1 Introduction

Noise reduction and energy saving issues are among the major challenges in the construction industry and machinery sector. Due to the viscoelastic properties of polymeric materials on the one hand and their thermal insulation quality on the other, polymers are the preferred materials in this regard (Corsaro and Sperling 1990; Defonseka 2013; Sonnenschein 2014). Nevertheless, for successful application of polymeric materials the overall loading situation in service such as the time- and temperature-dependent deformation behavior and possible media influence are of major importance. In the special case of polymeric foam materials the fundamental viscoelastic properties of the underlying polymer (Ferry 1980; Hellerich et al. 2010; Ehrenstein and Theriault 2001) and load-dependent deformation of the specific cell structure is decisive for the overall deformation behavior (Gibson and Ashby 1999; Ashby 2006; Eaves 2004; Szycher 2013; Mills 2007).

According to the respective field of applications, commercial polyurethane foam materials are available in various formulations of the polymer type, closed or open cell structured in adjustable grades of density. All these parameters determine the deformation behavior of the elastomeric foam, which in general can be categorized as elastic and reversible. In the case of low-density foam types with large pore spaces, typically three regions of different stress–strain behavior can be distinguished in uniaxial compression (Gibson and Ashby 1999; Briody et al. 2012). Initially, the bending and compression of cell walls and edges lead to approximately linear stress–strain correlation up to strains of about 5% (region I).

The following stress plateau (region II) with moderate and constant stress increase up to a compression strain level of about 60% is dominated by viscoelastic cell wall buckling and initial cell collapse. This region represents the area of the highest energy absorption without significant structural damage and is therefore the recommended area for damping applications. Finally, the stress–strain curve ends up in the densification regime of the foam (region III), with significant increase of compression stress due to intense cell wall contact, density increase, and thus structural damage.

Concerning the overall loading situation in common structural applications, especially static long-term loading is predominant for load carrying damping elements. Consequently, the resulting time-dependent deformation behavior determines the damping quality of the component for superimposed dynamic-mechanical loading.

Further on, surrounding environmental impact such as elevated temperatures and media contact strongly influences the mechanical behavior especially for foam materials with extensive media uptake. Liquid medium fills up the cellular volume to a certain extent, which influences the structural deformation behavior of the foam component (Biot 1962; Cheng 2016). Moreover, the media contents of the polymer itself may result in a softening effect along with a shift of glass transition toward lower temperature.

Considering the complex loading profile of mechanical short- and long-term loads in combination with environmental influencing factors, a corresponding loading scenario is also necessary for proper materials testing and the reliable estimation of service performance. In this regard, the prime goal of the present study was the establishment of a suitable procedure for creep tests on polyurethane (PUR) foam materials immersed in mineral oil, which is also a typical loading scenario for supporting components in the machinery. This involves the development and implementation of a proper small load compression testing device, which enables the performance of compressive creep tests in media immersion at elevated temperatures. The resulting creep deformation was monitored as a function of time and further evaluated in the form of corresponding creep compliance curves \(D_{\mathrm{c}}(t)\) as the usual presentation of the creep properties. Further on, the creep behavior of various PUR foam materials was compared to their thermo-mechanical properties such as the elastic storage modulus \(E'\) determined by additional dynamic mechanical analysis (DMA). Thereby, a further correlation between the time- and temperature-dependent materials performance was established.

2 Experimental

For the characterization of soft polymeric foam materials under static long-term compression load, at first a proper testing device for application-related creep tests under direct media contact at elevated temperatures had to be developed. Thus the following features were in special focus: variable compression loading in the small load range, test performance at various elevated temperatures, and continuous deformation measurement of the foam specimens in media immersion. In this regard, a creep testing device was built up consisting of three compression loading units, which were separately controllable by an automated test start feature and implemented sensors for continuous load and displacement measurement (see Fig. 1). Each test rig was equipped with a small media container providing the performance of long-term creep measurements in a constant saturated material state (in the present case, foam specimens immersed in mineral oil).

Fig. 1
figure 1

Compression test device for creep tests on soft materials at elevated temperatures in media immersion: single components (a, left); complete equipment in temperature camber (b, right)

After the test specimen was placed inbetween the loading plates in the media container at the bottom plate, static load was applied by drive controlled downward moving of the upper loading plate with defined additional weight. Once full load was reached, the applied deadweight provided constant compression force over the entire measuring time. The creep-deformation was measured continuously by an LVDT placed on top of the moveable loading plate. All three test rigs were operated simultaneously in a standard temperature camber to perform the creep tests at various elevated temperatures.

Subsequently, the compression test device was implemented by a series of creep tests on various commercially available polyurethane foam grades provided by Getzner Werkstoffe GmbH (A). The chosen materials are commonly used for various damping applications at different load levels and thus show distinct variations in cellular structure and stiffness. An overview of the investigated foam types is given in Table 1 along with some of their characteristic properties.

Table 1 Investigated polyurethane (PUR) soft foam materials provided by Getzner Werkstoffe GmbH

By the use of cylindrical foam specimens (diameter: 20 mm, height: 20 mm) the single creep experiments were performed for loading times of 24 hours at constant compressive stress levels. With the prime goal to reach a creep deformation regime within compression region II, appropriate loading weights were chosen for various materials states also accounting for the buoyancy of the foam specimens in oil immersion. The resulting compression stresses \(\sigma _{0}\) directly measured underneath the foam specimens were ranging from 0.012 to 0.103 MPa for various material states.

Each stress level was given by the specific loading force F divided by the cross-section of the specimens \(A_{0}\) in the unloaded state. The continuously measured compressive deformation divided by the initial specimens height results in the time-dependent creep strain \(\varepsilon _{\mathrm{c}}(t)\), which was the basis for the further calculation of the compressive creep compliance as follows:

$$ D_{c} \left ( t \right ) = \frac{\varepsilon _{c} \left ( t \right )}{\sigma _{0}} $$
(1)

To characterize the influence of elevated temperature and oil content on the creep properties of the foams, the corresponding creep tests were performed in air and in oil immersion at 23 and 60 °C. Because of the typical application of PUR damping components in the machinery, for example, in cooling compressors, the refrigeration oil RenisoWF5A46 based on mineral oil was used for specimens conditioning. The oil-saturated materials state was provided by the storage of the foam specimens immersed in the test medium for 14 days at 60 °C, and the time-dependent oil uptake was monitored. As expected, the amount of oil uptake is closely related to the cell structure, which means high relative mass increase of 400 and 500 wt-% for the open cell foam types FPF-op1 and FPF-op2 and a significantly reduced corresponding value of about 40 wt-% for the closed cell foam type FPF-cl1; see Fig. 2. This is due to the smaller scaled cell volume of FPF-cl1 with cell diameters of about 130 μm compared to the open cell structured foams with cell diameters up to about 350 μm along with reduced deformability and permeability of the predominantly closed cell wall structures. Further detailed investigations concerning the oil contents under creep load and the corresponding poroelasticity of the foam materials were not carried out within the scope of this study. However, it should be noted that intercellular fluid content and thus the interaction between fluid flow and foam structure under load significantly influence the overall deformation behavior of the porous medium (Biot 1962; Cheng 2016). Particularly, the permeability of the present foam materials primarily determined by open vs. closed cell structures and the softening effect of the mineral oil on the polymeric material itself may be mentioned in this concern.

Fig. 2
figure 2

Time-dependent oil absorption of open and closed cell PUR foam types in oil immersion at 60 °C and SEM images of the corresponding cell structures

Prior to creep testing, cyclic short-term compression tests were performed for a basic characterization of the deformation behavior of the soft foam materials in dry state, also as a guidance for the definition of appropriate stress levels for the subsequent creep tests. The cylindrical foam specimens (diameter: 20 mm, height: 20 mm) were placed inbetween the parallel compression plates of a Zwick Z010 universal testing device (Zwick, Ulm, D) with a load cell capacity of 500 N. Monotonic loading and unloading cycles (10 cycles in each experiment) were applied with a test speed of 500 mm/min up to a compression strain of 50%. In each test the last loading cycle was extended to ultimate foam densification (compression strain >60%).

Finally, additional dynamic-mechanical analysis was performed on a DMA device type MCR 702 MultiDrive (Anton Paar, Graz, A) in compression mode to characterize the temperature dependency of the mechanical properties such as elastic storage modulus \(E'(T) \)and mechanical loss factor tan \(\delta \). In the DMA tests, cylindrical specimens (diameter: 5 mm, height: 5 mm) were loaded by precompression of 20% (respective specimens height under preload: 4 mm) to reach the relevant compression plateau region II. The precompressed state was superimposed by a dynamic displacement amplitude of 250 μm at a frequency \(f\) of 1 Hz. Temperature was increased from 30 up to 100 °C by a constant heating rate of 2 K/min. Based on the applied dynamic compression strain amplitude \(\varepsilon _{{A}}\), the resulting stress amplitude \(\sigma _{{A}}\) was measured, and the complex modulus \(E^{*}\) was calculated as follows:

$$ \left \vert E^{*} \right \vert = \frac{\sigma _{A}}{\varepsilon _{A}}. $$
(2)

Along with the also measured time shift \(\delta \)/\(\omega \) between stress and strain, the storage modulus \(E'\)(\(\omega \)) was determined for the test frequency \(f\) (\(\omega =2\pi f\)) of 1 Hz as follows:

$$ E' \left ( \omega \right ) = \left \vert E^{*} \right \vert \cdot \cos \delta . $$
(3)

Further on, the storage modulus, which is roughly equal to the elastic modulus for a single rapid stress at low load and reversible deformation (Ehrenstein et al. 2004), was compared to the corresponding creep properties of various foam materials. In this concern, the temperature dependency of the storage modulus may provide a useful guidance at least for a qualitative estimation of the creep behavior.

3 Results

A comprehensive overview of the compression behavior of various soft foam types in dry materials state at 23 °C was provided by the results of the cyclic compression tests (see Fig. 3). The characteristic three different regions of stress–strain behavior can be distinguished more or less pronounced depending on the specific foam type. Whereas the closed cell structured foam FPF-cl1 shows distinct stress increase over the whole range of compression with only small flattening in region II, the open cell foam types FPF-op1 and FPF-op2 reveal the typical plateau regime with only small stress increase over a wide compression strain range. Moreover, the included curve area within the loading and unloading cycles corresponds to the damping capability of the material, which is the largest for FPF-op2. Besides structural effects of this open cell foam, particularly its glass transition temperature of 15 °C, which is close to the test temperature, has a strong viscoelastic effect on the materials behavior revealing distinct mechanical losses.

Fig. 3
figure 3

Compression stress vs. strain curves for various soft foam types in dry state at 23 °C by cyclic loading and unloading (10 cycles) and final compression up to foam densification

Moreover, an analogous series of compression tests for the oil saturated materials state at 60 °C is shown in Fig. 4 compared to the corresponding results for the dry reference state at 23 °C. Whereas for the materials FPF-cl1 and FPF-op1, the oil immersed state at 60 °C leads to a comparable small decline of the compression stress level at similar damping behavior, a much stronger effect of oil immersion was observed for foam type FPF-op2. The significant drop in the compressive stress level with simultaneously reduced damping capacity is probably due to the decreasing influence of the glass transition, which is 15 °C for this foam type.

Fig. 4
figure 4

Compression stress vs. strain curves for various soft foam types in oil immersion at 60 °C for 10 loading and unloading cycles and the corresponding reference curves for the dry state at 23 °C (shadow lines)

To reach compression strain in the creep experiments within a range of about 10 to 60% (compression region II), which is recommended for optimal damping performance, the corresponding creep stress levels had to be defined. Considering the specific foam types and test conditions (temperatures 23 °C and 60 °C, materials states dry and oil-saturated), appropriate loading weights were chosen for various creep tests with resulting stress levels ranging from 0.012 to 0.103 MPa. Particularly for the oil immersed state, higher loading weights were chosen to account for the buoyancy of the test specimens still ensuring a resulting loading stress within compression region II. Figure 5 gives a comprehensive overview of the creep behavior showing the creep strain curves \(\varepsilon _{\mathrm{c}}(t)\) for various foam types and test conditions. The reached compression strain range roughly coincides with the intended and service relevant compression region II recommended for optimal damping.

Fig. 5
figure 5

Creep strain curves \(\varepsilon _{\mathrm{c}}(t)\) for various soft foam types and test conditions: stress levels 0.012 to 0.103 MPa, temperatures 23 °C and 60 °C, materials states dry and oil-saturated

Obviously, direct comparison of materials regarding initial deformation after loading and resulting creep rates is limited due to different loading stresses. However, the following general remarks are to be stated concerning the dependency of creep behavior of the foams on the various test conditions such as elevated temperature and media immersion.

Material type FPF-op1 was tested at creep stresses of 0.012 and 0.021 MPa to reach an overall creep deformation regime (plateau region II) for various test conditions at 23 °C and 60 °C in air and in oil immersion at 60 °C. Thus the initial creep compliance levels \(D_{\mathrm{c}}(t)\) were significantly differing, showing a small initial increase of the short-term compliance from about 8.5 to 10 MPa−1 due to the elevated temperature of 60 °C. The creep test at 60 °C also reveals the largest creep rate for the dry material state ending up at a creep compliance level of about 23 MPa−1 (see Fig. 6) after a loading time of 24 hours. On the other hand, a large increase of the initial compliance to about 19 MPa−1 was noticed for the oil immersed state. The corresponding compression strain of 40% is close to the regime of significant foam densification (cf. Figs. 3 and 4), which for the oil immersed state at 60 °C is reached in the initial loading phase along with comparatively low creep tendency. Besides the general acceleration of the creep rate at increased temperatures (Ferry 1980), in the case of PUR materials, elevated temperatures are known to cause hydrogen bond disruption, which leads to an additional increase of the creep rates in the temperature range investigated (Kaushiva 1999).

Fig. 6
figure 6

Time dependency of creep compliance \(D_{\mathrm{c}}(t)\) for the open cell PUR foam type FPF-op1 at test temperatures of 23 °C and 60 °C and for the oil immersed state at 60 °C

Analogous creep tests were performed for the second open cell PUR foam type FPF-op2 at increased load levels of 0.026 and 0.031 MPa to reach the relevant foam compression range within region II. The resulting creep compliance curves \(D_{\mathrm{c}}(t)\) for various test conditions (23 and 60 °C in air, 60 °C in oil immersion) are shown in Fig. 7. Significant time-dependent increase of the creep compliance in the initial phase of the creep tests is ending up in a compression regime with distinctly reduced creep tendency for longer loading times. Whereas this is evident especially for a test temperature of 23 °C, the elevated temperature of 60 °C, particularly for the oil immersed state, leads to a large immediate increase of the creep compliance reaching a densified condition with reduced creep rate.

Fig. 7
figure 7

Time dependency of creep compliance \(D_{\mathrm{c}}(t)\) for the open cell PUR foam type FPF-op2 at test temperatures of 23 °C and 60 °C and for the oil immersed state at 60 °C

Finally, the corresponding creep compliance curves for the closed cell PUR foam type FPF-cl1 at stress levels of 0.099 and 0.103 MPa are shown in Fig. 8. Mainly due to the denser, closed cell structure and the comparatively small amount of oil uptake, generally a low level of compressive compliance along with reduced creep tendency was observed for all test conditions investigated. In this case, temperature increase particularly in oil immersion leads to a slighter increase of the creep compliance due to temperature and media influence.

Fig. 8
figure 8

Time dependency of creep compliance \(D_{\mathrm{c}}(t)\) for the closed cell PUR foam type FPF-cl1 at test temperatures of 23 °C and 60 °C and for the oil immersed state at 60 °C

In an additional test series, the present PUR foam materials were investigated by dynamic-mechanical analysis (DMA) in compression mode to characterize the temperature-dependent storage modulus \(E'\) and the mechanical loss factor tan \(\delta \) within a temperature range from 30 to 100 °C (see Fig. 9). In good agreement with the creep properties of various PUR foam types, the temperature dependency of the corresponding dynamic-mechanical properties shows similar trends. Thus the quite temperature stable modulus and loss factor levels of closed cell foam type FPF-cl1 determined by DMA correlate with the lowest creep rate among the present foam types investigated. A slight increase of storage modulus with rising temperature is probably the result of thermal expansion of the foam specimens inducing larger stress amplitudes at constant dynamic elongation. Further on, entropy elastic effects of the elastomeric polymer could be a further reason for modulus increase in the regime above Tg (Schwarzl 1990).

Fig. 9
figure 9

Compressive storage modulus \(E'(T)\) and mechanical loss factor tan \(\delta \) determined by DMA as functions of temperature for various PUR foam types

On the other hand, a temperature-dependent modulus decrease was determined for foam type FPF-op1, generally on a lower modulus regime for this open cell structured foam. The enhanced creep tendency of this material particularly at higher creep test temperature correlates with the distinctive temperature dependency of the storage modulus shown in DMA.

Finally, the second open cell foam type FPF-op2 showed the most significant decrease of the temperature-dependent compressive modulus in DMA along with the highest mechanical damping level among the foam materials investigated. This pronounced temperature dependency within the investigated range from 30 up to 100 °C can be attributed to the glass transition temperature of 15 °C for this foam type, which is close to the present test temperature range. As mentioned before, the neighboring glass transition is a dominant influencing factor for the creep behavior at room temperature and above and thus was also noticed in the pronounced increase of creep compliance for foam type FPF-op2 particularly in the initial time range at 23 °C.

4 Summary

A small load compression creep testing device suitable for the characterization of time-dependent deformation of polymeric soft foam materials under static load was developed. With the special focus on the performance of creep tests under direct liquid media influence, the test arrangement includes containers fillable with the specific liquid providing tests in media immersion. Moreover, the whole arrangement can be positioned in a temperature camber allowing the corresponding creep investigations also at elevated temperatures up to 80 °C.

Within the present study, this creep testing device was successfully implemented by creep investigations on various PUR soft foam materials with different densities and cell structures, both in dry state and immersed in mineral oil at 23 and 60 °C. Depending on the individual structural state of the investigated foam types (cell size, open vs. closed cell structure), various materials showed distinct differences in their creep behavior according to the specific test parameters. In this regard, open cell structure and elevated temperature are enhancing factors for the materials creep, particularly for a temperature range close to glass transition. This result was also confirmed by additional thermomechanical analysis of the foam materials revealing temperature dependencies of the compressive storage modulus in good agreement with the corresponding creep behavior. Moreover, oil absorption of polymeric foam causes distinct materials softening, which results in larger initial deformation under creep load but reduced further creep deformation due to the larger compressed materials state.