Crosslinking structure and properties of poly(urethane-urea) elastomers.Poly(urethane-urea) elastomers have been widely used in a variety of fields. They show excellent mechanical properties such as high tensile strength tensile strength Ratio of the maximum load a material can support without fracture when being stretched to the original area of a cross section of the material. When stresses less than the tensile strength are removed, a material completely or partially returns to its and abrasion abrasion /abra·sion/ (ah-bra´zhun) 1. a rubbing or scraping off through unusual or abnormal action; see also planing. 2. a rubbed or scraped area on skin or mucous membrane. resistance. Taking advantage of these features, the elastomers are used in solid tires for vehicles, conveyer belts, timing belts, hoses and blades for a copy machine. A urethane-urea elastomer elastomer (ĭlăs`təmər), substance having to some extent the elastic properties of natural rubber. The term is sometimes used technically to distinguish synthetic rubbers and rubberlike plastics from natural rubber. is synthesized by poly-addition reaction of a prepolymer, having isocyanate i·so·cy·a·nate n. Any of a family of nitrogenous chemicals that are used in industry and can cause respiratory disorders, especially asthma, if inhaled. groups at the end of the polymer chain, and a diamine di·am·ine n. Any of various chemical compounds containing two amino groups, especially hydrazine. Noun 1. diamine - any organic compound containing two amino groups . The molecular structure of poly(urethane-urea) elastomers (hereafter urethane urethane (yoor´ithān´), n ethyl carbamate used as an anesthetic agent for laboratory animals, formerly used as a hypnotic in humans. ) has been extensively studied (refs. 1-5). Most of these studies point out that a urethane elastomer consists of soft and hard segments, the hard segments form molecular blocks. Strong hydrogen bonds hydrogen bond n. A chemical bond in which a hydrogen atom of one molecule is attracted to an electronegative atom, especially a nitrogen, oxygen, or fluorine atom, usually of another molecule. exist between the molecules in the hard segments and the hard segments work as crosslinks. These bonds are often called physical bonds. When a component of the hard segment, isocyanate, exists more than the chemically equivalent amount of amine amine (əmēn`, ăm`ēn): see under amino group. amine Any of a class of nitrogen-containing organic compounds derived, either in principle or in practice, from ammonia (NH3). , the other component of the hard segment, chemical crosslinks are formed between the urea or urethane groups of those segments and the excess isocyanate. This chemical bonding, for example, between the urea and isocyanate is called Biuret bonding (figure 1). Thus, a urethane elastomer has both chemical and physical bondings when isocyanate groups excessively exist The authors studied the mechanical properties of urethane elastomers and the effect of heat treatment of urethanes in relation to crosslinking structures by analyzing the compressive com·pres·sive adj. Serving to or able to compress. com·pres  sive·ly adv. mechanical properties of swollen rubber in two solvents. This method gives us information on the quantity of both chemical and physical crosslink density of a urethane. The application of this method to solve industrial problems will be also reported. Experimental Sample preparation Poly(tetra-oxymethylene glycol glycol (glī`kōl), dihydric alcohol in which the two hydroxyl groups are bonded to different carbon atoms; the general formula for a glycol is (CH2)n(OH)2. )di-isocyanates were used as prepolymers. Both polymers have isocyanate groups at the telechelic position of the poly(tetra-oxymethylene glycol) chains. A methylene-ortho- chloro-aniline (hereafter MOCA MOCA Museum of Contemporary Art MOCA Multimedia over Coax MoCA Museum of Chinese in the Americas MOCA Minnesota Ovarian Cancer Alliance MOCA Montezuma Castle National Monument (US National Park Service) , having two amine groups) was employed as a curing agent for these prepolymers. The prepolymer was degassed in a flask flask (flask) 1. a laboratory vessel, usually of glass and with a constricted neck. 2. a metal case in which materials used in making artificial dentures are placed for processing. , stirred at 80[degrees]C under a reduced pressure In thermodynamics, the reduced pressure of a fluid is defined as its actual pressure divided by its critical pressure. A/I ARC/INFO A/I Accident/Incident A/I Adsorption Isotherm A/I Anti-Ice A/I Aircraft Inspector (also seen as AI) ratio) varied from 0.82 to 1.1. It should be noted that the chemical bonds exist below a A/I ratio of 1.0 when the completion of reaction is assumed. After curing, the sheet was stored in a desiccator des·ic·cate v. des·ic·cat·ed, des·ic·cat·ing, des·ic·cates v.tr. 1. To dry out thoroughly. 2. To preserve (foods) by removing the moisture. See Synonyms at dry. 3. for a week before testing. Characterization of crosslink structure A 2mm cubic sample was cut from the sheet and its compressive strain and stress properties were measured in two solvents, chloroform chloroform (klôr`əfôrm) or trichloromethane (trī'klôrōmĕth`ān), CHCl3 and tetrahydrofuran tetrahydrofuran: see furfural. . The instrument employed in this measurement is illustrated in figure 2. The solubility solubility Degree to which a substance dissolves in a solvent to make a solution (usually expressed as grams of solute per litre of solvent). Solubility of one fluid (liquid or gas) in another may be complete (totally miscible; e.g. parameters of chloroform and tetrahydrofuran are 9.3 and 9.35, respectively (ref. 7). Though the difference in solubility parameter for both the solvents is small, chloroform dissolves only the soft segment of a urethane elastomer, poly(tetra-oxymethylene glycol) chains, while tetrahydrofuran dissolves both the soft and the hard segments. In other words Adv. 1. in other words - otherwise stated; "in other words, we are broke" put differently , chloroform remains both chemical and physical bondings while tetrahydrofuran leaves chemical bonds. This is attributed to the difference in polarity (1) The direction of charged particles, which may determine the binary status of a bit. (2) In micrographics, the change in the light to dark relationship of an image when copies are made. of the two solvents. Rubber test samples were evaluated after reaching an equilibrium in solvent, step by step, adding weight to the weight tray of the test instrument (figure 2). The resulting compressive strain of the swollen rubber was measured using a linear transducer transducer, device that accepts an input of energy in one form and produces an output of energy in some other form, with a known, fixed relationship between the input and output. The network chain density of the rubber was calculated using equation 1 (ref. 6). (1) v=[Vr.sup.1/3] F/RT(a-[a.sup.2])Ao where: v: network chain density Vr: volume fraction of rubber in a swollen gel F: applied weight R: gas constant T: absolute temperature [alpha]: compression ratio compression ratio Degree to which the fuel mixture in an internal-combustion engine is compressed before ignition. It is defined as the volume of the combustion chamber with the piston farthest out divided by the volume with the piston in the full-compression position ( Ao: cross sectional area of a sample before swelling When using chloroform as a solvent, the network density obtained by the equation 1 contains both the physical crosslinks and the chemical crosslinks (hereafter defined as [v.sub.c]). On the other hand, only the chemical network density(hereafter defined as [v.sub.t]) is obtained by using tetrahydrofuran as a solvent. Accordingly, the physical crosslinks are obtained as the difference between the [v.sub.c] and the [v.sub.t] . Mechanical properties The stress strain properties and tear strength were measured using a tensile tester at a cross head speed of 50 mm/mint A test piece of 1 cm by 10 cm was cut from the sheet and a 2 mm cut was made at the edge in the center of the test piece for the tear strength measurement. JIS JIS Japanese Industrial Standard JIS Jamaica Information Service JIS Juggling Information Service JIS Just in Sequence (automotive industry) JIS Jakarta International School JIS Joint Information System 3 dumbbell Dumbbell An investment strategy, used mainly for bonds, where holdings are heavily concentrated in both very short and long term maturities. Notes: This is also known as a barbell, charting on a timeline gives the appearance of a barbell or dumbbell. type test pieces were used for the tensile measurement. A creep test was carried out at 80[degrees]C. Test pieces of 1 cm by 10 cm were used in this measurement. A dynamic fatigue tester was used at 500 cycles per minute with a strain of 10% to evaluate the fatigue life of the elastomer. And another dynamic fatigue test using urethane tubings was done according to according to prep. 1. As stated or indicated by; on the authority of: according to historians. 2. In keeping with: according to instructions. 3. JIS L 1017-1983, originally designed for fiber testing. Urethane tubings of o24 cm long, 2.7 cm outer diameter and 1.9 cm inner diameter respectively, were prepared. Then the inside of the tubings was inflated with air at a pressure of 0.34 MPa and rotated the samples at 1,000 rpm. The tubings were bent at an angle of 40[degrees] to give both compressive and tensile strains reciprocally to the samples. Heat treatment The effect of heat treatment on the urethane was evaluated. For this test, urethanes with 0.82 A/I ratio were employed. The samples were treated in an oven at 100-150[degrees]C for up to 50 hours before testing. Results and discussion Network chain density Tetrahydrofuran and chloroform have almost the same solubility parameter, yet the swelling characteristics of urethane to each solvent is quite different (figure 3). The relationship between the A/I ratio and [v.sub.c] and [v.sub.t] is shown in figure 4. From this figure, it is seen that [v.sub.t] goes to almost zero at an A/I ratio of 1.0 suggesting that the [v.sub.t] represents the network chain density based on only the chemical bonds. When one subtracts the [v.sub.t] from the [v.sub.c], it is observed that the difference which denotes physical bondings (hereafter [v.sub.p]) is almost independent of the A/I ratio up to 1.0. At a ratio of 1.1, the [v.sub.c] (=[v.sub.p]) slightly reduced. This is possibly attributed to a kind of plasticizer plas·ti·ciz·er n. Any of various substances added to plastics or other materials to make or keep them soft or pliable. plasticizer or -ciser Noun effect of the excess amine which affects the hard segments of the urethane elastomer. Table 1 shows the relationship between the A/I ratio and the molecular weight of the chain between crosslink points (hereafter Mc). It should be noted that the Mc, calculated from the [v.sub.t], must theoretically be infinity at the A/I ratio of 1.0, however, the Mc observed vas 5,100 at that point. This may be attributed to the technical difficulty of precise determination of the number of isocyanate groups of a prepolymer, incompleteness of the reaction or an error in measuring the raw materials prior to reaction. Mechanical properties and crosslink structure The mechanical properties of urethane elastomers depend on the complex crosslink structure and a function of the A/I ratio. Figure 5 shows the stress strain properties of urethane elastomers in relation to their A/I ratio. This shows a strong relation between the strain at failure of an elastomer and an increase in the A/I ratio. Similarly, the energy of tearing, the elasticity at 10% strain, the fatigue resistance, and the creep of the urethane elastomers as tabulated in table 2 show a strong dependence on the A/I ratios. The tearing energy, fatigue resistance and creep deformation increase with the increase of the A/I ratio. It should be pointed out that the total crosslink density ([v.sub.t] +[v.sub.p] = [v.sub.c] ) decreases as A/I ratio increases (figure 4). It is well known that the similar phenomena were observed for sulfur cured elastomers (ref. 11) and almost the same elucidation e·lu·ci·date v. e·lu·ci·dat·ed, e·lu·ci·dat·ing, e·lu·ci·dates v.tr. To make clear or plain, especially by explanation; clarify. v.intr. To give an explanation that serves to clarify. may be applied to the relationship between the above properties and the crosslink chain density. It was found that a plot of the elongation elongation, in astronomy, the angular distance between two points in the sky as measured from a third point. The elongation of a planet is usually measured as the angular distance from the sun to the planet as measured from the earth. (strain at failure divided by the original length) defined as ab, the plots of ab versus [v.sub.c], is a linear relationship (figure 6) with a slope of one-half This result can be explained by a theory proposed by Smith (ref. 8). Smith found that when folded polymer chains between crosslink points extend to the limit of their length at failure, the following equation results. [[alpha].sub.b] =k [[v.sub.c].sup.1/2] where k is a constant. Figure 7 shows the change of the [v.sub.p] and the [v.sub.t] with strain. The [v.sub.p] decreases as strain increases while [v.sub.t] remains constant. This result implies that the hard segments which form the physical crosslink points are gradually destroyed when the polymer chains are extended. However, the chemical bonds are not destroyed until the polymer chains are broken. To know the change in crosslink structure of urethane by mechanical fatigue, the tube test, JIS L1017-1983 was carried out as described earlier. The maximum temperature observed during the test was about 110[degrees]C for all samples The change of crosslink structure before and after the test is shown in figure 8. Decrease of crosslink density after the fatigue test is observed for all samples. However, this is more remarkable for the samples at lower A/I ratio and the decrease of the [v.sub.t] contributes a great deal whereas the [v.sub.p], physical crosslink density, shows small change. Heat treatment The change of the [v.sub.t] versus time at 100-150[degrees]C is shown in figure 9. It is found that the change of the [v.sub.t] in this figure is expressed by a first order reaction. When an Ahrenius type reaction is assumed, the rate constant k is expressed by the following equation. (3) k = Aexp(-E/RT) where: A: frequency factor E: activation energy activation energy, in chemistry, minimum energy needed to cause a chemical reaction. A chemical reaction between two substances occurs only when an atom, ion, or molecule of one collides with an atom, ion, or molecule of the other. R: gas constant T: absolute temperature From the k versus 1/T plot, E was found to be 28.5 kcal/mole. This E value coincides with the value obtained by Tobolsky for biuret bonding (ref. 8). Figure 10 presents the mutual relationships among temperature. length of heat treatment time, and the v/v0. When two parameters out of the three are known, the remaining parameter can be determined from the figure. Using this figure, one can estimate the temperature or time when a urethane sample is treated. Application to a practical problem * Service life of urethane sieve in use. Polyurethane elastomers have excellent abrasion resistance and are used in a quarry as sieves to classify macadam macadam Form of pavement invented by John McAdam. McAdam's road cross-section consisted of a compacted subgrade of crushed granite or greenstone designed to support the load, covered by a surface of light stone to absorb wear and tear and shed water to the drainage ditches. . Occasionally, the service life of a sieve was much shorter than expected, for unknown reason. Figure 11 shows the crosslink structure of urethane sieves used for one year under a normal condition. Small difference can be seen between the original crosslink structure and the sieve. On the other hand, a sample which cracked in use shows no chemical crosslinks (also shown in figure 11). Since the decrease of chemical crosslinks in a urethane elastomer is caused by heat and moisture, it is strongly suggested that this sample was used excessively in hot and humid conditions. * Urethane sieve stored. Urethane sieves stored in a warehouse (sample A) for five years showed cracks. Whereas others stocked in another warehouse (sample B) did not. The warehouse for sample A (hereafter house C) is a simple house which allowed moisture and air penetration. Contrary, the warehouse for sample B was air conditioned. Change in crosslink density for both sample A and B was analyzed. Test pieces were cut from the surface of samples, 100p thick, step by step, to a depth of 1 mm. Since the thickness of each sample is too thin to apply the compressive swollen method, the Flory-Huggins equation (ref. 10) was used to obtain crosslink densities. The interaction parameter between solvent (tetrahydrofuran) and urethane was determined by using the compressive swollen method as 0.365 at 20[degrees]C, beforehand. Figure 12 shows a depth profile of crosslink density from the surface to 1 mm. Though both sample A and B show decrease in [v.sub.t], comparing with that of the original product, the decrease is dominant for sample A, especially in the surface region. This suggests that the cracks in sample A were caused by moisture and hot air in house C in summer time. Conclusions The crosslink structure of poly(urethane-urea) elastomers was studied by analyzing the compressive stress-strain properties of the elastomers under an equilibrium swollen state in two solvents. The crosslink chain density measured in chloroform; [v.sub.c] represents both the chemical and physical crosslinks. On the other hand, the crosslink chain density measured in tetrahydrofuran; [v.sub.t] represents only the chemical crosslinks. when the elongation (strain at failure divided by the original length of a sample) defined as [[alpha].sub.b], was plotted versus [v.sub.c], a linear relationship with a slope of one-half resulted This result can be explained by the theory proposed by Smith (ref. 8). It was also observed that [v.sub.p] decreases as strain increases while [v.sub.t] remains constant. This result implies that the hard segments which form the crosslink points were gradually destroyed when the polymer chains were extended. However. the chemical bonds are not destroyed on stretching until the polymer chains are broken. It is found that the change of [v.sub.t] in heat treatment can be expressed as a first order reaction. The activation energy E was found to be 28.5 Kcal/mole and this value coincides with the value obtained by Tobolsky for biuret bonding (ref. 9). The mutual relationships among temperature, time of heat treatment, and the network chain density before and after heat treatment; v/[v.sub.o] were developed. When two parameters out of the three are known, the third parameter can be determined. These relationships are useful to estimate the time or temperature history of a sample. The analysis of crosslink structure of poly(urethaneurea) elastomers was successfully applied to solve practical industrial problems. [Figures 1 to 12 ILLUSTRATION OMITTED] Literature (1.) R. Bonart, L. Morbitzer and G. Hentze, J. Macromol. Sci., B3 (2) 337 (1969). (2.) I. Kimura, H. Ishihara, H. Ono, N. Yoshihara, S. Nomura and H. Kawai, Macromolecules Macromolecules A large molecule composed of thousands of atoms. Mentioned in: Gene Therapy macromolecules 7, 335 (1974). (3.) G.M. Estes, R.W. Seymour and S.L. Cooper: ibid, 4,452 (1971). (4.) L.M. Leung and J. T. Koberstein, J. of Polymer Sci., Polymer Phys. Ed phys. abbr. 1. physical 2. physician 3. physiological 4. physiology ., 23, 1883 (1985). (5.) Polyurethane Handbook, K. Iwata Ed., Ch. 2, Nikkan Kogyo Press (1987) (6.) P.A. Small, J. Appl. Chem., 3, 71 (1953). (7.) M. Yamamoto: Properties and processing of rubbers, Chijin Shokan, Tokyo (1965). (8.) T.L. Smith and A.B. Yagnussun: Rubber Chemistry and TechnoL, 35, 753 (1962). (9.) P.C. Colodmy and A.V. Tobolsky: J. Am. Chem. Soc., 71, 4320 (1957). (10.) P. J. Flory: Principle of polymer chemistry Polymer chemistry or macromolecular chemistry is a multidisciplinary science that deals with the chemical synthesis and chemical properties of polymers or macromolecules. , Cornell Univ. Press, New York New York, state, United States New York, Middle Atlantic state of the United States. It is bordered by Vermont, Massachusetts, Connecticut, and the Atlantic Ocean (E), New Jersey and Pennsylvania (S), Lakes Erie and Ontario and the Canadian province of (1954). (11.) A.Y. Coran: Science and technology of rubber, Chapter 7, Academic Press, (1978). |
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