Thermodynamic consideration of ice adhesion

The specific work of adhesion W-π_e in the air can be represented by the correct form of the Young-Diipré relation (Dupré 1869; Fox and Zisman 1950) modified by Bangham and Razouk (1937).

where y_i is surface free energy of ice, θ is the contact angle of ice/substrate and π_e is the reduction in surface energy of the solid resulting from adsorption of vapor from liquid being measured.

On the other hand, when the water droplet on a substrate in liquid paraffin cools into ice π_e will be eliminated. Energetic equilibrium condition is represented by

where y_sl y_si - y_ilare interfacial free energy of substrate/paraffin, substrate/ice and ice/paraffin,

respectively. And θ1 is the contact angle of ice/substrate in paraffin. There are well known equations on the work of adhesion W, and interfacial free energy,

where y_s, y_i, y₁ [ and y_ds₁ are surface free energy of substrate, ice, paraffin and dispersion component of ice, respectively. And θ₂, is contact angle of paraffin on a substrate. From the equations 2, 3, 4 and 5 W is expressed by

Using Equation 6, work of adhesion W can be determined by measurement of contact angles θ1 of ice/substrate in paraffin and θ2, of paraffin on a substrate in the air and from surface free energy of ice and paraffin.

Calculation of surface free energy of ice

Fowkes (1964) determined dispersion and hydrogen bond components of water at 20°C 21.8 and 51.0 mJ/m₂, respectively. Surface and interfacial free energy of ice and ice/water at 0°C are determined as 109.0 and 33.0 mJ/m₂ by Hobbs (1974).

On the other hand, the heat of vaporization of water at 0°C is 44.9 kJ/mol and latent heat of freezing 6.0 kJ/mol. These interna! energies must correspond to the surface contribution of 75.6 and 33.0 mJ/m₂, respectively. Dispersion energy can be expressed (Tabor 1978) by the work required to separate the adhered parallel plates infinitely.

where E is dispersion energy, f is attractive force per unit area, ho is distance between molecules, A is Hamaker constant. This energy is equivalent to cohesive energy 2y and h_o will be proportional to one-third power of molar volume. Then y is proportional to two-third power of molar volume V_m. By the use of this relationship dispersion component of water and ice at any temperature can be calculated. Assumed all heat of deicing involved in the contribution from dissociated hydrogen-bond of ice, dispersion and hydrogen bond energy at 0°C will be 20.59 and 88.41 mJ/m₂, respectively. Moreover, vaporization energy at O K is 56.1 kJ/mol. The values at an arbitary temperature can be calculated by interpolation. These relationships are shown in Figure I. On the other hand, surface free energy of liquid paraffin {Witco chemical, Kaydol) was determined by Wilhelmy-Plate method (Klungness 1981) at 20°C and pendant drop method at 20°C and -15°C.

Fig. 1. Dispersion and hydrogen bond components of surface free energy of water and ice.

Materials

Polymeric materials used in this investigation are listed in Table I. Resins No 1 to 13 were coated by solidification from solution on 2 mm thick aluminum plates cut into 70x90 mm for the measurement of shear strength, and on the 10 mm thick stainless steel plates of the same size for the tensile measurement. Plastic plates of No 14 to 22 were cut into test panels in the same size described above and were adhered to 10 mm thick stainless steel plates for the two kinds of measurements.

Apparatus and test methods

• a) For the measurement of contact angle of icing we used a goniometer (Kyowa Kaimenkagaku) consisting essentially of a contact angle meter, TV monitoring system and circulating bath for the temperature regulation. Test pieces were made in the size of 25x8x3 mm. Resinous test pieces are used without treatment, whereas plastic test pieces are cleaned 3 times with distilled deionized water and finally with methanol. Test piece prepared is set in a pyrex-cell (30x20x14 mm). Then contact angles of water and ice formed on the polymeric substrates are measured at 20 C and -15°C in the air and in paraffin, respectively. For the droplet, distilled deionized water is used and its volume is 50μl.

• b) For the measurement of adhesive strength of ice we developed a new programming test apparatus for the measurement of the force of ice adhesion with good accuracy and reproducibility. The apparatus consists essentially of a temperature regulated chamber, in which specimen panels are mounted firmly on a base turn-table, a driving device which generates “pull and push” force connected to a load cell, a process controller and a recorder. Stress cycles, cooling-heating schedule can be programmed freely.

Measurement of shear strength

The metal ring with inside section area 5 cm₂, height 1.5 cm is set on polymer surface of test plates and precooled for 90 minutes at predetermined temperature, then 2 ml of 5 C distilled-deionized water is poured in the ring. After keeping for 3 hours at that temperature shear strength of ice adhesion is measured.

Measurement of tensile strength

The apparatus consists of an attachment of stainless steel with 10 cm₂ cross sectional area. 30μ1 of distilled-deionized water is sandwiched between the specimen and a polymer substrate so as to form an ultra-thin layer (30μτη) of water. The whole apparatus is then refrigerated to predetermined temperature for 3 hours at that temperature. Then tensile strength is measured.

The work of adhesion W- π_e, and W for different polymers can be seen in Figure 2. Figures 3 and 4 show the relationships of theoretical vs. observed ice adhesion by shear method, respectively.

Physical properties and ice adhesion

In order to investigate the susceptibility of physical properties of polymers to adhesive strength of ice visco-elastic behaviour particularly below icing temperature’ on some polymers, using TBA (Tortional Braid Analysis Toray Rigaku) was studied. Further, the temperature dependence of strain in the ice/polymer system, in which ice adhered the polymer surface, was studied with a DSA (Dynamic Strain Amplifier, Kyowa Electronic Institute).

Composition and mechanism for prevention from ice adhesion

Basic studies of mechanism of icing from viewpoints of thermodynamic and physical factors were made. In the course of numerous attempts, it has been found that ice adhesion can be almost completely prevented by the synergetic effect resulting from the combined use of an organopolysiloxane resin and alkali metal compound. The trial product of this coating material is tentatively named IRC. The film made from this composite materials has characteristic surface properties, and shows amphibious nature; hydrophobic and hydrophilic.

Fig. 7. Schematic representation of bound water hydrated on a lithium ion.

The organopolysiloxane resin has a chain of hydrocarbon atoms arranged on its surface and thus is low in surface energy resulting hydrophobicity. This resin contains a small amount of a polar ingredients prone to form hydrogen bonds. This is the reason for the formation of the polymers considerably amenable to icing. Alkali metal compound, especially containing lithium atoms, shows strong hydrophilicity. The lithium ion has a small Pauling radius (0.06 nm) so that the hydration energy is great as 5.23 x 10₂ kJ mol_-1 and acts therefore as a hydrogen bond breaker. It is confirmed by Hiraoka and Yokoyama (1982), that the four oxygen atoms from water molecules and two oxygen atoras contained in a carboxylic residue associate together to form the structure of octahedron coordination. The water molecules thus hydrated on lithium ion are said the bound water or non freezing water. Schematic representation of the structure is shown in Figure 7. Around the bound water, some layers of water molecules so-called the restrained water are arranged, and surrounded by the free water. Each three types of water will behave differently at icing temperature. It is assumed that structural and energetic differences thereof and synergetic effect from silicone matrix result in preventing ice adhesion. DSC analysis of this film showed that the water absorbed in the film up to 8% does not have a definite freezing point, and at the 15% the water showed a broader freezing range, namely 0~-28°C. furthermore, the relaxation times of the equilibrium water absorbed in freezed film at -20 °C were studied by Pulsed NMR. It was clear that the structure of water molecules are in the state “restrained”. The adhesive strength of ice to the film in comparison with other materials of low ice adhesion is shown in Figure 8. Monitoring tests are under way in many fields of application.

Fig. 8. Adhesive strength of ice to IRC in comparison with some low energy polymers (in shear at -15°C).