Abstract
The paper presents the impact tensile behaviors of two common building membranes (Ferrari 1002T2 membrane and XYD 300N membrane) in PVDF-coated-fabric membrane structures. The tests are conducted using the split Hopkinson bar test device. Typical forms of stress and strain are applied for comparing the stress-strain relationship between quasi-static and high strain rates. Besides, the failure mechanism and energy absorption at high strain rates are discussed. The results show that with the increase of strain rates, the growth rate of the stress of PVDF membrane decreases gradually, which is different from the stress-strain relationship in low strain rates. At high strain rates, the ultimate tensile strength increases linearly with the increase of strain rates. In addition, the energy absorption capacity of the material increases with the increase of strain rates. The results can provide an important basis for the design and analysis of membrane structures under the impact loads.
1. Introduction
As a new form of large-span spatial structures, membrane structures are often used in the construction of large public buildings such as stadiums and exhibition centers. The membrane structure is pretensioned to maintain the shape and bear the load [1]. However, under the wind-induced disaster, the membrane structure is often impacted by the fragments rolled up by the strong wind, including glass, stone, and metal [2]. These wind-induced fragments impact the membrane surface at a higher rate, resulting in a gap in the membrane surface [3]. Then, under the wind load, the tearing failure occurs easily, and the crack propagates fast, resulting in the overall damage of the structure (Figure 1).

At present, considerable progress has been made in the research of structural theory, including form-finding analysis, cutting analysis, and load state analysis, as well as the development of calculation and software analysis [4]. Accordingly, as another important factor to study the performance of membrane structures and ensure the safety of membrane structures, research on the properties of membrane materials is still lacking behind [5].
At present, the research on membrane materials is mainly focused on the quasi-static tests. The main mechanical properties of membrane materials have been studied systematically, such as the uniaxial tensile test, the biaxial tensile test, the tear test, and the creep test [6]. Some researchers have done a lot of research on the failure mechanism and constitutive relationship of building membrane materials [7–9]. Some researchers have done a lot of research on the micro performance of PVDF membrane materials [10–14]. Dinh et al. [15] analyzed the tension fabric membrane structure used in foldable architectural applications using nonlinear finite elements, which was validated with the experimental data obtained from digital image correlation (DIC) technique. Ambroziak and Klosowski performed uniaxial and biaxial tests based on the least squares technique and proposed a method of laboratory tests necessary for the identification of mechanical properties of the coated fabric [16].
In the study of dynamic response of membrane structures, Wang et al. [17] studied the mechanical behavior of plain woven fabrics under high-strain-rate lateral impact using the finite element method. Besides, the impact test of single-layer plates is carried out under the same fabric structure and loading conditions, which showed good agreement with the FE results. Some researchers have studied the dynamic response of membrane structures under impact load and analyzed the parameters of boundary conditions, membrane prestress, and alluvial velocity [3, 18–20]. Some researchers have studied the dynamic response of circular thin membranes under low velocity impact loading and discussed the dynamic response law of forced vibration of thin membranes under different initial conditions and material parameters [21, 22]. Ma et al. [23] analyzed mechanical properties of CWKF composites at different strain rates from the point of view of frequency domain. Jain [24] studied the impact of wind-induced fragments on high-rise glass and considered the effect of impact velocity. Ross et al. [25] studied the failure mode of metal roof under the impact of wind-induced fragments and explained the failure mechanism. Zhao et al. [26] and Zhang et al. [27] studied the dynamic mechanical properties of PVC membranes from the perspective of failure mode and frequency domain.
When textile structural composites are subjected to quasi-static loads, the force has sufficient time to transfer in the fiber and matrix until the final state. Nevertheless, when the material is subjected to high-strain-rate stress, the situation will change significantly. Because the load propagates rapidly in the material, there is less time for stress wave to be completely transferred in the material. Because of the distribution of fiber and matrix in the material, the effect of stress wave on each part of the material is also completely different and unclear.
Referring to the current research results, it can be found that the research on membrane structures mainly focuses on the mechanical properties and response analysis of materials and structures under quasi-static and the impact loads. However, there are few studies on the mechanical properties of building membrane materials under high strain rates. In the current design of membrane structures, the mechanical properties of the material under quasi-static are taken as design basis. For example, according to the relevant design specifications, the common rate of the tensile test is 100 mm/min when the tensile strength value needs to be determined. However, as coated fabric composites, the mechanical properties of membrane materials under high strain rates are not clear, which is important for the response of membrane structures under impact. In order to deeply study the accurate response of membrane structures under wind-induced disasters, it is necessary to further study the mechanical properties of membrane materials under high strain rates and the impact resistance of membrane structures.
In this paper, two common building membrane materials, Ferrari 1002T2 membrane and XYD 3000N membrane, are chosen as the research object. The stress-strain relationship between high strain rates and quasi-static is discussed, and the failure mechanism and energy absorption are studied. The variations of mechanical property parameters under different strain rates are analyzed, including ultimate strength, Young’s modulus, energy absorption, and so on. The results can provide an important basis for the design and analysis of membrane structures under the impact loads.
2. Experimental Procedure
2.1. Materials
Two kinds of coated fabrics were selected for mechanical analysis. One is XYD 3000N, a typical PVC-coated fabrics with the thickness of 0.65 mm and the density of 850 kg/m3. The other one is Ferrari 1002T2 (PVDF), with the thickness of 0.78 mm and the density of 1050 kg/m3. Figure 2 shows the dimensions and microscopic structure of PVC/PVDF-coated fabrics studied in this paper. Due to the different weaving process, under normal circumstances, the warp and weft direction of the membrane material show the difference in tensile strength.

2.2. Tensile Tests under Various Strain Rates
In this part, test schemes of quasi-static tests and high-strain-rate tests are introduced, and the measuring principle and equipment of high-strain-rate tests are explained in detail.
2.2.1. Quasi-Static Tests
The rates of tensile tests under quasi-static are 1, 10, and 100 mm/min. The tensile tests of warp and weft specimens were carried out respectively. Considering the size of the specimen, the strain rate under quasi-static can be calculated according to the following formula:where is the approximate strain rate, is the tensile rate, and is the length of the specimen.
2.2.2. High-Tensile-Velocity Tests
The wind-induced fragment velocity is in the range from 30 m/s to 50 m/s, and the strain values of 350, 500, 750, 900, and 950 s−1 are taken as the five loading conditions. In this paper, the impact tensile test device is used to study the impact tensile mechanical properties of PVC/PVDF membrane specimens using the split Hopkinson tension bar device, and it is shown in Figure 3. The test device is mainly composed of a launch system, bar system, and data processing system. In order to complete the test as accurately as possible, the adhesive mode between the specimen and the bar is adopted. The advantage of this method over the wedge extrusion system is that there is no stress concentration at the edge of the clamp. The adhesive is made of DP810 two-component epoxy adhesive from 3M Company.

According to the one-dimensional elastic stress wave theory, the stress of the specimen can be calculated:where is the elastic modulus of the transmission bar; is the strain of the transmission bar; is the cross-sectional area of the elastic bar; and is the cross-sectional area of the specimen core.
3. Results and Discussion
3.1. Failure Modes
The typical failure modes under different strain rates are shown in Figure 4. There are three main failure modes. For the first mode (damage mode), the specimen do not break completely. According to the statistical data, it can be found that the failure mode corresponds to the rate range from 350 s−1 to 500 s−1. For the second mode (single fracture mode), the failure form of the specimen approximately shows a flat port, which corresponds to the test of strain rates in the range from 500 s−1 to 750 s−1. In addition to the complete port, there are many cracks in the specimen of the third kind of failure mode (multiple fracture mode), which corresponds to the strain rate within the strain-rate range from 750 s−1 to 950 s−1. The main reason why the material does not break obviously at strain rates of 350/s and 500/s is that the material does not reach the ultimate tensile strength corresponding to this strain rate. However, at a strain rate of 750/s, the material reaches the ultimate failure strength, and at this strain rate, there is a synergistic time of stress transfer between coating and fiber, and the stress concentration region is mainly located in the middle of the specimen. Finally, after reaching the ultimate tensile strength, the material has a flat fracture. At strain rates of 900/s and 950/s, while some specimens have tensile failure at the end, there will be more cracks along with it. This is mainly because that the impact tensile time at a high strain rate is very short, about 100. There is not enough time for the yarns and coatings to achieve the energy minimum state and uniform stress distribution, so that the coating does not deform well with the yarns. It results in the stress concentration in multiple areas and finally develops to multiple cracks.

From the point of view of failure mode, it can be found that different strain rates correspond to different failure modes, and PVC/PVDF membrane materials are sensitive to strain rates. It indicates that there will be many types of failure modes of the membrane structure, when subjected to the impact of wind-induced fragments at different rates. In ① failure mode, there is no fracture on the surface of the specimens, only a few internal fibers are broken, and there is no obvious cracking in the coating. ① failure mode mostly occurs at the strain rate of 350/s and 500/s. In the ② failure mode, the complete flush port appears on the surface of the specimens, and there are no other cracking positions. ② failure mode mostly occurs at the strain rates of 500/s and 750/s. In the ③ failure mode, in addition to the same complete flat fracture as the B failure mode, there will be more than one incomplete fracture. ③ failure mode mostly appears in the strain rate of 900/s and 950/s. The specific damage form is shown in Figure 4.
3.2. Stress-Strain Relations
3.2.1. Typical Stress-Strain Relation of PVDF-Coated Fabrics under Quasi-Static Tensile Loads
The stress-strain relationship curve of PVDF membrane material under quasi-static mainly consists of two stages, as shown in Figure 5. In the first stage (I), the fiber in the membrane and the coating on the surface are in the elastic stage at the same time, which is shown on the stress-strain curve and approximately shows a linear relationship. After reaching the elastic strain limit, the material enters the stage of plastic stress strengthening (II). In this stage, due to the leading role of fiber stress strengthening, the slope of the stress-strain curve is larger than that of the elastic section, and the stress increases rapidly with the increase of strain. Until the ultimate strain is reached, the specimen is broken.

3.2.2. Typical Form under High Strain Rates
The impact tensile tests were carried out along the warp and weft directions at five strain rates, respectively. According to the one-dimensional stress wave propagation theory [28], the stress-strain curve at high strain rates can be calculated by signals.
A typical stress-strain curve obtained from the impact tensile tests is shown in Figure 5. When it comes to the high-strain-rate state, the stress-strain curves along both the warp direction and the weft direction increase linearly at first. After reaching the yield point, the increase of the stress-strain curves becomes obviously slower. Then, the stress-strain curves decrease rapidly after exceeding the maximum stress. It can be found that the stress-strain curves are highly sensitive to the strain rate. The impact mechanical properties of PVDF-coated woven fabrics are determined by the mechanical properties of the polyester thread net and the PVDF coating on the surfaces of the woven structure. Since the polyester fiber and the coating material all have high sensitivity to the strain rate, the stress-strain curves of PVC-coated woven fabrics under the impact tension are sensitive to the strain rate.
The stress-strain curve can be divided into three stages: “Stage I”: as shown in Figure 5, point A is the coordinate origin and the starting point. The AB segment is approximately a straight line, which is the “stage I” and becomes a linear stage, in which the stress increases linearly and forms a straight line. The corresponding point B is called the linear limit point, the abscissa of the point B is the linear limit strain, and the longitudinal coordinate is the linear limit stress. “Stage II”: point C is the maximum stress point, so the longitudinal coordinate of point C is the tensile strength value of the material, and its abscissa is the strain under the tensile strength. The BC segment is “stage II,” and the stress value continues to rise after the AB segment, which is called the ascending stage. “Stage III”: point D is the last point of the stress-strain curve, which is called the breaking point, and the strain is the largest. The abscissa of point D is the maximum strain, which is called breaking elongation. The CD segment is “stage III,” and the stress begins to decrease from point C to point D, which is called the descending section. Then, the curve enters the highest point, which is the impact tensile strength of the material, and then the curve decreases in a straight line, indicating that the material is broken and the material is damaged.
3.2.3. Stress-Strain Relationship under Different Strain Rates
The mechanical properties of materials under dynamic loads are very different from those under quasi-static loads. In the range of high strain rate, there is little difference in yield stress under different strain rates, which is mainly manifested by the difference of ultimate strength. The ultimate strength increases with the increase of strain rates. Quasi-static loading and Hopkinson bar loading are used as the criterion for distinguishing low and high strain rates. In this paper, the low strain rates are 0.0001/s–0.01/s and the high strain rates are 350/s–950/s.
As shown in Figure 6, in the range of low strain rates, the stress-strain curve of the material is approximately coincident in the elastic stage. Within the range of stress strengthening, the ultimate tensile strength of the material increases with the increase of strain rates. In addition, the ultimate strength varies greatly under different strain rates. At the same time, the ultimate strain increases with the increase of strain rates. By comparing Figures 6(a) and 6(b), it can be found that under the same quasi-static strain rate, the ultimate tensile strength along the warp direction is larger, and the tensile strength varies greatly with the strain rate. Compared with the warp direction, the ultimate tensile strength of the weft direction does not change obviously under different strain rates. The mainly reason is the fact that the membrane material is an anisotropic material, and the mechanical properties of warp fiber and weft fiber are quite different. The same conclusion can be obtained by comparing Figure 6(c) with Figure 6(d).

(a)

(b)

(c)

(d)
As shown in Figure 6, in the range of high strain rate, the stress-strain curves of the materials in the elastic stage are approximately the same, and the elastic ultimate tensile strength of the materials is consistent. In the yield stage, the stress increases with strain at different strain rates, which is reflected in the slope of the stress-strain relationship curve. However, it is noteworthy that the ultimate tensile strength of materials is different at different strain rates, and the ultimate tensile strength increases with the increase of strain rates. In addition, the ultimate strain increases and changes greatly with the increase of strain rates. By comparing Figures 6(a) and 6(b), it can be found that under the same strain rate, the ultimate tensile strength along the warp direction is larger, and the tensile strength varies greatly with the strain rate. Compared with the warp direction, the ultimate tensile strength of the weft direction does not change obviously under different strain rates.
In the range of quasi-static and high strain rates, stress and strain have a strong strain rate effect with the increase of strain rates. For example, in Figure 6(a), the warp direction of XYD material is in the range of high strain rate, the ultimate strain is 6.5% at the strain rate of 350 s−1, and the ultimate tensile strength is 57 MPa. At the strain rate of 950 s−1, the ultimate strain reaches 23% and the ultimate tensile strength reaches 88 MPa. In the range of strain rate from 350 s−1 to 950 s−1, the tensile strength of the material increased by 31 MPa and the ultimate strain increased by 16.5%. In this process, the ultimate strain and ultimate tensile strength of the materials increase linearly.
3.3. Mechanical Properties
The ultimate tensile strength corresponding to different strain rates is drawn in Figure 7. The ultimate tensile strength of each material increases linearly with the increase of strain rates in the longitude and latitude.

It is noteworthy that there are great differences between the longitude and latitude of XYD materials. When the strain rate increases to the same extent, the ultimate tensile strength of the warp specimen increases more, indicating that the warp fiber has stronger strain rate sensitivity. The anisotropy of ultimate tensile strength of XYD materials is obvious in the range of high strain rate. In the impact resistance design of membrane structures, the influence of anisotropy should be considered. It is suggested that the lower ultimate tensile strength in two directions should be taken as the design value to ensure the overall safety of the structure.
Under different strain rates, the ultimate tensile strength of Ferrari 1002T2 material is similar in longitude and latitude. And with the increase of the same strain rate, the ultimate stress strength increases approximately. It shows that the anisotropy of ultimate tensile strength of Ferrari 1002T2 material is not obvious in the range of high strain rate. In the anti-impact design of membrane structures, the materials with similar ultimate tensile strength in two ways under high strain rates are selected as far as possible, so that the material can be fully used to resist the impact of wind-induced fragments.
3.3.1. Energy Absorption
Two parameters are used to describe the energy absorbing properties of the two kinds of PVC/PVDF-coated woven fabric. The first one shows the absorbed energy before failure. It can be calculated by integrating the stress-strain curve up to the peak point, as shown in Figure 8. It demonstrates the energy absorbed by the composite before reaching its tensile strength. The other is the absorbed energy, which is the total energy absorbed during the whole tensile process. As shown in Figure 8, the parameter can be calculated by integrating the whole stress-strain curve [22].

Toughness refers to the ability of a material to absorb energy during plastic deformation and fracture process. The higher the toughness, the less the possibility of brittle fracture. The total energy absorbed by the material before it reaches the tensile strength represents the fracture strain energy of the material under the impact tensile load. In this paper, the region surrounded by the coordinate axis and the AC segment in Figure 5 is called the fracture energy density of the material, which reflects the toughness of the material.
According to Figure 9, the fracture energy density of the material increases linearly with the increase of strain rates before the strain rate of 900 s−1, and the trend of PVC/PVDF membrane material is basically the same, indicating that the fracture energy of the material has strong strain rate sensitivity. It shows that the material has better energy absorption capacity and better toughness at high strain rates. It is of great significance for the research of membrane materials as protective materials. At the strain rate of 900 s−1, the warp and weft fracture energy density of Ferrari membrane material change, and the warp direction increases and the weft direction decreases, which is due to the anisotropy of the membrane material.

(a)

(b)

(c)

(d)
According to Figure 9, the two parameters of XYD fabric and Ferrari 1002T2 fabric along the two directions increase with the rising strain rate. Significant strain rate sensitivity can be observed. All the phenomenon mentioned above shows that PVC/PVDF-coated woven fabrics have great ability to consume energy in the high-strain-rate state. The absorbed energy before failure along the weft direction of both the two kinds of PVC/PVDF-coated woven fabrics is higher than that along the warp direction, while the difference between the two directions of Ferrari 1002T2 fabric is smaller than that of XYD fabric.
4. Conclusion
This paper presents the impact tensile behaviors of PVC/PVDF building coated fabrics under low and high strain rate. The failure modes of materials under different strain rates are statistically analyzed and the typical stress-strain relationships under quasi-static and high strain rates are proposed respectively. Finally, the stress-strain relationship, ultimate tensile strength, and energy absorption of materials under different strain rates are studied. The following conclusions are obtained:(1)The failure modes of two kinds coated fabrics are sensitive to strain rates. In the range of high strain rates, there is no obvious fracture in the strain-rate range from 350 s−1 to 500 s−1. The failure mode in the strain-rate range from 500 s−1 to 750 s−1 shows single fracture. The failure mode in the range of strain rate from 750 s−1 to 950 s−1 is accompanied by multiple cracks in addition to the multiple fracture.(2)In the range of low strain rate, the material stress-strain relationship consists of two stages. The first stage is the elastic stage, and the stress increases linearly with the increase of strain. The second stage is the stress strengthening stage in which the slope of the stress-strain curve increases and the tensile modulus is higher than that of the first stage. In the impact simulation of membrane structures, the constitutive model at the high strain rate is used to describe the mechanical properties of membrane materials, and there is higher displacement in the same strain state, which has the reference value for accurately describing the deformation and damage under the impact loads.(3)In the range of high strain rate, the ultimate tensile strength increases linearly with the increase of strain rates, and the ultimate strain increases linearly with the increase of strain rates. In the strain rate range from 350 s−1 to 900 s−1, the energy absorption capacity of the material increases linearly, and the energy absorption increases greatly at the strain rate of 900 s−1. This shows that the energy dissipation capacity of membrane materials under high strain is strong, which provides the energy dissipation contribution of materials to the impact resistance of structures, and the ultimate tensile strength of materials under high strain rates is approximately linear growth.
Data Availability
The research data used to support the findings of this study are included within the article. Request for more details should be made to the corresponding author.
Conflicts of Interest
The authors declare that they have no conflicts of interest.