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Article

Mechanism and Optimization of a Novel Automobile Pneumatic Suspension Based on Dynamic Analysis

1
Engineering Training Center, Beihang University, Beijing 102206, China
2
School of Automation Science and Electrical Engineering, Beihang University, Beijing 100191, China
*
Authors to whom correspondence should be addressed.
Electronics 2021, 10(18), 2232; https://doi.org/10.3390/electronics10182232
Submission received: 13 August 2021 / Revised: 8 September 2021 / Accepted: 9 September 2021 / Published: 11 September 2021
(This article belongs to the Special Issue Advanced Research in Electromagnetic Devices for Electric Vehicles)

Abstract

:
Pneumatic suspension is the most significant subsystem for an automobile. In this paper, a simplified and novel pneumatic spring structure with only a conical rubber surface is presented and designed to reduce the influence of external factors besides the pneumatic. The nonlinear stiffness of the pneumatic spring is analyzed based on the ideal gas model and material mechanics. Natural frequency analysis and the transmission rate of the pneumatic suspension are obtained as two effect criteria for the dynamic model. The vibration isolation system platform is established in both simulation and prototype tests. With the results from the simulation, the rules of the pneumatic suspension are analyzed, and the optimal function of mass and pressure is achieved. The experiment results show the analysis of the simulation to be effective. This achievement will become an important basis for future research concerning precise active control of the pneumatic suspension in vehicles.

1. Introduction

In vehicle dynamics, the suspension system is an important part of the composition for driving comfort and stability [1]. Pneumatic springs have been widely used in automobiles as well as in maglev and rail vehicles [2,3]. As one of the core components of automobile vibration isolation systems, a pneumatic spring can change the stiffness in response to driving conditions by changing the gas pressure inside the air spring volume [4]. This adjustment has a direct impact on automobile comfort. Compared with the traditional spring mechanism, a pneumatic spring has the advantages of low natural frequency, variable stiffness range, and high energy storage [5,6,7,8], and has better vertical vibration isolation [9,10]. Moreover, the nonlinear stiffness and damping properties can enhance the attenuation of ride quality and handling performance for large payload variations [11].
In recent years, great achievements have been made in the research of pneumatic springs. F Chang et al. analyzed the dynamic model of an air spring used in vehicles through MATLAB/Simulink and ADAMS [12]. Hengmin Qi et al. developed an electronic-controlled pneumatic spring to improve the stability and ride comfort of a 9-DOF vehicle [13]. Chai studied the mechanical characteristics of automobile air springs based on the finite element method [14]. Zhong studied the nonlinearity of the pneumatic vibration isolation system through frequency analysis [15]. M.M. Moheyeldein analyzed the parameters of air spring and passive suspensions and investigated the influences of air spring model parameters on vehicle dynamics [16]. Li Yuyan designed a pneumatic spring with a natural frequency below 1 Hz and evaluated the vibration isolation effect through vibration isolation transmissibility and vibration isolation efficiency [17]. Yin et al. developed a predictive method of effective area of rolling lobe air spring for vehicles [18]. Active suspension technology is also under development with control methods such as T-S fuzzy [19], model predictive control (MPC) [20,21], deep learning [22], sliding mode [23], and BP neural networks [24] applied in engine systems [25], steering systems [26], and driving systems [27] of vehicles.
In this study, a simple and novel structure of a pneumatic spring is proposed. The stiffness of the spring is analyzed, and a dynamic model of the vibration isolation system is established based on the ideal gas equation and material mechanics [28]. Based on the results of our simulation, the influence of the pneumatic spring parameters on the vibration isolation system performance is presented, showing that optimal function has been achieved. Finally, a summary of the results and conclusions is presented.

2. Dynamic Model of the Pneumatic Vibration System

2.1. Nomenclature Table for Main Parameters

For convenient application, the main symbols of the pneumatic spring parameters are shown in Table 1.

2.2. Structure of the Pneumatic Spring

Three types of springs can be used for vehicle vibration isolation systems, but rolling lobe air springs (RLAS) are commonly used in vehicle suspensions for better transmission performance [29]. In this study, to simplify the model and analyze the mechanism of the pneumatic characteristic directly, a simple and novel pneumatic spring structure is presented, and the structure sketch and 3D model of the pneumatic spring are shown in Figure 1.
The nonlinear characteristic of rubber with multi-layers of composite materials of different thicknesses and different original pressures is difficult to analyze. In the structure shown in Figure 1, the floating platform is connected to the fixed bogie with a conical rubber surface. The influence of the nonlinear rubber is limited by the simple structure.

2.3. Stiffness Analysis of the Pneumatic Spring

For the classical model of a pneumatic spring in the literature, the characteristic can be calculated using the ideal gas equation:
p g V = m g R T
where pg denotes the absolute pressure of the pneumatic spring, V means the gas volume in the cavity, mg is the gas mass, R is the molar gas constant, and T means the temperature in the cavity. Air molecule interaction and volume are ignored in the ideal gas model, and the ideal gas equation is suitable for an environment under 10 MPa with normal temperature [30]. Compared with other models, such as the van der Waals equation, the ideal gas equation reduces the amount of calculation involved while ensuring the reliability of the results.
According to the parameters shown in Figure 2, the volume of the air spring can be calculated as:
V = π D 2 2 4 L 1 + 0 x π ( D 1 2 + ( D 2 D 1 2 x ) h ) 2 d h
The result can be integrated as:
V = π D 2 2 4 L 1 + π D 1 2 + D 2 2 + D 1 D 2 12 x
where L1, D1, and D2 are the geometric parameters of the air spring cavity. L1 denotes the length of the air spring cavity, D1 is the diameter of the floating platform, D2 is the diameter of the fixed platform, and x is the floating displacement. With the new index ε and the effective area Aef introduced, the equation can be simplified as:
V = A e f ( 3 L 1 + ( ε 2 + ε + 1 ) x ) 4
where ε = D1/D2, and the effective area Aef can be calculated as A e f = π ( D 2 2 ) 2 . Through this derivation, the stiffness characteristic of the pneumatic element can be obtained as:
k k = F p x = ( P g P 0 ) A e f x = ( P g P 0 ) x A e f + A e f x ( P g P 0 )
where kk denotes the stiffness of the air, Fp is the vertical force, and P0 is the pressure of the atmosphere. The gas condition change determines that it is polytrophic; therefore, the following equation is valid:
p g V λ = const
where λ is the polytrophic coefficient. If the internal temperature is constant, then λ = 1. If part of the gas cannot complete the heat exchange process within a short time or there is not much heat exchange and it is regarded as an adiabatic process, then λ is recorded as 1.4. From Equation (2) to Equation (6), Equation (7) is differentiated as follows:
P g x = P g λ V V x = P g λ A e f ( ε 2 + ε + 1 ) 4 V
In this pneumatic spring model, the effective area is a constant. Referring to Equations (5) and (7), the stiffness of the air can be expressed as:
k p = P g λ A e f 2 ( ε 2 + ε + 1 ) 4 V

2.4. Stiffness Analysis of the Rubber

In this pneumatic spring, the rubber is the connector between the pneumatic cavity and the fixed bogie. Within the structure, the influence of the rubber’s nonlinear characteristic is limited and mainly affects the boundary stiffness of the spring. As shown in Figure 3, the rubber has a conical surface and can be regarded as a series of ring springs. It is assumed that the rubber material presents a smooth characteristic. Based on the material mechanics, the stiffness of the rubber can be integrated as:
k x = 1 i = 1 n 1 Δ k x = 1 i = 1 n Δ l E S i = 1 i = 1 n Δ l E ( ( D 1 + D 2 D 1 n i + δ ) 2 ( D 1 + D 2 D 1 n i ) 2 )
where E denotes Young’s modulus of the rubber, l is the vertical elongation of the rubber, S is the interface area of the rubber, x0 is the activating length of the rubber spring, δ is the thickness of the rubber, Δl is an element of the rubber spring, and n is the number of the element that can be calculated as n = ll. The boundary stiffness is considered as the parallel of the air and the rubber. Thus, the stiffness of the pneumatic spring can be determined from the aforementioned equations as follows:
k = { k p x x 0 k x + k p x > x 0

3. Analysis of the Vehicle Pneumatic Vibration Isolation Model

3.1. Dynamic Model Analysis

The schematic diagram of the 1/4 vehicle pneumatic suspension model is presented in Figure 4. In this system, a 2-DOF suspension model is established. It consists of a sprung mass, referring to the frame of the vehicle that is supported by the pneumatic suspension. The pneumatic suspension and the wheel assembly are connected to the axle. A simple representation of the wheel is used that includes the tire stiffness and damping. Pavement vibration acts on the wheel directly. The dynamic model of the system can be established as:
{ m s x ¨ + c ( x ˙ x ˙ b ) + k ( x x b ) = 0 m a x ¨ b + c w ( x ˙ b x ˙ a ) + k w ( x b x a ) + c ( x ˙ b x ˙ ) + k ( x b x ) = 0
where ms is the mass of the 1/4 frame of the vehicle; ma is the mass of the axle; xb denotes the displacement from the axle; xa is the displacement of the pavement; kw and cw are the stiffness and the damping of the wheel assembly, respectively; and C is the damping of the pneumatic spring. In the pneumatic system, an air inlet is the key component of air spring damping. According to hydrodynamics and the flow characteristics of the air inlet, the damping of the pneumatic spring can be expressed as:
c = m ˙ g = s v 2 g ρ ( p ˙ q p ˙ g )
where s is the area of the air inlet, v is the air velocity through the air inlet, g is the gravitational acceleration, ρ is the air density, and pq is the air pressure out of the air inlet. Based on Equation (12), c is a variable changed by the parameters v, pq, and pg. In the passive spring, the air velocity through the air inlet is zero, so the damping of the spring will be ignored.

3.2. Natural Frequency Analysis

Equation (11) can be translated in the matrix form as:
[ m s 0 0 0 m a 0 0 0 0 ] [ x ¨ x ¨ b x ¨ a ] + [ C C 0 C C + C w C w 0 0 0 ] [ x ˙ x ˙ b x ˙ a ] + [ k k 0 k k + k w k w 0 0 0 ] [ x x b x a ] = 0
Additionally, it can also be simplified as:
[ M ] X ¨ + [ C ] X ˙ + [ K ] X   = 0
Damping of the system can be ignored because it has minimal impact on the natural frequency of the damping. The free vibration can be decomposed into the superposition of a series of simple harmonic vibrations, and the solution of the above equation can be expressed as:
X = [ φ ] e j ω t
where ω is the circular frequency of the system and φ denotes the amplitude vector. The dynamic function can be changed to:
( [ K ] ω 2 [ M ] ) [ φ ]   = 0
The circular frequency can be solved as the square root of the eigenvalues of the matrix [M]−1*[K]. The ith natural frequency will be obtained as: ωi/(2π).

3.3. Vibration Isolation Efficiency Analysis

The vibration isolation effect of a nonlinear vibration isolation system is evaluated using its transmission rate, which is defined as the ratio of corresponding vibration energy before and after the vibration isolation system [31]. The expression can be presented as:
T d = E [ x ˙ 2 ] / E [ x ˙ b 2 ]
where E [ x ˙ 2 ] and E [ x ˙ b 2 ] denote the mean square of the frame and pavement velocity. The vibration isolation efficiency can be expressed as:
T = ( 1 T d ) × 100 0 0

4. Simulation of the Pneumatic Spring Working Process

4.1. Establishment of the Simulation

In order to study the influence of different parameters of the pneumatic spring on vibration isolation performance, a test model for the pneumatic vibration isolation system is established. In the test system shown in Figure 5, the wheel assembly system is neglected. The vibration signal from the vibration exciter simulates the vibration from the axle. The pneumatic spring is connected to a vibration exciter, an air compressor, and a payload. The air compressor controls the absolute pressure of the pneumatic spring. The effect is reflected in the performance of the payload vibration.
During the real work state, the pneumatic spring equals a passive suspension. The damping of the system is ignored. The analysis model of the pneumatic spring working process is set up in a MATLAB/Simulink environment. According to Equations (10), (11), (16) and (17), four integrated computing modules are established, which are dynamic analysis, natural frequency analysis, transmission rate analysis, and rubber stiffness analysis. In this simulation, five parameters, including L1, D1, D2, mg (directly influence the pressure pg), and ms, are set as input variables. The evaluating values such as velocity, displacement, natural frequency, and transmission rate are the outputs of the system.

4.2. Pressure and Signal Frequency Analysis in Simulation

Based on the designed parameters of the pneumatic spring and the estimated vehicle weight, the initial state of the simulation is presented in Table 2.
Based on the road roughness levels defined in GB7031-1986, levels A, B, C, and D, with random road excitation at speeds of 120, 70, and 30 km/h, are in the mid-frequency range, and the normal frequency is under 100 Hz [32]. In the first simulation, the frequency of the signal is set as 50 Hz, and the amplitude is 5 mm. To analyze the pressure influence, the absolute pressure of the pneumatic spring is set at 5, 6, 7, and 8 bar, respectively. The simulation time is 1 s with 50 cycles, and the simulation results are shown in Figure 6.
As can be seen in the displacement comparison in Figure 6, the curve of 7 bar shows the smoothest performance. The curves of 5 and 6 bar touch below rubber deformation, and the curve of 8 bar touches above rubber deformation. The natural frequency of the system change is not obvious with different pressures. The natural frequency is around 2 Hz.
The maximum velocity fluctuations of 5, 6, 7, and 8 bar are 0.450, 0.248, 0.033, and 0.282 (m/s), respectively, which are much lower than that of the signal vibration at 3.127. Moreover, in the diagram of transmission rates, a pressure of 7 bar reaches 0.97%, which is much lower than the rates of 13.4%, 8.18%, and 8.85% reached by 5, 6, and 8 bar, respectively.
The results show that the pneumatic spring has a great effect on isolation under 50 Hz with 5 mm amplitude vibration on a 300 kg payload; therefore, 7 bar is a suitable pressure in this situation. However, the natural frequency changed little with the pressure.
In order to analyze the effect of different vibration frequencies, the frequency of the signal is changed to 10 Hz. As can be seen in Figure 7, compared with results from 50 Hz, the displacement and the natural frequency show little difference. The maximum velocity fluctuations of the signal drops to 0.629 (m/s), and that of the 5, 6, 7, and 8 bar pressures are 0.484, 0.212, 0.062, and 0.287 (m/s), respectively. The final transmission rates are raised to 65.65%, 28.62%, 7.34%, and 41.55%, respectively. The simulation results show that for the two important criteria—isolation velocity and transmission rate—the performance under 10 Hz vibration is worse than under 50 Hz vibration.
When the frequency of the signal is lowered to 2 Hz, which is around the natural frequency of the system, and the simulation time is lengthened to 5 s (Figure 8), the displacement of the payload changes little when compared with the above results. The maximum velocity fluctuation of the signal drops to 0.127 (m/s), and that of the 5, 6, 7, and 8 bar pressures are 0.487, 0.408, 0.336, and 0.521 (m/s), respectively. All the final transmission rates increase beyond 100%. In this environment, the pneumatic spring no longer has any effect on vibration isolation.
Raising the frequency of the signal to 100 Hz, as can be seen in Figure 9, and compared with the results above, the displacement and the natural frequency show little difference. The maximum velocity fluctuation of the signal is 6.28 (m/s), and that of the 5, 6, 7, and 8 bar pressures are 0.452, 0.227, 0.03, and 0.286 (m/s), respectively. All the final transmission rates drop below 8%. The pneumatic spring performs better than before on isolation velocity and transmission rate.
To analyze the transmission rates under different frequency vibrations, unequal piecewise frequency vibrations of 2, 3, 5, 20, 40, 60, and 80 Hz are introduced to the simulation. As can be seen in Figure 10, with a 300 kg payload, the simulation results prove that the pneumatic spring performs better as the vibration frequency increases and loses efficacy (transmission beyond 100%) as the vibration frequency drops to 3 Hz. A bar of 7 is a suitable pressure for this situation.

4.3. Payload Mass Effect Analysis in Simulation

The mass of the payload is a constant of 300 kg in the former simulation. In the dynamic analysis, the payload mass (ms) is a key parameter and will affect the performance of the spring. In the mass effect simulation, the frame mass is changed from 1 kg to 300 kg, and the step size is 1 kg. The absolute pressure is set as 1.5, 2, 3, 4, 5, 6, 7, and 8 bar, separately. As can be seen in Figure 11, the frequency of the signal vibration is 50 Hz, and the maximum velocity fluctuation and the transmission rate are the two criteria used to evaluate performance. From the results of the simulation, the two criteria present consistently, and the pressure selected table with different masses is obtained, as shown in Table 3.
In order to analyze the frequency effect, the frequency of the signal vibration is raised to 100 Hz. As can be seen in Figure 12, the two criteria perform better, and the pressure selected table presents consistency when compared with results from 50 Hz vibration.
Based on the values from the simulation, a fitting function between payload mass and absolute pressure is achieved to obtain a smaller transmission rate. The applicable pressure value with the payload mass is expressed as:
p g = 50.93 + m g 51

5. Validation of the Pneumatic Spring Experiment

To validate the simulation results, a test prototype of the vibration isolation system is designed and developed. As can be seen in Figure 13a, the prototype system consists of an air compressor to control the pressure of the pneumatic spring, a vibration exciter to produce the vibration wave, a pneumatic spring designed as the novel structure, a vibration platform, an isolation platform, and two accelerators to measure the vibration of the two platforms.
As can be seen in Figure 13b, besides the vibration exciter and the pneumatic spring, the vibration isolation platform consists of flexible ground supports, fixed support, protective springs, and linear bearings. To reduce the vibration transmitted to the ground, four flexible ground supports with rubber pads support the vibration exciter. A fixed frame is assembled from an aluminum profile, and four protective springs support the vibration platform on the fixed frame. This structure shares the load from the vibration platform and protects the vibration exciter. Two linear bearings ensure the transitive vibration direction is vertical.
The mass of the isolation platform is 5 kg. To ensure the effectiveness of the vibration isolator, the transmission rate should be less than 100%. Based on our previous simulation, the pressures of the experiment are set at 1.5, 2, 3, and 4 bar. The vibration frequency is set at 50 and 100 Hz, respectively.
As can be seen in Figure 14, the final transmission rates under 100 Hz vibration are 41.65%, 47.17%, 48.36%, and 54.49% with 1.5, 2, 3, and 4 bar absolute pressure, respectively. Compared with the under 100 Hz vibrations, the transmission rates are 46.81%, 52.06%, 61.49%, and 65.75% under the 50 Hz vibrations.
In the experiment, when the vibration frequency is under 10 Hz, the isolation platform performs large amplitude vibrations. This proves the passive spring cannot isolate low-frequency vibrations. The results of the experiment prove that:
(1)
The pneumatic spring is effective for vibration isolation under 50 Hz and, separately, under 100 Hz, both with a 5 kg payload.
(2)
The pneumatic spring performs better with vibration frequencies under 100 Hz than with those under 50 Hz.
(3)
With a 5 kg payload and the same frequency vibrations, the absolute pressures of the spring from superior to inferior are 1.5, 2, 3, and 4 bar, successively.
(4)
For low-frequency vibrations, the passive pneumatic spring is less effective.
The experiment validates the simulation and dynamic models.

6. Conclusions

(1) A novel structure of a pneumatic spring is presented. The nonlinear stiffness of the pneumatic spring is analyzed based on the ideal gas model and material mechanics. Natural frequency analysis and the transmission rate of the pneumatic suspension are obtained as two effect criteria using the dynamic model.
(2) The vibration isolation system platform is established using a MATLAB/Simulink environment. With the results from the simulation, the rules of the pneumatic suspension are analyzed. The pressure selected table with different masses is obtained, and the optimal function between the payload mass and the absolute pressure required is achieved.
(3) A prototype of the vibration isolation system is designed and developed. Both the simulation and the experiment prove that our pneumatic spring design is effective at high-frequency vibration isolation—the higher-frequency vibration produced, the better performance the spring shows. For low-frequency vibration, the passive pneumatic spring loses effectiveness. The relationship between payload mass and absolute pressure is validated.
According to the analyzed characteristics, this pneumatic spring can be used for other vehicles or equipment, such as motorcycles or machine tool processing, to reduce high-frequency vibrations. The applicable pressure of the pneumatic spring with different payloads can be determined for better vibration isolation performance based on the relationship equation.
Compared with RLAS, this structure limits the nonlinearity of the rubber. Because it controls the air flow through the air inlet, this structure can be converted into an active suspension for a vehicle. With active suspension, the vehicle comfort should be improved in a low vibration frequency environment. If so, this would become an important basis for future research into improving vehicle suspension and a fundamental theory for the precise control of pneumatic springs in active suspensions.

Author Contributions

Data curation, N.W.; Formal analysis, Z.S.; Project administration, Y.S.; Software, J.Z.; Supervision, Y.S.; Validation, Y.W.; Writing—original draft, Z.S.; Writing—review & editing, Z.S., Y.W. and S.X. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Conflicts of Interest

The authors declare that there is no conflict of interest regarding the publication of this article.

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Figure 1. The novel pneumatic spring. (a) Sketch of the pneumatic spring; (b) 3D model of the pneumatic spring.
Figure 1. The novel pneumatic spring. (a) Sketch of the pneumatic spring; (b) 3D model of the pneumatic spring.
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Figure 2. Parameters of the pneumatic spring.
Figure 2. Parameters of the pneumatic spring.
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Figure 3. Parameters of the rubber connector.
Figure 3. Parameters of the rubber connector.
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Figure 4. The schematic diagram of the 1/4 vehicle pneumatic suspension.
Figure 4. The schematic diagram of the 1/4 vehicle pneumatic suspension.
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Figure 5. The test model of the pneumatic vibration isolation.
Figure 5. The test model of the pneumatic vibration isolation.
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Figure 6. Simulation results under 50 Hz, with 5 mm amplitude vibration.
Figure 6. Simulation results under 50 Hz, with 5 mm amplitude vibration.
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Figure 7. Simulation results under 10 Hz, with 5 mm amplitude vibration.
Figure 7. Simulation results under 10 Hz, with 5 mm amplitude vibration.
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Figure 8. Simulation results under 2 Hz, with 5 mm amplitude vibration.
Figure 8. Simulation results under 2 Hz, with 5 mm amplitude vibration.
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Figure 9. Simulation results under 100 Hz, 5 mm amplitude vibration.
Figure 9. Simulation results under 100 Hz, 5 mm amplitude vibration.
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Figure 10. Simulation results under different frequency vibrations.
Figure 10. Simulation results under different frequency vibrations.
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Figure 11. Mass effect simulation under 50 Hz vibration.
Figure 11. Mass effect simulation under 50 Hz vibration.
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Figure 12. Mass effect simulation under 100 Hz vibration.
Figure 12. Mass effect simulation under 100 Hz vibration.
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Figure 13. The test prototype of the vibration isolation system. (a) The vibration isolation system; (b) The vibration isolation platform.
Figure 13. The test prototype of the vibration isolation system. (a) The vibration isolation system; (b) The vibration isolation platform.
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Figure 14. The experiment results from the vibration isolation system.
Figure 14. The experiment results from the vibration isolation system.
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Table 1. Nomenclature table for the main parameters of the pneumatic spring.
Table 1. Nomenclature table for the main parameters of the pneumatic spring.
SymbolExplanationSymbolExplanation
pgThe absolute pressure of pneumatic springkpThe stiffness of the air
VThe gas volume in cavitykxThe stiffness of rubber
mgThe gas masskThe stiffness of the spring
AefThe effective areaxDisplacement of the floating platform
msMass of the payload(kg)xbDisplacement of the vibration
cThe damping of the springTdTransmission rate
Table 2. Initial state of the simulation.
Table 2. Initial state of the simulation.
ParametersDescription (Unit)Values
L1length of the air spring cavity (mm)46
D1diameter of the floating platform (mm)44
D2diameter of the fixed platform (mm)80
MsMass of the payload (kg)300
Table 3. Optimal results between the payload mass and the absolute pressure.
Table 3. Optimal results between the payload mass and the absolute pressure.
Payload Mass (kg)1~3738~7778~126127~180181~231232~280281~330331~
Optimal Pressure (bar)1.52345678
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Sun, Z.; Shi, Y.; Wang, N.; Zhang, J.; Wang, Y.; Xu, S. Mechanism and Optimization of a Novel Automobile Pneumatic Suspension Based on Dynamic Analysis. Electronics 2021, 10, 2232. https://doi.org/10.3390/electronics10182232

AMA Style

Sun Z, Shi Y, Wang N, Zhang J, Wang Y, Xu S. Mechanism and Optimization of a Novel Automobile Pneumatic Suspension Based on Dynamic Analysis. Electronics. 2021; 10(18):2232. https://doi.org/10.3390/electronics10182232

Chicago/Turabian Style

Sun, Zhibo, Yan Shi, Na Wang, Jian Zhang, Yixuan Wang, and Shaofeng Xu. 2021. "Mechanism and Optimization of a Novel Automobile Pneumatic Suspension Based on Dynamic Analysis" Electronics 10, no. 18: 2232. https://doi.org/10.3390/electronics10182232

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