixing of unsprung mass (nut movement), m.
For the maximum comfort of the driver and passengers in the car, it will be ideal if the movement of the body, i.e., the sprung mass of the car, is zero (xu = 0) under any disturbing effects. It is necessary to determine the resistance force at which this condition will be met.
The sprung part of the vehicle can start to move upward if the spring begins to expand or if the resistance force of the shock absorber is too high, as a result of which all the load from the unsprung part will be transferred to the sprung mass.
Equilibrium equation of this system:
where ẍs—acceleration of the compressed mass, m/s2; ẋu—speed of unsprung mass movement, m/s; ẋs—speed of the compressed mass movement, m/c.; g—acceleration of free fall, m/s2; ms—sprung weight, kg; Kd—damping coefficient, N∙s/m; Cs—spring stiffness, N/m; Fu—equal to all forces on the wheel transmitted from the unsprung part, N.
To ensure the immobility of the pressed mass, Eq. 7 should take the form:
In order for the spring part to be stationary, it is necessary that the gravity of the spring mass, together with the forces generated in the suspension itself, be compensated by the force transmitted from the spring part.
Force Fu—equal to all forces on the wheel transmitted from the unsprung part is:
where mu—unsprung mass, kg.
Consider the most interesting part of the presented model—the damping coefficient Kd, which is a characteristic of an electromechanical shock absorber, depending on its controlled and constant parameters. The damping coefficient characterizes the force of resistance to the movement of the ball-screw gear nut relative to the shaft depending on the driving conditions and is composed of the given forces and moments of inertia Fi,, as well as the reduced electromechanical force of resistance Fem to the ball-screw gear nut.
The law of movement of the wheel from disturbing effects of the road is represented by Eq. (10):
where A—amplitude, m; ω—frequency, Hz; t—time, s.
Then, the law of movement of the ball-screw gear nut as part of the electromechanical shock absorber:
where is—gear ratio of vehicle wheel suspension.
Converting Eq. 11 to describe the vehicle motion conditions taking into account the following parameters:
-
vehicle speed, Sv (m/s);
-
height of the unevenness to be overcome, A (m);
-
length of irregularity, λ (m);
we will receive:
Figure 4 graphically shows the dependencies of movement (x), speed (ẋ) and acceleration (ẍ) of unsprung mass on time.
The condition of the ball-screw drive shaft of the electromechanical shock absorber is described by the following equations:
These equations are also true for the generator rotor in the case of direct drive of the generator (Fig. 1). If a multiplier is used to increase the rotor speed of the generator, the equations of its motion will take the form:
where \(i_{{\text{m}}}\)—multiplier gear ratio.
According to a given law of motion, it is possible to determine the state of the movable parts of the electromagnetic damper at any moment in time, therefore, to determine the effect of weight and size and design parameters on the operation of the damper as a whole.
So the force of inertia from the reciprocating parts, we define from the equation, N:
where ∑mi—sum of masses moving with one acceleration.
The damper under investigation is represented as a link consisting of inertial and electromagnetic elements connected in parallel to Fig. 5.
Inertial moment of resistance from rotating elements of damper is equal to product of angular acceleration at moment of inertia, N m:
where ∑Ji—sum of moments of inertia of elements moving with one angular acceleration.
For elements installed after the multiplier, N m:
The reduced force to the upper eye of the damper from the inertial moment of resistance is, N:
with multiplier:
Electromechanical moment of resistance of electromechanical shock absorber is expressed, N m:
where U—voltage in the circuit, V; R—load resistance, Ohm; r—reactance, Ohm; ηg—generator efficiency.
or:
where I—current in the circuit, A.
The reduced force to the upper eye of the damper from the electromechanical moment of resistance is, N:
or:
3 Research Results
It follows from the above that the sum of all forces brought to the nut of the electromechanical shock absorber ball-screw drive will be the resistance force of the damper.
Since the only controlled parameter in Eq. (30) is Fem(x)—the electromechanical resistance force brought to the upper lug of the damper, it is advisable to consider it as the main component when calculating the characteristics of the elements of the electromechanical damper and express the electromechanical resistance force from Eq. (30).
From Eqs. (4)–(6), we express the generated electric power of the generator, W:
where Fem—reduced damping force to the upper eye of the shock absorber from the moment of generator resistance, N.
It can be seen from Eq. (32) that when determining the power of a generator for operation as part of an electromechanical damper, the most significant parameters are the rotation speed and efficiency of the generator, which in turn depend on the rotation speed of its rotor and the load connected to the stator outputs.
4 Conclusions
The use of an electromechanical shock absorber in vehicle suspensions will allow changing the damping level in a wide range, as well as using recuperable energy to perform useful work. The presented dependencies can be used when studying the effect of mass and electromagnetic parameters of electromechanical shock absorber elements on its properties, as well as recommendations for designing an electromechanical shock absorber. To reduce the effect of inertia forces on the generator drive, for example, it is possible to use generators with a smaller rotor radius, with equal power characteristics, and also it is possible to install elastic and friction elements between the generator rotor and the ball-screw transmission shaft.
References
Nikonov VO, Posmet'ev VI (2018) Sostoyanie problemy i analiz konstruktsij sistem rekuperatsii ehnergii v podveskakh kolesnykh mashin (State of the problem and analysis of the structures of energy recovery systems in the suspensions of wheeled vehicles). Voronezhskij nauchno-tekhnicheskij vestnik
Posmet'ev VI, Drapalyuk MV, Zelikov VA (2012) Otsenka ehffektivnosti primeneniya sistemy rekuperatsii ehnergii v podveske avtomobilya (Evaluation of the efficiency of the energy recovery system in the vehicle suspension). Nauchnyj zhurnal KubGAU
Okladnikov DL, Zeer VA, Grazhdantsev EV, Avdeev RM, Akhremov SA (2019) Energy recovery method of damping oscillations of the vehicle suspension. IOP Mater Sci Eng 537:032074:1–7. https://doi.org/10.1088/1757-899x/537/3/032074
Klimov AV, Karelina MYu (2017) Vybor tipa konstruktsii i opredelenie parametrov i kharakteristik amortizatora s rekuperativnym ehffektom (Selection of the type of structure and determination of parameters and characteristics of the damper with regenerative effect). Trudy NAMI
Sergienko AN, Lyubarskij BG, Samorodov VB, Sergienko NE (2012) Analiz konstruktsij ehlektromekhanicheskikh preobrazovatelej i vybor skhemy ehlektroamortizatora nepodressorennykh mass transportnogo sredstva (Analysis of the designs of electromechanical converters and the choice of an electric shock absorber circuit for unsprung mass vehicles). Avtomobil'nyj
Okladnikov DL, Perikov DS, Sorokin AA, Evseev PP (2013) K voprosu ispol'zovaniya ehlektromagnitnykh ustrojstv v podveskakh avtobilej (On the use of electromagnetic devices in car suspensions). Tret'ya vserossijskaya nauchno-tekhnicheskaya konferentsiya “Sovremennaya tekhnika i tekhnologii: problemy, sostoyanie i perspektivy”, Rubtsovsk
Demetgul M, Guney I (2017) Design of the hybrid regenerative shock absorber and energy harvesting from linear movement. J Clean Energy Technol 5:81–84. https://doi.org/10.18178/jocet.2017.5.1.349
Sarbayev VI, Garmash UV, Blinnikova LG (2016) Rekuperativnyy amortizator (Regenerative shock absorber). Vestnik mashinostroyeniya
Oprea CA, Martis CS, Jurca FN, Fodorean D, Szabó L (2011) Permanent magnet linear generator for renewable energy applications: Tubular vs. four-sided structures. Clean electrical power (ICCEP), pp 588–592. https://doi.org/10.1109/iccep.2011.6036316
Avadhany S, Abel P, Tarasov V, Anderson L (2011) Regenerative shock absorber. CN Patent 102007008:6
Khushal A, Monis A (2017) Design and simulated analysis of regenerative suspension system with hydraulic cylinder, motor and dynamo. SAE technical paper series. https://doi.org/10.4271/2017-01-1284
Li Z, Zuo L, Luhrs G, Lin L, Qin Y (2013) Electromagnetic energy-harvesting shock absorbers: design, modeling, and road tests. IEEE Trans Veh Technol 62:1065–1074. https://doi.org/10.1109/tvt.2012.2229308
Zeer VA, Okladnikov DL, Filatov AN, Golubtsov DI (2020) Electromagnetic shock absorber with regenerative effect. RU 2714331 C1 4 Feb 2019
Kireev AV, Kozhemyaka NM, Grebennikov NV (2017) Energy-regenerative shock absorber mathematical model. Proc Eng 206:1741–1746. https://doi.org/10.1016/j.proeng.2017.10.707
Author information
Authors and Affiliations
Corresponding author
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 2022 The Author(s), under exclusive license to Springer Nature Switzerland AG
About this paper
Cite this paper
Okladnikov, D.L., Zeer, V.A., Grazhdantsev, E.V. (2022). Development of a Mathematical Model of Electromechanical Dampers with a Regenerative Effect in Vehicle Wheel Suspensions. In: Radionov, A.A., Gasiyarov, V.R. (eds) Proceedings of the 7th International Conference on Industrial Engineering (ICIE 2021). ICIE 2021. Lecture Notes in Mechanical Engineering. Springer, Cham. https://doi.org/10.1007/978-3-030-85230-6_23
Download citation
DOI: https://doi.org/10.1007/978-3-030-85230-6_23
Published:
Publisher Name: Springer, Cham
Print ISBN: 978-3-030-85229-0
Online ISBN: 978-3-030-85230-6
eBook Packages: EngineeringEngineering (R0)