Relationship between the Dynamic Parameters of a Structure’s Vibration Process and the Loading Model Moving on a Bridge

A sufficiently strict conduction of supervision during bridge operation is a crucial matter for many countries, including the underdeveloped country of Viet Nam. In recent times, the budgets in developed countries used for funding the implementation of quality-assessment procedures are quite high compared to the lower budgets in underdeveloped countries. e plan proposed in this work addresses the current lack of information available in the process of structure-quality evaluation. e vibration signals will be acquired from the random circulation status to determine the structure’s behavior so as to utilize the signal information during the bridge span’s operation. e study’s main goal is to find various parameters that can be used to evaluate the actual bridge performance. ese parameters must meet certain criteria, such as high sensitivity, lowmeasurement cost, and efficiency in the measurement process, but must not affect the itinerary of vehicles moving on the bridge. e actual structural vibration signals used in this work currently serve as a best trend model for evaluating the operation of the bridge span structure. is study will focus on determining the relationship among deflection, acceleration, and vehicle load so as to evaluate the structure’s working process. is study has also fabricated an experimental model to evaluate and test the sensitivity of the parameters utilized in this study in order to verify the results obtained. e results obtained in this research will be applied for the quality-control process in several bridge models with span structures built with the composite steel concrete cross section of the beam. Many developing countries, including Viet Nam, will receive benefit in the future from the useful advantages presented in this study.


Introduction
Viet Nam is similar to other Southeast Asian countries [1,2] located in the region, in that it has an interlace system of rivers and canals. Most major cities in Viet Nam are located in areas near rivers or river junctions. After conducting extensive surveys in the Ho Chi Minh City area [3,4], it was determined that there are more than 1000 bridges [5,6] and safe operations of these bridges are especially considered as a key focus because of their important role in so many socioeconomic activities. e normal measures of assessing the quality conditions of the bridge structure will be undertaken through an assessment of the bridge structure's concrete beams and the composite steel concrete cross section of the beam [7,8]. At present, the inspection, monitoring, and verification of bridge quality are commonly implemented through three main measures as follows: (i) e first measure is a system of human monitoring, giving information that is often more qualitative than quantitative, and that can be somewhat subjective. e techniques of this measure include inspection and monitoring by manual methods, visual inspection, and use of specialized equipment [9][10][11]. is measure has significant advantages and is simple and easy to implement, and the inspection cost for initial investment is low, but it has disadvantages as well: the damages in the details of the bridge structure cannot be detected in a timely fashion, and the bridge material mechanical changes cannot be evaluated. Most of the information obtained from a structure with these methods is of a qualitative nature, acquired through the subjective evaluation of human observations.
(ii) e second measure consists of methods for collecting quantitative data for bridge vibrations generated by an applied periodic force. e bridge quality inspection [12][13][14] includes the following activities: the quality is either merely checked or thoroughly determined, the project quality is formally assessed, and the quality is compared to the design's original requirements. e aim of this measure is to assess the bridge's actual working ability under the actual load effect. Some parameters are used for a quantitative evaluation process during implementation [15], including deformation, deflection, vibration amplitude, and specific frequency. e advantage of this measure is that it can give us a clear understanding of the different quantitative values and the load's impact options.
ese methods can shed light on the factors responsible for putting the structure in some of the most dangerous situations during its operation. is measure's disadvantage is that the measurement data are obtained in a static state, except for few of the following dynamic parameters: specific frequency, damping coefficient, and vibration amplitude, which are determined by generating the vibration pattern with a periodic force. e amount of information received from this method is too low; therefore, it cannot fully reflect the operation status of the structure, nor fully explain the structure's behavior.
(iii) e third measure surveys the structure's behavior during the actual operation through vibration measurement [16][17][18][19]. is measure has been widely applied to bridge abutments in recent times.
is measure allows the acquisition of much data regarding bridge behavior under diverse actual loads.
is measure allows the advantages of characterizing the actual situation of the load, detecting changes in mechanical parameters, locating weakened portions of the structure, and determining the weakening rate over time. ese advantages can help in making reasonable decisions and plans when evaluating a project's quality. However, for the cases of difficult economic situations in underdeveloped countries, these testing systems are not economically feasible and so cannot be widely applied.
Assessing the advantages and disadvantages of all three methods above, this study proposes several methods for building relationships between important parameters in the bridge structure's vibration process so as to collect data for the vibrations and deformation of the structure under the effects of random loads during operation and utilization. e data obtained in this study will supplement the bridge's existing database system and, at the same time, will add new parameters having a higher sensitivity than traditional parameters. is can serve in making the most suitable plan for quality assessment, inspection, and regular maintenance for a project. is study has practical significance in monitoring and evaluating a project's working status over time.
is study also helps management agencies form a basis for making important decisions about the structure's operation. Furthermore, the results in this study, which have been implemented in practice, will establish a database source facilitating the application of these advanced methods in quality assessment and project management. is is the basis for expanding these research methods and conducting future bridge evaluations.

Theoretical Basis
Many studies have already carried out the modeling of bridge structures, which are categorized by type according to the structure's bearing status. Many models have simulated the structure of a bridge span in the form of force-bearing beams, models which are presently popular [20][21][22]. For a load applied under static conditions, the span structure model is generally depicted as shown in Figure 1.
For the case of the span model shown in Figure 1, if P is the static load, the beam's deflection y is given by the following formulas as in which l is the length of the beam and a and b are the positions to determine the set point of the load P. EJ is the flexural stiffness; E is the elastic modulus; P is the load on the beam; and J is the area inertia moment to the principal axis of inertia, which is coincident with the x-axis direction. If the load p moves with speed v along the beam length with Q � Q 0 cos(Ωt), as shown in Figure 2, the beam's forced vibration is demonstrated through the deflection equation, shown as follows: where g is the gravity acceleration, ρ is the specific weight per structure's unit volume, A is the cross-sectional area, d � ����� � EJ/Aρ, and t is the time. e forces actually acting on the structure are, however, often in the form of a harmonic force.
For the case shown in Figure 3, in which Q is the variable force given by the expression Q � Q 0 cos Ωt and moving with speed v, the beam's forced vibration [23,24] is presented as follows: 2 Advances in Civil Engineering in which α � vl/πa; β � τ/τ 2 ; τ � 2l 2 /πa; τ 1 � l/v; and τ 2 � 2π/Ω. e nondamped free vibration of a single support beam has the following form: where C i and D i are constants and p i is the i th -specific frequency in the following equation: is study introduces the concept of "dynamic coefficient" so as to determine the relationship between the structure's load impact and the specific vibration frequency, in order to evaluate the changes in bridge span structure during the vibration process. e dynamic coefficient model has demonstrated that this coefficient is used for evaluating the bridge's load capacity through the deflection and the vibration frequency, as shown in equations (2) and (3), and the abridged model of the dynamic coefficient, as shown in the following equation: in which δ is the dynamic coefficient, ω is the excitation frequency of vehicle load, Ω is the excitation frequency of the load under the action of velocity v, ω (1) is the first excitation frequency of vehicle load, and ω b is the bending frequency.

Building the Experimental Models.
Considering the methods implemented by us, this study examines the actual model of the ang Long Bridge, as shown in Figure 4, which has the following specifications: the bridge is 60 m long; it includes 5 spans, each span being 12 m long; it has a simple steel concrete; the span cross-section includes 5 steel I-beams with dimensions 550 × 250 × 9 × 22 mm; the abutments and pillars are made of reinforced concrete; the bridge deck for vehicles is made of reinforced concrete of thickness   Advances in Civil Engineering 3 18 cm; the bridge deck for pedestrians has a thickness of 20 cm; the current operating load is 13 tons; and the bridge was built before 1990. e modeling process used in this study for the ang Long Bridge, which is located on ang Long Street, District 9, Ho Chi Minh City, is shown in Figure 5. e bridge span is narrow; therefore, only one vehicle at a time can cross the bridge. e study models the ang Long Bridge's mechanical force-bearing system, as shown in Figure 5, with a load consisting of two contributing components: the concentrated load P and the moving load Q 0 sin Ωt, with forced frequency Ω, as originally analyzed.
In this research, the displacement signals are measured using a displacement sensor and the vibrations are measured with an accelerometer sensor. ese sensors are permanently mounted and in contact with the beams' underside surfaces. e signal acquisition model is demonstrated in Figure 6. In fact, the frequency of the constraining force Ω often depends on the mechanism and Q depends on the velocity v as in Table 1. is study assumes that Q � k * v 2 and Ω � v/R, where Q is the amplitude of the harmonic force, k is the experimental coefficient, Ω is the force's angular frequency, and R is the wheel radius, as shown in Table 2. is study will consider the change of load P in the range of load limit for each type of vehicle, as in Table 3, due to the harmonically constraining force influenced by the vehicle structure.
With the parameters of the load P, the velocity v, and the frequency Ω of the constraining force, this study has built a workable model through the actual measurement process so as to determine the maximum deflection at given locations on the bridge span. is study has calculated the maximum stress value during the beams' vibration for the locations at which the deflection value is measured. e graph of the relationship between deflection and stress is given in Figure 7.
We can see the linear relationship between deflection and stress with the results in Figures 7 and 8. e linear regression equation is y � 6 × 10 − 12 x-8 × 10 − 9 with a correlation coefficient of R 2 � 1. When the load, velocity, and frequency of the constraining force change, the slope coefficient in Figure 8 remains constant; the deflection linearly increases when the load increases, regardless of the change in velocity or the change in frequency of the constraining force. e relationship between displacement and stress is often expressed as the structure's stress-deformation relationship. e results shown in Figure 9 [25,26] were obtained from a study that used the linear material model to demonstrate the stress-deformation relationship of a concrete-reinforced beam structure with two required parameters: the elastic modulus of steel E s and the yield intensity of steel f y . is concrete structure's simple stress-strain relationship curve has a multilinear isotropic form, proposed by Kachlakev [27], with two required parameters: the concrete's elastic modulus E c and its compressive strength f c ′ . In this material model, the von Mises criterion was used for determining the stress threshold so as to convert the concrete's linear behavior into nonlinear behavior, as shown in Figure 10, in which ε 0 is the stress at the peak of the material structure and β is a material parameter depending on the shape of the stressdeformation diagram. e stress-deformation relationship is given by equation (7a). For the case of [25], the stress-deformation relationship is as shown in equation (7b).
With the models being studied in [25][26][27], we can see in the results that the relationship between stress and deformation is either always a linear function during a process [28,29] or it is only a linear function in each defined space [25,26]. An evaluation model that exhibits both the influence of the elastic modulus E, which is a structural characteristic, (  and the antiviscosity coefficient C, which is a characteristic property of the material, has not yet been constructed.

Relationship between Deflection and Vibration
Acceleration. For the change of each load P, this study gets the results of both maximum deflection and maximum acceleration. When the velocity v changes in the model, this study changes the velocity v from 6 m/s to 16 m/s in order to either simplify the simulation process or conform to the bridge inspection standards.
We can see from the graphs shown in Figures 11(a)-11(f) that the variable relationship between deflection and acceleration at different load levels is relatively similar in terms of shape. Generally, when the acceleration increases, the deflection also increases and the difference in loads may be due to the masses of the loads that have influenced the beam's vibration        Figure 9: Stress-deformation relationship between reinforcement and concrete beams' concrete [25] and [26].
frequencies according to equation (6). us, when the speed changes from 6 m/s to 16 m/s with the same P load value, the study gets both the maximum deflection in this speed range and the frequency of the corresponding coercive force. From this, the study gets a graph that demonstrates the relationship between the deflection and the coercive force frequency

Building the Relationship between the Dynamic Coefficient and the Excitation Conditions.
e curve has demonstrated the relationship between the dynamic coefficient δ and the velocity v, as represented in equation (6). When the force P is constant, this study shows a dynamic coefficient δ corresponding to each velocity v, with v varying from 6 m/s to 16 m/s. In the graph, the dynamic coefficient δ and the velocity v appear as two neighboring peaks, the distance between the two peaks being about 1 m/s, as shown in Figure 12. is can be explained because δ is affected by Ω in equation (6). eoretically, the larger the dynamic coefficient is, the closer the coercive force frequency will be to the system's specific frequency. When referring to the actual spectrum analysis graph for a bridge, the frequency graph of the free vibrations shows two frequency peaks, which is called the "beat" phenomenon.
is will be clearly analyzed in the following points: (1) e influence of P on the dynamic coefficient of fixed v. Because of the fixed speed and the increased load, the dynamic coefficient δ increases due to the force P affecting the beam's first natural frequency, according to equation (6). erefore, when P increases, the beam's specific frequency ω 1 decreases, with a value close to the coercive frequency generated by the vehicle, and the dynamic coefficient δ also increases. Because of the increased load P, the dynamic coefficient δ also increases in each specified load interval. In Figure 13, each new segment will linearly increase and then a sudden decrease is shown at the segment's end. At that moment, the dynamic coefficient δ linearly increases according to the original relationship; this process continues in many different force intervals, forming a graph that is not entirely linear, according to the theory originally given. is can be explained: When the force P increases, the dynamic coefficient δ linearly increases, but when Ω decreases, the dynamic coefficient δ also decreases because it corresponds to each frequency of the coercive force Ω. At certain locations, the δ value suddenly decreases because the coercive force frequency Ω abruptly changes under the original sine-cosine period, as shown in Figures 14(a)-14(f ). Table 4 shows that in the experimental model, the slope coefficient a, which is calculated as the ratio of the dynamic coefficient δ to the coercive force Ω, is nearly constant during the experiment process. is can be explained by the fact that the coefficient a does not depend on the angular frequency of the coercive force at constant velocity. In addition, when the coercive force frequency Ω increases, the coefficient of b decreases. Table 4 shows the result that the more the Ω decreases in value, the faster the coefficient of b increases. When the actual speed of the experimental model is v � 9 m/s, the relationship between the load P and the dynamic coefficient δ given by the equation δ � aP + b is δ � 0.000003 * P + 1.041517. In this experiment, the average deviation for coefficient a is 0, and for coefficient of b, it is 0.004117. With this deviation level, the obtained results have given a high convergence.
(2) e influence of P impacted on the dynamic coefficient in the case of changed velocity v.
With the increase in speed, the load value increases and the δ value also increases in each specified load interval. However, when all load ranges are considered in the same graph, the δ value tends to decrease, as shown in Figure 15. is study can see the conformity with equation (6) when the P load value is in inverse ratio to the δ coefficient. is is similar to the previous survey, which showed that when the speed increases, the dynamic coefficient in each P value segment increases and the δ value increases linearly, as shown in Figures 16(a)-16(e).  Deflection (mm) Figure 13: Graph showing relationship between P and δ corresponding to v � 9 m/s.

Advances in Civil Engineering
In Table 5, we can see that the equation showing the relationship between the dynamic coefficient δ and the load P, when the velocity v changes, gives δ � 0.000004 * P + 1.24804 with an average deviation of 0.0000016 for the coefficient of a and of 0.009768 for the coefficient b. us, the value of the dynamic coefficient δ depends on both the velocity v and the load P as well as the frequency of coercive force Ω. As v increases, the δ value changes according to the linear relationship, as shown in the diagrams for δ and v. Corresponding to each Ω value, P and δ increase linearly.

Conclusion
e experimental testing model has been applied in this study so as to find the relationships between the characteristic mechanical parameters during the measurement and testing process. From this manuscript, we can build an experimental model in the field that is most suitable for the actual moving load model, with some conclusions as follows: (1) From either theory or experiment, the deflection values obtained under the load influence moving on the beams are relatively similar in terms of shape. As the deflection increases along with the velocity increase of the accelerating load, it can be seen that the difference in results with the varying loads may be due to the loads' mass influence on the beam's vibration frequencies. With a constant P load value, but with speed increasing from 6 m/s to 16 m/s, the study finds that the maximum deflection of frequency of the corresponding coercive force either remains unchanged or shows an insignificant change. From this study, we get the relationship between the deflection and the frequency of the corresponding coercive force. And, the deflection reaches the maximum value when the vibration  Figure 16: e diagram of the maximum δ value, when the velocity v changes corresponding to P (a) from 4,500 N to 4,800 N, (b) from 4,900 N to 5,600 N, (c) from 7,200 N to 8,000 N, (d) from 8,100 N to 9,000 N, and (e) from 9,100 N to 10,000 N. frequency approaches closer to the beam's first specific frequency. (2) Vehicle velocity has almost no influence on deflection values in both theoretical and experimental cases. It can be shown that for varying velocities, the differences in the results obtained for deflection values are insignificant and a structure's quality verification process is based primarily on deflection values. (3) As P increases, the beam's specific frequency ω 1 decreases, so the dynamic coefficient δ increases accordingly. As the load P increases, however, the dynamic coefficient δ increases only for each specified load interval. e value of the dynamic coefficient δ appears as a relationship, showing a linear increase at each segment, with a sudden decrease between segments. is process continues for many different force intervals, resulting in an incompletely linear diagram, according to the originally given theory. It can be shown that at certain locations, the δ value suddenly decreases because the coercive force frequency Ω suddenly changes, according to the initially given period.

Data Availability
e data used to support the findings of this study are included within the article.

Conflicts of Interest
e author declares no conflicts of interest.