Rubber Solutions Research Articles

Theoretical and experimental investigation of shearing in elastic polymer liquids

In the present paper a rheologic theory (1) has been compared to results of different shear experiments in the region of moderate elastic strains using a polymer solution as an example. The 40% butyl rubber solution (M ≈ 3 ⋅ 104) in transformer oil has been employed as tested liquid. A major part of the experimental data has been obtained on the Weissenberg Rheogoniometer. The three and five constants rheologic models (the first and second approximations) have been discussed. Model constants have been defined in the linear region of the rheologic behaviour of the solution using dynamic characteristics.

Casts of chorodial vasculature at physiologic pressures. A new technique.

A method for making latex rubber casts of the ocular vasculature while maintaining physiologic vascular relations has been developed. A series of short-haired domestic ctas, Rhesus monkeys, and albino rabbits were anesthetized and cannulated in the common carotid arteries. The jugular veins were severed, and heparinized saline was infused into the carotid arterial circulation of the animals for complete exsanguination of the head. Throughout the infusion procedure, normal physiologic pressure was maintained. After exsanguination was complete, a solution of latex rubber in distilled water was infused bilaterally and continued until the flow from the jugular veins ceased. The eyes were enucleated and placed in a curing solution. After fixation, the eyes were selectively trimmed and placed into a solution of sodium hydroxide for digestion. The digested tissue was transferred to distilled water for dissection. After dissection, the cast was closely inspected for completeness of capillary filling. Casts such as these are intended for use in observations of ocular vascular anatomy.

Structural control of rubber modified thermoplastic as produced by the mass process

AbstractCommercially important polyblends can be produced by a mass process which proceeds via the dispersion of a rubber solution phase. During the process several distinct stages can be identified and structural variation of the final polymer is achieved by controlled agitation. The relationship between the nature and structure of the dispersed phase and the mechanical properties of the polyblend are illustrated and discussed in the light of current theories of impact enhancement.

Polymer/particulate filler interaction—the bound rubber phenomena

In Part I, after an historical note on the subject of bound rubber, the experimental determination of bound rubber and the many factors affecting the value, in the case of the organic rubber/carbon black and silicone rubber/silica systems, are reviewed. Mention is made of the relation between swelling index and bound rubber and, in Part II, the accuracy and significance of bound rubber values are appraised. Some experimental work on the natural rubber/fine particle black system is described in Part III; this assesses qualitatively the rigidity of swollen jellies of the (unvulcanized) mixtures and shows how it is not correlated with either bound rubber or solvent content. Other experiments lead to the conclusion that the uptake of solvents of different solubility parameters compares with that of a pure gum vulcanisate, indicating no significant or substantial change in the solubility parameter of the rubber on becoming insolubilized. Results are reported on bound rubber determinations in solutions of rubber and it is suggested that these provide a method of arriving at the true bound rubber value. The discussion which forms Part IV suggests how the two structures, postulated recently as present in polymer/filler systems, might be further analysed to explain the phenomena.

The Determination of Network Chain Density and the Chemical Stress Relaxation of Crosslinked Polymers

Abstract Both initial network chain densities nM(0) and nS(0) of dicumyl peroxide- cured natural rubbers were determined from the tensile stress and swelling method, respectively. The difference between nM(0) and nS(0) was usually constant, independent of the magnitude of network chain density. That is, it was found that the number of entanglement network chains in the crosslinked natural rubber was usually constant, independent of network chain density. The entanglement network chain density nII(0) was 0.7×10−4 mole/cc. This led to the supposition that the molecular weight between entanglement points Me would be about 9000. Although this value is far from exact, it does not differ too greatly from the value found for noncrosslinked natural rubber. Next, in order to calculate the number of main-chain scissions of crosslinked polymers from their chemical stress relaxation, we proposed our modification of Tobolsky's equation. Using our equation, it was found that the scission of dicumyl peroxide-cured natural rubber occurred in the main chain only. Furthermore, this value agreed with the one obtained from the oxidation of toluene solution of noncrosslinked rubber under the same conditions.

Experimental determination of the influence of periodic shear deformation and filling on the effective viscosity of solutions of synthetic rubber

The influence of periodic shear deformation on the effective viscosity of filled solutions of synthetic rubber has been studied. The study was carried out on an amplitude-frequency viscosimeter developed by the authors. It has been established that during periodic deformation a linear region exists in which the effective viscosity is independent of the vibration rate, and a nonlinear region where the effective viscosity of the solutions decreases with increase in amplitude of the speed of relative deformation.

Application of metallic membrane filters in the clarification of styrene-butadiene rubber solutions for gel permeation chromatography

Application of metallic membrane filters in the clarification of styrene-butadiene rubber solutions for gel permeation chromatography

On the solubility parameter of polar polymers

AbstractThe binary cluster integral, β, was computed from intrinsic viscosity data. Subtracting from β the polar contribution, βe, calculated from YRCR theory,9 the nonpolar interaction parameter, βn, was found. The calculations were performed for poly(vinylacetate) and poly(methyl methacrylate), each in 16 solvents. The correlation between βn and the solvent solubility parameter, δ1, was found to be similar to that reported8,17 for solutions of natural rubber, cis‐polybutadiene and for poly(vinyl chloride). This correlation can be crudely approximated by the formula where E and F are functions of the ill‐defined symmetry of the solvent molecule and δm is the δ1 value for the local maximum of the function. At δ1 = constant, the more spherical is the molecule, the higher is the βn value. It was shown that for most cases separation of the solvent into two classes (linear and nonlinear) is sufficient. This βn behavior finds support in the Funk and Prausnitz6 report on aromatic–saturated hydrocarbon mixtures and in the theoretical calculations of Huggins.21,22

The determination of network chain density and the chemical stress relaxation of crosslinked polymers

AbstractBoth initial network chain densities nM(0) and ns(0) of dicumyl peroxide‐cured natural rubbers were determined from the tensile stress and swelling method, respectively. The difference between nM(0) and nS(0) was usually constant, independent of the magnitude of network chain density. That is, it was found that the number of entanglement network chains in the crosslinked natural rubber was usually constant, independent of network chain density. The entanglement network chain density nII(0) was 0.7 × 10−4 mole/cc. This led to the supposition that the molecular weight between entanglement points (Me) would be about 9000. Although this value is far from exact, it does not differ too greatly from the value found for noncrosslinked natural rubber. Next, in order to calculate the number of main‐chain scission of crosslinked polymers from their chemical stress relaxation, we proposed our modification of Tobolsky's equation. Using our equation, it was found that the scission of dicumyl peroxide‐cured natural rubber occurred in the main chain only. Furthermore, this value agreed with the one obtained from the oxidation of toluene solution of noncrosslinked rubber under the same conditions.

A Polyester Casting Process for Replicating Cliff Surfaces for Artistic Purposes

The first named author of this note set for himself the project to replicate parts of a forty-foot-high cliff in the Catskill Mountains of the State of New York, for which he developed the process described below. The molding process was begun by waxing the face of a cliff part with a product called a 'separator' to ease the removal of a sprayed rubber mold. Holes and crevices that were too deep to receive the rubber spray were stuffed with paper. Then numerous coats of rubber solution were applied (cf. Fig. 1). To strengthen the rubber layer, which was too thin and brittle to withstand its removal, a urethane foam was sprayed over the rubber. Most of the spraying devices were specially designed. Ten to fourteen

Structure of solution grafted polybutadiene

AbstractThree different polybutadienes possessing widely different vinyl and cis monomer structures have been grafted with methyl methacrylate in solution using both benzoyl peroxide and azobisisobutyronitrile catalysts. Careful fractionation and backbone degradation techniques together with molecular weight determinations lead to the conclusions that both catalysts gave graft copolymer in the 10% rubber solutions used. Benzoyl peroxide always gave better graft efficiencies, (as did high vinyl and to a lesser extent high cis polybutadiene). The molecular weight of the polymethylmethacrylate grafts are slightly lower than those of homopolymers polymerized under the same conditions indicating < 20% grafting by chain transfer and termination mainly by disproportionation.

Heterogeneous polymer systems. V. Viscosity behavior of polymerizing solutions of rubber in styrene

Heterogeneous polymer systems. V. Viscosity behavior of polymerizing solutions of rubber in styrene

Densification behavior of Fe, Co, and Ni powders with additions of zirconium, niobium, and molybdenum carbide powders

1. The densification behavior of Fe-ZrC, Fe-NbC, Fe-Mo2C, Ni-ZrC, Ni-NbC,Ni-Mo2C,Co-ZrC, Co-NbC, and Co-Mo2C mixtures was investigated. It was observed that increasing the carbide content of mixtures intended for pressing raises their porosity at pressures above 10–15 kg/m2 and lowers it at lower compaction pressures. 2. The dependence of the density of compacts on compaction pressure and carbide content was established. It was found that the magnitude n, which appears in Eq. (1), is a linear function of the amount of the second component over a wide range of carbide contents of a mixture. The magnitudes n0 and K0 in Eq. (4) are determined by the physicomechanical properties of the mixture components. 3. It was demonstrated that the presence of a lubricant (solution of synthetic rubber in benzine) exerts no significant influence on the value of n and on its rate of variation, i.e., on the value of K0. 4. The effects of compaction pressure and the amount of a second component on compact porosity was studied. A hypothesis is advanced postulating that the same mechanism controls the deformation of sintered metal-powder materials and the deformation of powders subjected to densification in a closed die in the second stage of compaction.

Study of the viscous flow of dimethylsiloxane polymer and rubber solutions over a wide range of deformation rates

Study of the viscous flow of dimethylsiloxane polymer and rubber solutions over a wide range of deformation rates

Rheological Properties of Disperse Systems of Butyl Rubber Solutions and Carbon Black

プチルゴムの流動パラフィン溶液に,粒子径の異なった2種類のカrボンブラックを分散させた系のレオロジー的性質について研究した。分散系の塑性粘度ηP1.降伏値Sy,動的粘性率η',動的剛性率G'を2種類の回転円筒型レオメータ.一によって測定した。えられたおもな結果はつぎのとおりである・(1)Cassonの式S1/2=K0+KD1/2(ここでS はせん断応力,Dはせん断速度,K0,K1は定数)はニュートン液体を分散媒とする分散系においてはよく成立するが,非ニュートン液体を分散媒とする分散系においては,Dが非常に低くないかぎり成立しない。(2)Cassonの式から求めた降伏値Syが分散媒の粘度や測定温度に依存しない系もあるが,それらに依存する系もある。その事情は測定条件,すなわち分散媒や粒子の種類,測定温度によって変化する。(3)分散系特有の非ニュートン流動は低せん断速度領域あるいは低せん断応力領域において顕著である。この点は高分子溶液あるいは溶融物の非ニュートン流動と非常に異なる・(4)降伏値が温度に依存しない系においては,塑性粘度ηP1に対して時間一温度の重ね合わせの原理がタイムスケールの全領域にわたって適用できるが,降伏値が温度に依存する系においては,時間一温度の重ね合わせの原理ほ適用できない。(5)時間一温度の重ね合わせが可能ならば,著者らの実験範囲において,移動係数αTは粒子濃度に無関係である。(6)分散系の塑性粘度ηP1と分散媒自身の粘度ηmの比は,高せん断速度領域で一定値になる。この一定値は分散系中の高分子濃度約0.3%で極大をもつ.(7)今回の研究においては,降伏値の値と粒子の大きさの間に相関関係が認められなかった。

Non-Newtonian effects in axially symmetric rotational flows of some elastico-viscous liquids

In recent years new materials of industrial importance have become known whose rheological properties cannot be adequately characterized by the classical Newtonian working model, many of these materials exhibiting both viscous and elastic properties. The large-scale flow behaviour of some of these new materials can be strikingly different from that of purely viscous liquids. For example, when sheared between coaxial cylinders, some liquids are observed to ‘climb up’ the inner cylinder, i.e. the free surface rises spectacularly near the inner boundary. This phenomenon has been observed by many authors (see, for example (1–4)), and is now widely known as the Weissenberg effect. Again, Merrington (5) observed that a stream of rubber solution ‘swells’ radially immediately on emerging from a capillary tube. In order to attempt to explain behaviour such as this, we must examine the consequences of a working model which is more complex than that for Newtonian liquids.

Accelerated Oxidations of Polyisoprene. I. Metal-Catalyzed Oxidations in Solution

Abstract Most of our work was carried out at 50° C with about 2 per cent solutions of synthetic polyisoprene in chlorobenzene. In many experiments, oxygen absorption and decrease in viscosity were followed together. Viscosity changes are a very sensitive measure of chain cleavage of high molecular weight polymers but of little use with degraded polymers; for the latter some number average molecular weights are available. The effects of several metal compounds were examined on both undegraded and partly degraded rubber solutions; for metal catalysis some peroxides are also required. Unless oxidation is initiated by a free radical source such as 2,2′-azobis-(2-methylpropionitrile) or unless a peroxide (e.g., t-butyl hydroperoxide) is added initially, considerable time elapses before the catalytic effect of the metal becomes obvious. The lower valence form of the metal often has a net retarding effect on oxidation at this stage. In partially oxidized solutions, however, the metals catalyze oxidation at once. Addition of metal salts to degraded rubber solutions, even in the absence of oxygen, causes decomposition of peroxides and cleavage of chains. The abilities of metal compounds to decompose peroxides, to cleave chains, and to catalyze oxidation differ considerably. On starting with undegraded rubber solution, and either AZBN or one of several metal compounds, the oxygen absorbed for a given reduction of viscosity was nearly constant even though the rates of oxidation varied widely. In two experiments on a rubber solution without metals (where chain cleavages could be determined more accurately), about 48 molecules of oxygen were absorbed and four chains were cleaved per initiating radical. About one cleavage occurred per 14 oxygen molecules absorbed in chain propagation, independent of the rate of chain initiation. This ratio seems to apply fairly generally. Thus chain cleavage is a primary reaction accompanying chain propagation, rather than chain termination, and added metal compounds affect mainly the rates of initiation and termination rather than chain propagation. Cobalt compounds are the most active metal catalysts for oxidation of rubber. Except for a few inactive complexes, differences among cobaltous compounds so far have been small. The cobaltous forms lose some of their activity as they are converted to cobaltic compounds. The latter in turn lose their activity entirely when they form insoluble complexes with highly degraded rubber. Several fractions of these complexes were investigated. The catalytic activity of cobaltic compounds is more affected by solvent and coordinating groups. The ability of both cobaltous and cobaltic forms to react with peroxides is critical in catalytic activity. We have been unable to account satisfactorily for all the oxygen absorbed by our rubber solutions. Part appears as titratable hydroperoxides; part is in alcohol and carbonyl groups; the balance is unaccounted for and possibly is in ether links, cyclic or dialkyl peroxides, or hydroperoxides which we were unable to titrate. Very little of any primary, simple fragmentation product of oxidation was found. Pyrolyses of oxidized rubber gave some limonene, not enough simple oxygenated compounds to tell much about its structure, and no evidence of adjacent cyclic peroxide groups.

The effect of a low‐viscosity swelling liquid on the tensile strength of rubber

AbstractThe paper examines the effect of swelling on a number of different gum rubbers and rubbers filled with different types and concentrations of black. The observed decrease in strength with decreasing rubber fraction Vr (increasing swelling ratio) is, in the case of gum rubbers, associated with a decrease in internal friction. The incorporation of a black filler is shown to increase strength by hydrodynamic stiffening and by an increase in internal friction of the rubber network, and a simple reduction scheme of the data shows a close analogy between the strength as a function of Vr and the dynamic modulus of a rubber solution as a function of concentration. The results lead to a failure criterion, which describes the energy density at break as a simple function of the hysteresis near break.

Heterogeneous Polymer Systems. IV. Mechanism of Rubber Particle Formation in Rubber Modified Vinyl Polymers

Abstract Polymerization of a solution of a rubber in a vinyl monomer consists of two stages. In the first stage (0–40 per cent conversion), in which the system is liquid, a polymeric oil-in-oil emulsion is formed, and the size of the rubber particles is established. In the second stage (40–100 per cent) this polymeric oil-in-oil emulsion hardens gradually to a solid dispersion of rubber particles in a matrix of the vinyl polymer, whereby the structure of the emulsion is retained and no significant morphological changes occur. The rubber particles are formed in the phase inversion which occurs in the first stage of polymerization. After the manuscript of this paper had been completed, a publication appeared, in which the dispersion of rubber by a phase inversion was also described. Bender's observations are in agreement with the observations presented in this paper and in the first paper in this series.) At the phase inversion point, the rubber phase is dispersed in the form of droplets in the vinyl polymer. Formation of multiple emulsions can occur at this point. The droplets of the rubber phase harden gradually by polymerization of the monomer and by crosslinking of the rubber and become finally solid rubber particles. The rubber particles contain irregularly shaped, tiny occlusions of vinyl polymer caused by polymerization of the portion of the monomer which was the solvent in the rubber phase. In addition, the rubber particles can contain larger occlusions with round peripheries stemming from multiple emulsions formed at the phase inversion point. Since the high viscosity of rubber solutions has an impeding effect on phase inversion, agitation is necessary in the first phase of the polymerization in order to overcome the inertia of the system and achieve inversion before the emulsions can solidify in the uninverted state.

Cationic graft copolymerization of styrene onto natural rubber

AbstractThe polymerization of styrene was carried out in a cyclohexane solution of natural rubber with stannic chloride. It was found that the grafting copolymerizations of styrene took place as well as the cyclization of rubber. The rate of polymerization of styrene was proportional to the second power of the concentration of styrene and to the concentrations of stannic chloride and natural rubber, respectively. The overall activation energy was about 6 kcal./mole. The percentage grafting increased with increasing concentration of rubber. On the other hand, the grafting efficiency showed the reverse tendency. The percentage grafting could be increased to 150% by the addition of nitrobenzene, a polar solvent.