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1. Introduction
The excessive noise and vibration on the car seat affect the mental and physical health of driver and passengers. Moreover, they reduce their working performance and efficiency [1]. The vibration and sound absorption characteristics of automobile parts are very important because of passenger comfort and avoiding component failure. Vibrations in different structures occur at different types of frequencies. If a component vibrates at frequencies higher or nearer to the natural frequency of the body, the vibration might be significantly high. Usually car seat models for vibration analysis of the whole body vibration (WBV) have been considered, including vertical, lateral, and longitudinal vibration, as shown in Figure 1. Here we have considered only the revolving part of the rotating car seat, i.e., swivel plate. It is well known that the revolving swivel plate in car seat application is subjected to bending and vibration. Therefore the main objective of this research work is to conduct experimental test for bending, vibration, and sound absorption analysis of swivel plate. Moreover, in the bending, natural frequency and frequency under static loading conditions were obtained using experimental method. The flexural strength and sound absorption capacity of swivel plate were obtained using specimen by experimental method. This analysis considers not only passenger’s comfort, regarding the sound absorption and frequency range, but also the load carrying and damping capacity of the swivel plate.
[figure omitted; refer to PDF]With the development of modern industry and transportation, noise pollution has one of the dangerous environmental problems [2]. In recent days, automobile and aircraft industries are focused on the lightweight and environmental friendly materials with good mechanical properties. Saravanan and Suresh [3] had investigated material replacement for gear and concluded that bronze alloy material is suitable instead of steel, for better strength, load carrying capacity, high velocity, and low-intensity stress level. Prabhakaran et al. [4] had investigated sound and vibration properties of flax fiber-reinforced composites using Data Acquisition system with Lab View software and finally concluded that the sound absorption coefficient of flax fiber-reinforced composites was 21.42% higher than that of glass fiber-reinforced composites. Also the damping factor was determined by using free vibration method as per the ASTM standard E756. The same experimental setup was utilized in this current sound and vibrational analysis.
Magnesium alloy has drawn a good deal of attention from automotive and aerospace components, due to its low density, high specific strength, and good damping capacity [5]. Also, it has outstanding physical and mechanical properties such as high stiffness/weight ratios, good castability, excellent vibration and shock absorption, and high damping capacity [6]. In automobile industry, the widely used magnesium alloys are Mg-Al-Zn series alloys, which have excellent castability and are of low cost [7–9]. However, the use of Mg alloys has been limited to a narrow range because of its limited mechanical properties such as low hardness and low tensile strength. Recently, a large number of research studies have focused on improving the mechanical properties of magnesium alloys by alloying [10, 11]. Moreover the improvement of mechanical properties often results in a decline of damping capacity [12]. For further engineering applications of magnesium, balancing the damping behavior and the mechanical properties has been a critical challenge [13]. Recently, several investigators have reported that the addition of Ca, Sr, Bi, Sb, or rare earth (RE) elements was to effectively improve the mechanical properties for the Mg-Al-Zn series alloys [14, 15]. Wu et al. [16] studied the effect of combined addition of Ca and RE elements on the mechanical properties of AZ91D alloy. The result showed that with the combined addition of 1mass% of Ca and 1 mss% of RE elements to AZ91D alloy, the UTS increased by 15.9%. Chen et al. [17] had investigated the effect of mechanical vibration on microstructure and properties of cast AZ91D-Mg alloy, finally concluding that, with the increase of mechanical amplitude, it can refine the β-Mg17-Al12 phase in AZ91D. Moreover, with the increase of mechanical vibration frequency up to 100 Hz the tensile strength and yield strength of AZ91D alloy increase gradually, and the tensile strength and yield strength increased by 17.9% and 10.3%, respectively. The ultimate tensile strength (UTS), yield strength, and elongation of as-cast AZ91D increase with the addition of Y [18]. The results revealed that the mechanical and damping properties of AZ91D could be increased with alloying elements. The chemical composition of AZ91D-Mg alloy is given in Table 1.
Table 1
Chemical composition of AZ91D-magnesium Alloy.
S. no | (Mass %) | Composition (%) | |||||||
Al | Mn | Zn | Si | Cu | Ni | Fe | Other | ||
1 | AZ91D | 8.5 | 0.20 | 0.55 | 0.10 | 0.03 | 0.022 | 0.055 | 0.02 |
The goal of this study is to explore the load carrying capacity, sound absorbing, and damping properties of Mg alloy swivel plate compared with A3 steel swivel plate, which is used in the revolving car seat. The revolving seat, which is used in the car, is specially made for physically challenged/ill persons, so damping property plays major role in this type of applications. By utilizing Mg alloy materials in the fabrication of structures, significant reductions in weight and emissions could be achieved, along with the ability to have materials that are renewable, recyclable, and biodegradable. Moreover, those materials with improved acoustic performance and damping properties will be an environmental friendly solution to the structure-noise challenge, besides several numbers of bending and vibration analyses of Mg alloy (e.g., [19, 20]) but only a limited number of studies regarding the combination of bending, vibration, and sound absorption analysis of automobile component especially in car seat parts [21, 22]. To solely investigate the bending, damping and sound absorbing capacity of swivel plate are proposed in to this work. Normally swivel plate is made up of A3 steel plate which we replaced with magnesium (AZ91D) alloy for that application, because the AZ91D alloy has great potential for the applications in suppressing the mechanical vibration and attenuating wave propagation for the control of noise and stabilization of structure components because of their low density and damping capacity. Weijiu Huang et al. [23] investigated about the fretting wear behavior of AZ91D alloy with different numbers of cycle and loading condition compared with AM60B alloy, because they have excellent castability and good mechanical properties with low cost; moreover they have been mainly used to produce the engineering parts such as engine crank case, accelerator brake pedal bracket, instrument board of the cars, and steering wheels and seat [24]. The results showed that AZ91D alloy revealed a higher capability in crack nucleation and propagation and is also a less friction coefficient and is of lower wear quantity than that of AM60B alloy. As is known, the accessories in automobile especially car seat are always subjected to the vibration environment. The fretting damage of car seat parts is unavoidable. For a better life-time swivel plate, the AZ91D material was chosen. However, this paper focused on a methodology that may be used to model a swivel plate that is used for revolving car seat undergoing base vibration.
2. Materials and Methods
The material properties of A3 steel and magnesium alloy are tabulated in Table 2 for analyzing purpose.
(i)
A3 Tool Steel (UNS 30103)
(ii)
Magnesium alloy (AZ91D)
Table 2
Properties of A3 steel and magnesium alloy.
S. no | Properties | Unit | A3 tool steel | Magnesium alloy |
1 | Density | kg/m3 | 7860 | 1810 |
2 | Modulus of elasticity | GPa | 205 | 45 |
3 | Poisson’s ratio | — | 0.29 | 0.35 |
4 | Tensile yield strength | MPa | 350 | 160 |
5 | Tensile ultimate strength | MPa | 420 | 250 |
A3 steel swivel plate was purchased from Bherwa Metals Pvt. Ltd. Bangalore, India, which is suitable for revolving seat with standard dimension as given in Table 3. The AZ91D plate was purchased from NUFIT PIPING SOLUTIONS, Mumbai, India. The length and width of the Mg alloy plate are the same as in the A3 steel plate. The thickness of Mg alloy plate is increased when compared to A3 steel plate based on human body and car seat weight. The AZ91D plate is mechanically ground, polished by using surface polishing machine, and drilled with vertical drilling machine. In order to achieve revolving feature for Mg alloy plate, the steel ball bearings with riveted joint were used; finally AZ91D swivel plate was fabricated as shown in Figure 2.
Table 3
Dimensions and weight of Swivel plate.
S. no | Material | Thickness of single plat (mm) | Length (mm) | Width (mm) | Weight (grams) |
1 | A3 steel | 1.5 | 104 | 104 | 632 |
2 | Mg alloy | 5 | 104 | 104 | 464 |
[figures omitted; refer to PDF]
2.1. Design Specification
Figure 2(a) shows A3 steel swivel plate and Figure 2(b) shows Mg alloy swivel plate. The dimensions and weight of the swivel plate for both materials are given in Table 3.
3. Bending Analysis
In this research, bending analysis was carried out to evaluate the deformation behavior of AZ91D material. In order to find out the strength for load carrying capacity of the swivel plate, the bending analysis is a vital one. Moreover, two types of bending analysis were carried out.
(a)
Flexural strength measurement analysis
(b)
Stiffness measurement analysis
3.1. Flexural Strength Measurement Analysis
The flexural strength measurement was carried out as per the ASTM standard D 790 [25]. This analysis was used to determine the flexural strength and modulus of flexure of both the materials. The AZ91D and A3 steel specimen were tested in 3-point bending apparatus with a span to thickness ratio of 8. In order to achieve better results for both materials, the specimen was prepared with the same thickness as in the corresponding swivel plate for bending analysis. The dimensions of both materials are presented in Table 4. The specimens were tested using Zwick/Roell Z005 universal testing machine at a crosshead speed of 1.2 mm/min. The Zwick/Roell universal test machine has a maximum test load of 5 kN and maximum cross-head speed of 3000 mm/min.
Table 4
Dimensions and Weight of Specimen for flexural strength analysis.
S. no | Material | Thickness of single plate (mm) | Length (mm) | Width (mm) | Weight (grams) |
1. | A3 steel | 1.5 | 125 | 25 | 55 |
2. | Mg alloy | 5 | 125 | 25 | 41 |
3.2. Stiffness Measurement Analysis
The compression testing was chosen for stiffness measurement with a large range (up to 5 kN). The A3 steel and Mg alloy (AZ91D) material swivel plates were taken to carry out bending test of various compression loads. The compression test was performed by using a universal testing machine (UTM). Moreover, the compression test was performed by applying compression load on a swivel plate between two platforms of UTM. The load was applied on top surface of the swivel plate with a range from 1 kN to 5 kN. The deflection values were taken from dial gauge and load vs deflection values were plotted on the curve as shown in Figure 3.
[figure omitted; refer to PDF]Let us assume that the maximum load applied to the swivel plate is 300 kg. In order to find out the stiffness for both materials, the swivel plate and the following method were used, where load = 3
Stiffness for swivel plate (K) for Mg alloy
From this numerical analysis, it could be seen that the stiffness value of Mg alloy swivel plate is significantly higher than that of A3 steel plate. However, the Mg alloy plate carried significantly more load than the A3 steel plate in the same weight ratio.
4. Vibration Analysis of Swivel Plate
Noise, vibration and harshness (NVH) analysis helps improves the vibration attributes of car seat. To study the vibration behavior of the system or component a reliable experimental validation is required. Moreover, the experimental analysis is a very important one to investigate the frequency under no loading and loading conditions and also damping absorption capacity of the component. To analyze the swivel plate it is necessary to describe the dimension and geometrical shape. Table 2 shows the dimension and weight of the swivel plates for both materials; also Figure 1 shows the geometrical shape of the swivel plate for both materials. The chemical composition AZ91D material is given in Table 1 and the mechanical properties of both materials are given in Table 2; based on these values the experimental work has been conducted.
4.1. Experimental Analysis of Swivel Plate
The natural frequency and frequency under different loading conditions were obtained using the vibration test setup. The swivel plate is placed on the table and the base four corners touch the ground and the top of the plate is not touched by anyone. An accelerometer sensor supplied by Dytran whose sensitivity is 10.47 mV/g was placed at the top of the swivel plate at location points. The location points 1, 2, 3, and 4 are shown in Figure 2. The output signals are received by means of connecting the accelerometer sensor with a Data Acquisition (DAQ) card 9234, which is connected to the PC and interfaced with Laboratory Virtual Instrumentation Workshop (Lab VIEW) software supplied by the National Instruments.
Figures 4 and 5 show the time of response for free vibration of A3 steel and Mg alloy swivel plates were obtained from the LABVIEW software. In this experimental method time (sec) of response and frequency response for both materials for no loading and loading conditions were obtained. Time of response and frequency response curves were obtained from LABVIEW for investigating the damping capacity for both materials.
[figure omitted; refer to PDF][figure omitted; refer to PDF]In Figures 4 and 5, it could be seen that the time domain excitation response for Mg alloy was significantly higher when compared to A3 steel swivel plate under the same excitation force. Because of its less stiffness under no loading condition the Mg alloy swivel plate exhibits high time domain response amplitude. It is observed that under the no loading condition the time domain response result of the Mg alloy exhibits low stiffness and vibration absorbing capacity than that of A3 steel.
In Figures 6 and 7, it could be seen that the time domain attenuation response excitation for Mg alloy was very good when compared to steel swivel plate. Because of its high damping capacity under loading condition the Mg alloy swivel plate exhibits better vibration amplitude attention response excitation than that of A3 steel. It is observed that under the loading condition the time domain response results of the Mg alloy swivel plate exhibit better stiffness and vibration absorbing capacity than those of A3 steel swivel plate. Moreover, when there is increasing in load, the time domain excitation of response for Mg alloy gave better results than that of steel. This is due to its material property and composition of alloying elements.
[figure omitted; refer to PDF][figure omitted; refer to PDF]Figures 8 and 9 show the free frequency response of A3 steel and Mg alloy swivel plate obtained from the LABVIEW software. The values of the natural frequency of both materials of swivel plates are tabulated in Tables 5 and 6.
[figure omitted; refer to PDF][figure omitted; refer to PDF]Table 5
Natural frequency for A3 steel (with 4 location points).
S. no | Description | Natural frequency (ƒ) (Hz) |
1 | Location 1 | 375 |
2 | Location 2 | 380 |
3 | Location 3 | 390 |
4 | Location 4 | 390 |
5 | Minimum value (ƒ) | 375 |
Table 6
Natural frequency for Mg alloy (with 4 location points).
S. no | Description | Natural frequency (ƒ) (Hz) |
1 | Location 1 | 765 |
2 | Location 2 | 770 |
3 | Location 3 | 760 |
4 | Location 4 | 765 |
5 | Minimum value (ƒ) | 765 |
Figures 10 and 11 show the frequency response of A3 steel and Mg alloy swivel plate under loading condition (4 kg) obtained from the LABVIEW software. The values of frequency for both materials of swivel plates under different loading conditions with four location points were taken from the vibration setup and the values are tabulated in Tables 7 and 8.
[figure omitted; refer to PDF][figure omitted; refer to PDF]Table 7
Frequency under loading condition for A3 steel (with 4 location points).
S. no | Description | Frequency (Hz) | ||||||
2 kg | 4 kg | 6 kg | 8 kg | 10 kg | 20 kg | 30 kg | ||
1 | Location 1 | 325 | 300 | 280 | 245 | 210 | 180 | 145 |
2 | Location 2 | 325 | 310 | 285 | 250 | 215 | 185 | 140 |
3 | Location 3 | 335 | 300 | 285 | 250 | 210 | 185 | 140 |
4 | Location 4 | 335 | 290 | 285 | 250 | 215 | 185 | 145 |
Maximum value | 335 | 310 | 285 | 250 | 215 | 185 | 145 |
Table 8
Frequency under loading condition for Mg alloy (with 4 location points).
S. no | Description | Frequency (Hz) | ||||||
2 kg | 4 kg | 6 kg | 8 kg | 10 kg | 20 kg | 30 kg | ||
1 | Location 1 | 615 | 430 | 265 | 135 | 85 | 50 | 35 |
2 | Location 2 | 620 | 435 | 270 | 135 | 80 | 55 | 35 |
3 | Location 3 | 620 | 435 | 270 | 135 | 80 | 55 | 35 |
4 | Location 4 | 615 | 425 | 260 | 130 | 80 | 50 | 35 |
Maximum value | 620 | 435 | 270 | 135 | 85 | 55 | 35 |
The natural frequency values for both materials of swivel plates were taken in the four location points and are tabulated in Tables 5 and 6. From these numbers of location points readings were taken for obtaining the accurate value for natural frequency. Moreover, the four location points were the four corners of swivel plate. The four corners of swivel plate are shown in Figure 2.
The frequencies under different loading condition values for both materials of swivel plates were taken in the four location points and those are tabulated in Tables 7 and 8. These numbers of location points’ readings were taken for obtaining the accurate value for frequency under different loading conditions, because the four corners are used to connect the car seat parts. Moreover, that area of the plate is only carrying the load when the weight was applied on the seat.
5. Sound Absorption Measurement Analysis
The sound absorption analysis is a very important one because the material has the ability to absorb unwanted noise inside the car. Moreover, this analysis used to evaluate the noise effect for the magnesium alloys. The sound absorption coefficient was measured by using an impedance tube tester as per the ASTM E 1050. In order to find the sound absorption capacity of both materials, a circular disc specimen was prepared because the sound propagation cylinder is in cylindrical shape. The dimensions of the sound test specimen for both materials are presented in Table 9.
Table 9
Dimensions and Weight of Specimen for sound absorption analysis.
S. no | Material | Diameter of the plate (mm) | Thickness (mm) | Weight (grams) |
1 | A3 steel | 100 | 1.5 | 95 |
2 | Mg alloy | 100 | 5 | 71 |
5.1. Experimental Method
The impedance tube testing method was carried out by the generation of plane wave in a cylindrical tube by a sound source. The sound pressures are measured in a microphone position in close proximity of the test sample [26].
An impedance tube tester was utilized to find out sound absorption coefficient (α) for both materials. The impedance tube has sound source (loud speaker) at one side end and test sample was mounted on another end. The dimensions of the test sample for both materials are presented in Table 10. The loudspeaker produces broadband random sound waves and the sound waves are propagating as plane waves in the tube; those plane waves hit the sample, get partially absorbed, and subsequently reflected. The sound absorption properties of both materials sample were tested in the frequency range of 100–2000 Hz. This system tests a sound absorptive material, processes the results, and reports the results in a graph of the absorption coefficient in various frequencies. Thus, the sound absorption coefficient of each material sample was obtained.
Table 10
Natural frequency values of both materials.
S. no | Analysis (Hz) | Experimental (Hz) | |
Steel | Mg alloy | ||
1 | Natural frequency (ƒ) | 375 | 765 |
The ability of both materials to absorb unwanted noise is based on dissipation of the sound energy upon passing through the material and also on conversion of some of the energy into heat. The sound absorption coefficient (α) was calculated as the amount of original energy less than the remaining unabsorbed energy compared to the original energy leads to the measurement.
6. Results and Discussion
The behavior of AZ91D-Mg alloy and A3 steel swivel plate and specimen has been successfully studied and the following observations were made.
6.1. Flexural Strength Analysis
From the flexural test, the load vs. extension response of AZ91D and A3 steel specimen was studied. By using strength and modulus formulas, flexural strength and flexural modulus for both materials were calculated. The flexural load-extrusion response of A3 steel, load values increase linearly in the elastic region. Maximum stress occurs at the mid span in three-point bending configuration [27]. Above the maximum stress, the steel plate gets rapture and failure occurs. The average flexural strength and flexural modulus values of the A3 steel ware found to be 4.326 Mpa ± 0.085 MPa and 102.45 Mpa ± 15.05 Mpa, respectively. For the flexural load-extrusion response of AZ91D-Mg alloy, the average flexural strength and flexural modulus values were found to be 7.078 ± 0.145 MPa and 180.45 ± 7.05 Mpa, respectively. The values are plotted in the bar chart as shown in Figures 12 and 13.
[figure omitted; refer to PDF][figure omitted; refer to PDF]From Figure 12, it is observed that the flexural strength of AZ91D-Mg alloy exhibits better than that of A3 steel. It is also observed that the flexural modulus of Mg alloy is better than that of A3 steel from Figure 13. The bending test consists of tension, compression, and shear forces. Both materials were tested along the y-direction and they gradually experienced brittle failure in the tensile surface. Due to the bending moment, the middle section of the tensile surface of the rupture occurred. Until the specimen failure, large deflection was achieved. Moreover, during this analysis the Mg alloy exhibits better performance than that of A3 steel.
6.2. Stiffness Analysis
The load and deflection values were obtained from experiential method and plotted in curve as shown in Figure 3. Moreover, the stiffness values were obtained by using the experimental values. It is revealed that the specific stiffness value of AZ91D swivel plate is significantly higher when compared to that of A3 steel plate [28]. This is due to its mechanical property of Mg alloy; it exhibits better stiffness when compared to steel under loading condition. However, the load carrying capacity of AZ91D swivel plate was significantly higher when compared to A3 steel plate with the current dimension condition.
It could be seen from Figure 3 that the deflection value of AZ91D swivel plate is significantly lower than that of A3 steel plate. This is because the thickness of Mg alloy plate is high and the steel exhibits poor performance when compared to Mg alloy when it is subjected to bending [29].
The simple numerical analysis for finding out the mechanical advantage of the swivel plate was presented here. Let us consider the mechanical advantage (R) for both materials of swivel plate; also the upper plate of the swivel plate was chosen for this numerical analysis.
Now, let us assume that the applied loads are the same:
For a thicker, less density material can be determined by considering the ratio of the stress equation (3), also this method can be used to choose material with the best properties for particular mechanical component. From the mechanical advantage (R), it could be seen that Mg alloy exhibits better geometric advantage over the A3 steel for the current dimension condition. Even, the mg alloy swivel plate has less weight cross section when compared to A3 steel for current analysis; it performs better. If it has equal weight cross section of steel, the performance of the Mg alloy material will be superior to that of steel when it is subjected to bending. Even if the yield strength of the steel is higher than the Mg alloys, the Mg alloy carries high amounts of load when it is subjected to bending because of better geometric and strength advantage when compared to steel. From that experimental and numerical analysis, the results revealed that the AZ91D-Mg alloy swivel plate performed better than that of steel in terms of load carrying capacity and behavior in bending. Also, the flexural rigidity (EImg) of Mg alloy plate showed higher flexural rigidity (EIst) than that of steel plate.
6.3. Vibration Analysis
From the vibration analysis in experimental method the following observations were made. Table 10 shows the natural frequency of both materials in experimental methods and Tables 11 and 12 show the frequency under different loading conditions of both materials in the experimental method. For the natural frequency in the experimental method, minimum values were taken, whereas for loading condition, maximum frequency value was taken because in the natural frequency the componant tends to oscilate without any damping force so that we choose lowest value, whereas under loading condition always choose maximum value.
Table 11
Frequency under loading condition in experimental method for A3 steel.
S. no | Method | Frequency (Hz) | ||||||
A3 steel | ||||||||
2 kg | 4 kg | 6 kg | 8 kg | 10 kg | 20 kg | 30 kg | ||
1 | Experimental | 335 | 310 | 285 | 250 | 215 | 185 | 145 |
Table 12
Frequency under loading condition in experimental method for Mg alloy.
S. no | Method | Frequency (Hz) | ||||||
AZ91D-Mg alloy | ||||||||
2 kg | 4 kg | 6 kg | 8 kg | 10 kg | 20 kg | 30 kg | ||
1 | Experimental | 620 | 435 | 270 | 135 | 85 | 55 | 35 |
(i)
From Table 10, it can be seen that Mg alloy material exhibits higher than that of A3 steel under the same excitation pulse input, because the natural frequency of the structure is controlled by mass and stiffness. In this case, the mass of the AZ91D is lower than A3 steel (Table 3).
(ii)
From Tables 11 and 12, it can be seen that the vibration absorption capacity of Mg alloy swivel plate exhibits better than that of A3 steel under loading condition. It reflects that it has a high damping capacity than that of A3 steel material.
From Tables 11 and 12, the frequencies under different loading condition values for both materials were taken and plotted in a curve, given in Figure 14.
[figure omitted; refer to PDF](i)
From Figures 6 and 7, it is observed that under loading condition the Mg alloy exhibits better vibration amplitude attenuation response excitation than that of steel. So in order to increase the load for swivel plate the Mg alloy gave better time domain response when compared to A3 steel. It is revealed that Mg alloy material has better vibration absorbing capacity under loading condition when compared to A3 steel.
(ii)
Figure 14 shows the relation between load and frequency under different loading conditions of both materials. It could be seen that the initial frequency of Mg alloy plate was maximum when compared to A3 steel plate. After that, while increasing the load, it comes below that of the A3 steel plate; it is observed that while increasing the load the vibration observing capacity of Mg alloy plate is significantly increased. The result illustrates that it has high damping observing capacity when it is subjected to loading condition [30, 31].
(iii)
It is also observed that, at the intersect point “Q”, i.e., up to 5 kg, and the corresponding frequency value of 300 Hz, the Mg alloy swivel plate exhibits poor damping capacity and after that particular point “Q”, the Mg alloy exhibits superior damping capacity to that of A3 steel. Moreover, critical load and two stages were observed from Figure 14; at load of 10 kg (critical load) stage 1 changes over into stage 2. At stage1, the frequency rate suddenly decreased with respect to load and at stage 2 it gradually decreased. It is revealed that the Mg alloy swivel plate enters into steady state stage at the load of 10 kg (critical load).
(iv)
The result revealed that the weight of the car seat that is applied on the swivel plate should be more than 10 kg. The Mg alloy swivel plate only exhibits better damping capacity. Moreover, the seat occupied by humans will provide better comfort while the vehicle is under dynamic condition.
(v)
AZ91D-Mg alloy exhibits high damping capacity due to its material nature and alloying elements, given in Table 1. The addition of aluminum improves strength, hardness, and corrosion resistance. Addition of zinc is next to aluminum in effectiveness as an alloying ingredient to strengthen Magnesium. Also addition of small amount of Mn, Si, and Cu improves the strength and mechanical properties of AZ91D alloy.
(vi)
Chen et al. [17] had investigated the effect of mechanical vibration on microstructure and properties of AZ91D; they concluded that with the increase of mechanical amplitude the tensile and yield strength increased gradually. Because of that, AZ91D alloy showed better performance when subjected to vibration.
(vii)
For the swivel plate of the same structure of these two materials, the time domain response and exciting point are mainly controlled by the elastic modulus of the material. The AZ91D elastic modulus is significantly less and the stiffness is higher than that of A3 steel. Because of high stiffness, the AZ91D exhibits lower response amplitude for external excitation. Because of that, Mg alloy exhibits high damping capacity in structural application.
6.4. Sound Absorption Measurement Analysis
In this section, the sound insulation capacity of both materials was analyzed. According to the experimental results the sound absorption coefficient (α) was obtained in all frequency levels. The lower level frequency (100 Hz) and higher level frequency (2000 Hz) values are presented in Table 13.
Table 13
Sound absorption coefficient (α) for both materials.
S. no | Frequency | Steel | Mg alloy | Ratio |
1. | Low level (100 Hz) | 0.04 | 0.05 | 25% increased |
2 | High level (2000 Hz) | 0.17 | 0.19 | 11.76% increased |
To analyze the sound absorption capacity of Mg alloy and A3 steel with the same sound waves input, the comparison test of sound absorption coefficient (α) was performed using the specimens made of AZ91D and A3 steel. The relationship between sound absorption coefficients (α) and frequency (Hz) was plotted in the curve as shown in Figure 15.
[figure omitted; refer to PDF]From Figure 15, it is revealed that the AZ91D showed poor performance at middle and high frequency levels than A3 steel. According to acoustic theories, sound absorbing performance of the material at middle and high frequency levels depends on mass. In addition the damping capacity and stiffness of the material are important factors for controlling the structural NVH effect. The mass of Mg alloy specimen is significantly low when compared to A3 steel specimen (Table 9). Finally, with this result, we observed that the sound absorption capacity of AZ91D is lower than that of A3 steel. However, at low frequency level and at the end of high frequency level the AZ91D exhibits better sound absorption performance. The reason is that Mg alloy has high stiffness (Figure 3) and better damping capacity (Figure 14) than A3 steel. The AZ91D-Mg alloy swivel plate will have a better sound insulation performance and better restraint for the low frequency booming noise of the car [18]. Moreover, the overall sound absorption performance of AZ91D-Mg alloy swivel plate has also reached the requirement of automotive industry based on the sound insulation application. By analyzing the influence of sound on the AZ91D-Mg alloy swivel plate, it can be found that it is suitable for car seat application.
7. Conclusions
(i)
The AZ91D-Mg alloy swivel plate has a distinct mechanical advantage over A3 steel in terms of strength, stiffness, and load carrying capacity with greater flexural rigidity in current dimension conditions.
(ii)
The flexural strength measurement test for the specimen is made of the AZ91D-Mg alloy and A3 steel, and the results showed that AZ91D exhibits better specific flexural strength and specific flexural modulus.
(iii)
The AZ91D-Mg alloy swivel plate was performed very well in the time domain excitation response observation under different loading conditions; it is revealed that it exhibits better vibration observing capacity than A3 steel swivel plate while increasing load.
(iv)
From Figure 14, load 10 kg was observed as a critical load. In order to increase seating comfort, the load applied on the swivel plate should be more than 10 kg, because from the above observation the swivel plate exhibits good damping performance at higher values than the critical load value.
(v)
In order to compare the sound absorption capacity for AZ91D and A3 steel the specimens were prepared and experiment was conducted using impedance tube tester. The results showed that the sound absorption coefficient (α) of AZ91D-Mg alloy material is 11.76% higher than that of A3 steel at higher frequency level (2000 Hz) and 25% higher at lower frequency level (100 Hz).
(vi)
These results suggest that the AZ91D-Mg alloy material could be a viable candidate for better strength, sound, and vibration absorption application in automotive industry.
(vii)
The weight of the swivel plate can be decreased by 26.58% while AZ91D-Mg using alloy, when compared to A3 steel material (Table 14).
(viii)
It is concluded that when using AZ91D-Mg alloy to replace A3 steel swivel plate, it is expedient to increase the mechanical advantage of the swivel plate and also stiffness, flexural strength, damping capacity, good acoustic behavior, and weight reduction.
Table 14
Weight for both the materials.
S. no | Analysis (grams) | Steel | Mg alloy | % of reduced |
1 | Weight | 632 | 464 | 26.58 |
Acknowledgments
This work was carried out under the FIST Program 2015 Research Grant, No. SR/FST/College-279/2015, sponsored by the Department of Science and Technology (DST), Ministry of Science and Technology, India.
Appendix
A. Weight Ratio between Mg Alloy and A3 Steel
Figure 16 shows the weight difference between A3 steel and Mg alloy swivel plate.
[figures omitted; refer to PDF]
B. Numerical Analysis of Bending for A3 Steel and AZ91D-Mg Alloy Plate
For the numerical analysis the top part of the swivel plate was taken into consideration. Let us take those dimensions of the plates from Table 3.
Now consider the plate cross section dimension from Figure 17, where b is the breadth and d is the thickness of the plate. Moreover, “y” value is very minimum, so that it is taken the same as both materials.
Isteel = bd3/12 = 140∗1.53/12 = 29.25 mm4.
Also, IMg = bd3/12 = 140∗53/12 = 1083.3 mm4.
Mechanical Advantage R = 1083.3/29.25 = 37
Flexural rigidity of Mg plate EI = 45000
Flexural rigidity of steel plate EI = 205000
Ratio of EI between Mg alloy plate and steel plate = 45000
From that, it could be seen that Mg alloy swivel plate has nearly 37 times better mechanical advantage and 8 times better flexural rigidity when compared to A3 steel in the current dimension conditions.
C. Numerical Analysis of Vibration Absorption for A3 Steel and AZ91D-Mg Alloy Plate
The relationship of the specific strain energy for the material as
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Abstract
A comparison was made between Mg alloy and A3 steel on weight, bending, sound absorption, and vibration conditions. In this study, a swivel plate, which is used in rotating car seats, is to be taken into consideration for finding bending, natural frequency, and frequency under static loading conditions. The swivel plate is generally made up of A3 steel plate; instead, we have replaced that with Mg alloy (AZ91D) plate. Stiffness, flexural strength, natural frequency, frequency under different static loading conditions, and sound absorption capacity were obtained through experimental methods. Finally, it was concluded that the damping capacity of Mg alloy of swivel plate is higher, has better stiffness, and incurred weight reduction by 26.58% less than that of the A3 steel. Also, the Mg alloy material exhibits better specific flexural strength, and specific flexural modulus and sound absorption coefficient are 11.76% and 25% higher than those of A3 steel at higher frequency level (2000 Hz) and at lower frequency level (100 Hz).
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