StudentShare
Contact Us
Sign In / Sign Up for FREE
Search
Go to advanced search...
Free

Design of a Car Suspension System - Report Example

Cite this document
Summary
In this report "Design of a Car Suspension System", a focus on the design of a simplified car suspension system was undertaken in which certain parameter questions were answered in a report structured format as follows…
Download full paper File format: .doc, available for editing
GRAB THE BEST PAPER93.7% of users find it useful

Extract of sample "Design of a Car Suspension System"

Design of a Car Suspension System Student University Design of a Car Suspension System Introduction Car suspension system is a combination of springs, tires and its air, linkages and shock absorbers. The shock absorbers connect the wheels to the vehicles in order to allow relative motion to take place between them. This suspension system serves the roles of road holding and braking and that of creating a comfort atmosphere to the passengers through isolation of roads noise and vibration (Haykin, 2002). All these to be achieved, right trade-offs are required in the suspension system in order to serve the purpose. In this report, a focus on the design of a simplified car suspension system was undertaken in which certain parameter questions were answered in a report structured format as follows; Since the car suspension system helps the car to mitigate the force at which the boarders experience variations in frequency of the moving car, then, the car suspension system is perceived to like a filter that filters high frequency variations beyond which the comfort of boarders is affected. Therefore, car suspension system is used to act like a low pass filter in order to filter out unwanted frequencies beyond certain level. In this case, the car suspension system to be designed in the first case is that of undammed spring mass system. Because of this, the free body diagram of the system is as shown in figure 1. In this figure the forces acting on the mass, chassis, is also shown where represents the force due to the spring while represent the force due gravitational pull. In addition to that, the coordinates of the wheel and the masses have been shown as h(t) and y(t) respectively Figure 1: A free Body Diagram of the Chassis Showing the Co-ordinates and the Direction of Forces acting on it From this system, differential equation representing the behavior of the chassis can be generated by use of Newton is Second Law of motion as shown in equation (1) (1) Where; And are as However, at equilibrium, acceleration is equal to zero. Because of that, . Therefore, By considering the change in the position of the mass with respect to y direction, the force experienced by the spring is given by; Therefore, At this point , the mass experiences an acceleration (Haykin, 2002). This acceleration of the mass can be derived from Newton’s second law of motion as; By rearing this equation, Where, Based on the above differential equation, the frequency response of this linear transfer invariant system is obtained by letting the particular solution of the equation to be; Therefore, the complementary function is obtained to be; At t=0, Also, at t=0 Therefore, Therefore On the other hand, the particular function is solved as follows Therefore, Also; Therefore, For the frequency response, By differentiation the above equation twice and substituting into the net force experienced by the chassis, then; Also; Therefore, Therefore, Based on the result of the frequency response of the system, it is observed that the system amplitude of the response depends on the frequency due to the bump spacing. In this case, when the frequency response of the system will be at its minimum level of change from the neutral point. This implies that the value of the spring constant is not enough to sustain the system at its minimum point of variation from the neutral point. With respect to that, the frequency of the system depends on the mass of the chassis and the spring constant as shown below By changing the parameters of the system, parameters k and M, the system will not help because changing these parameters only changes the natural frequencies of the system which does not have any much effect on the frequency response of the chassis. Adding of a shock absorber reduces the impact of the variation of the amplitudes experienced by the passengers. This absorber acts in a directly proportional to the velocity of the chassis and as a result, it mitigates the impact of the change in amplitude with respect to the frequency of the moving car. Therefore, an introduction of the shock absorber into the car suspension system will change the LCCDE equation to like the one shown below; Considering the system at time zero, the change in the direction of the height of the wheels is equal to zero. Therefore, writing the above equation, it becomes; Based on the above differential equation, the frequency response of this linear transfer invariant system is obtained by; Therefore; Hence, differentiating the above and substituting it into the mass spring damper equation, By substituting the above into the equation, By assuming the The following Matlab command was used in plotting the frequency response of the system % Frequency response of the mass-damper spring system M=2000; %Mass of the Chassis in kg w=2; %Natural Frequency of the system eps=0.1 % The value of Zeta a=[0 0 w.^2]; b=[1 (2*eps*w) w.^2]; fre=[0:0.1:2*pi]; figure; freqs(a,b,fre); Grid on As a result of this code, the following was the plot output. Figure 2: The Frequency Response Plot using the Freqs command For the case when the natural frequency is 3, below is the code used and figure 3 shows its output. % Frequency response of the mass-damper spring system M=2000; %Mass of the Chassis in kg w=3; %Natural Frequency of the system eps=0.1 % The value of Zeta a=[0 0 w.^2]; b=[1 (2*eps*w) w.^2]; fre=[0:0.1:2*pi]; figure; freqs(a,b,fre); Grid on Figure 3: frequency Response when natural frequency is 3 and damping ratio=0.1 When natural frequency is 10 and damping ratio=0.1 % Frequency response of the mass-damper spring system M=2000; %Mass of the Chassis in kg w=10; %Natural Frequency of the system eps=0.1 % The value of Zeta a=[0 0 w.^2]; b=[1 (2*eps*w) w.^2]; fre=[0:0.1:2*pi]; figure; freqs(a,b,fre); Grid on On the other hand, the frequency response was plotted with constant natural frequency while varying the damping ratio as shown in the figures below. % Frequency response of the mass-damper spring system M=2000; %Mass of the Chassis in kg w=3; %Natural Frequency of the system eps=0.5 % The value of Zeta a=[0 0 w.^2]; b=[1 (2*eps*w) w.^2]; fre=[0:0.1:2*pi]; figure; freqs(a,b,fre); Grid on When When In addition to this, the step response of the system was solved by rewriting the second order differential equation to first order differential equation and then converted to state space for purpose of analysis. In this case, the equation was solved as follows; by rewriting the above into the form of two first order differ tai; equations as shown below, Let Then it implies that; Also; Rewriting equation 2 and 3 into matrix form In addition that, the response of the system with respect to the output only can be represented as follows; Defining these matrices into and putting them into the Matlab, the step repose can be obtained. But, And By using the following code, the following was the plot of the graph. %Solution of the sytem using Step response figure; for eps=0.2:0.4:1; for w=2:4:10; s=-(w)^2 d=(2*eps*w) A=[0 1; s d]; B=[0; -s]; C=[0 1]; D=[0]; sys=ss(A, B, C,D); if eps Read More

With respect to that, the frequency of the system depends on the mass of the chassis and the spring constant as shown below By changing the parameters of the system, parameters k and M, the system will not help because changing these parameters only changes the natural frequencies of the system which does not have any much effect on the frequency response of the chassis. Adding of a shock absorber reduces the impact of the variation of the amplitudes experienced by the passengers. This absorber acts in a directly proportional to the velocity of the chassis and as a result, it mitigates the impact of the change in amplitude with respect to the frequency of the moving car.

Therefore, an introduction of the shock absorber into the car suspension system will change the LCCDE equation to like the one shown below; Considering the system at time zero, the change in the direction of the height of the wheels is equal to zero. Therefore, writing the above equation, it becomes; Based on the above differential equation, the frequency response of this linear transfer invariant system is obtained by; Therefore; Hence, differentiating the above and substituting it into the mass spring damper equation, By substituting the above into the equation, By assuming the The following Matlab command was used in plotting the frequency response of the system % Frequency response of the mass-damper spring system M=2000; %Mass of the Chassis in kg w=2; %Natural Frequency of the system eps=0.

1 % The value of Zeta a=[0 0 w.^2]; b=[1 (2*eps*w) w.^2]; fre=[0:0.1:2*pi]; figure; freqs(a,b,fre); Grid on As a result of this code, the following was the plot output. Figure 2: The Frequency Response Plot using the Freqs command For the case when the natural frequency is 3, below is the code used and figure 3 shows its output. % Frequency response of the mass-damper spring system M=2000; %Mass of the Chassis in kg w=3; %Natural Frequency of the system eps=0.1 % The value of Zeta a=[0 0 w.^2]; b=[1 (2*eps*w) w.

^2]; fre=[0:0.1:2*pi]; figure; freqs(a,b,fre); Grid on Figure 3: frequency Response when natural frequency is 3 and damping ratio=0.1 When natural frequency is 10 and damping ratio=0.1 % Frequency response of the mass-damper spring system M=2000; %Mass of the Chassis in kg w=10; %Natural Frequency of the system eps=0.1 % The value of Zeta a=[0 0 w.^2]; b=[1 (2*eps*w) w.^2]; fre=[0:0.1:2*pi]; figure; freqs(a,b,fre); Grid on On the other hand, the frequency response was plotted with constant natural frequency while varying the damping ratio as shown in the figures below.

% Frequency response of the mass-damper spring system M=2000; %Mass of the Chassis in kg w=3; %Natural Frequency of the system eps=0.5 % The value of Zeta a=[0 0 w.^2]; b=[1 (2*eps*w) w.^2]; fre=[0:0.1:2*pi]; figure; freqs(a,b,fre); Grid on When When In addition to this, the step response of the system was solved by rewriting the second order differential equation to first order differential equation and then converted to state space for purpose of analysis. In this case, the equation was solved as follows; by rewriting the above into the form of two first order differ tai; equations as shown below, Let Then it implies that; Also; Rewriting equation 2 and 3 into matrix form In addition that, the response of the system with respect to the output only can be represented as follows; Defining these matrices into and putting them into the Matlab, the step repose can be obtained.

But, And By using the following code, the following was the plot of the graph. %Solution of the sytem using Step response figure; for eps=0.2:0.4:1; for w=2:4:10; s=-(w)^2 d=(2*eps*w) A=[0 1; s d]; B=[0; -s]; C=[0 1]; D=[0]; sys=ss(A, B, C,D); if eps

Read More
Cite this document
  • APA
  • MLA
  • CHICAGO
(Design of a Car Suspension System Report Example | Topics and Well Written Essays - 1500 words, n.d.)
Design of a Car Suspension System Report Example | Topics and Well Written Essays - 1500 words. https://studentshare.org/engineering-and-construction/2054046-signals-systems
(Design of a Car Suspension System Report Example | Topics and Well Written Essays - 1500 Words)
Design of a Car Suspension System Report Example | Topics and Well Written Essays - 1500 Words. https://studentshare.org/engineering-and-construction/2054046-signals-systems.
“Design of a Car Suspension System Report Example | Topics and Well Written Essays - 1500 Words”. https://studentshare.org/engineering-and-construction/2054046-signals-systems.
  • Cited: 0 times

CHECK THESE SAMPLES OF Design of a Car Suspension System

Recumbent Tricycle for Disabled User

It will specifically endeavor to examine the design and manufacture of the suspension system of the recumbent tricycle especially designed to be driven single-handed.... hellip; Full suspension is integrated into the proposed recumbent tricycle for single–handed users; this means that it has a front and rear suspension system.... The front suspension will simply make use of the front fork suspension common in other bicycles and tricycles....
19 Pages (4750 words) Research Paper

Car Spring Suspension System

The report "Car Spring suspension system" focuses on the analysis of a new technological solution, the positive linked suspension system (PLSS), the product of several years of hard work, and several false starts for engineering companies.... hellip; If someone has surveyed the current crop of auto designers, they would probably find a general consensus that the suspension of choice for today's car and trucks is the fully independent suspension system (Valkenburgh, 208)....
6 Pages (1500 words) Essay

Design and Analysis of a Motorcycle Rear Suspension

In the design of the system, the dimensions of the Motorcycle Rear Suspension are significant.... The paper titled the "Design and Analysis of a Motorcycle Rear suspension" is using Adam's software to simulate the operations of a Motorcycle Rear suspension by looking at modeling with the aim of having a model that can be relied upon for motorcycle riders.... nbsp;… In the production, design, modeling, and simulation of a Motorcycle Rear suspension various procedures and testing are done to ensure that the Motorcycle Rear suspension produced is going to function at the minimum without any effect....
7 Pages (1750 words) Coursework

Design of a Car Suspension System

"Design of a Car Suspension System - Mathematical Modelling, the Cut-Off Frequency Related to the Natural Frequency" paper argues that the design aimed to make a simplified car suspension system that can work and make the customers comfortable.... nbsp; The paper “Design of a Car Suspension System - Mathematical Modelling, the Cut-Off Frequency Related to the Natural Frequency”  is an engrossing variant of a math problem on mathematics.... When designing a car suspension system, one considers a simple shock absorber which is an important device in a car....
8 Pages (2000 words) Math Problem

Design and Analyze the Car Suspension System

This paper "Design and Analyze the car suspension system" discusses that the car suspension system is an important part.... Since the car suspension system acts as a low pass filter to attenuate high amplitudes, changing parameters relating to the suspense's amplitude will help.... hellip; I have learned how to design the suspension system because the damping ratio was important in changing the frequency amplitude of road roughness....
14 Pages (3500 words) Term Paper

Suspension Spring for an Offroad Vehicle

With a lifted suspension system the drive shaft must be lengthened.... This type of suspension is known as a dependent system because the wheels are literally connected so as they move together as a unit.... The paper "suspension Spring for an Offroad Vehicle" discusses that the suspension of UTVs and ATVs are typically dependent systems.... These kits retrofit an existing suspension of parallel four-link design....
8 Pages (2000 words) Report

Simplified Suspension System

One characteristic of the car suspension system is its mode of operation which tends to follow more harmonic patterns.... The relationship is premised on the fact that the car suspension system produces parameters such as specified torque, vibration, speeds, and both necessary and unnecessary noise.... The paper "Simplified suspension system" exclusively determined the aspect of the suspension system and the exploration of various parameters that define the engineering and the physics behind the system....
13 Pages (3250 words) Research Paper

Car Suspension System

The paper "car suspension system" underlines that the application of the model to the key equation accentuates clear remarks on the frictional forces on the kinetic velocity subjected to the constant in determining the draft and size of the shock absorber.... The suspension system is pragmatically positioned to support the cars driving pressure and compromising the instability that is prompted by the road vibrations.... The suspension system enhances diverse vehicles' movement as well as the positioning in the road surfaces....
7 Pages (1750 words) Case Study
sponsored ads
We use cookies to create the best experience for you. Keep on browsing if you are OK with that, or find out how to manage cookies.
Contact Us