Hydraulic Fluid Power. Andrea Vacca

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No toxicity 700 Water‐in‐oil 915–940 High Fairly good Excellent Good 0–50 Low 200 Water glycol 1060 High Fairly good Excellent Good 0–50 Low 400 Chlorinated hydrocarbons 1430 Low Good Good Fairly good −5 to 70 High 700 Phosphoric esters 1270 Low Excellent Good Fairly good −5 to 70 High 500 Mixture of esters and chlorides 1150 Low Excellent Good Fairly good −5 to 70 High 600 Silicones 930–1030 High Fairly good Excellent Fairly good −5 to 90 Low <700

      ^a Refers to biodegradable fluids.

2.3 Physical Properties of Hydraulic Fluids

      Properties of hydraulic fluids, such as density or viscosity, are usually tabulated (or expressed by analytical formulas) as functions of pressure and temperature. In order to justify the choice of pressure and temperature as independent variables, the Gibbs' phase law of thermodynamics should be considered:

(2.1)

      The Gibbs' rule defines the number of degrees of freedom, f, necessary to describe the state of a substance in thermodynamic equilibrium. The formula uses the number of components of the substance (n) and the number of phases in equilibrium (κ). The number of degrees of freedom is the number of independent intensive variables that can be varied simultaneously and arbitrarily without determining one another. An intensive variable does not depend on the size of the considered system. For the case of a hydraulic oil, specific volume, density, pressure, temperature, and viscosity are examples of intensive variables.

If we consider the hydraulic fluid as a single component matter (i.e. a pure chemical) even if it is usually a mixture of different components, then from Eq. (2.1), for a single‐component system (n = 1) in the liquid phase (κ = 1), the number of degrees of freedom f is equal to two. This means that two intensive variables can be arbitrarily selected to completely determine the status of the fluid. Among all possible choices, choosing pressure and temperature is particularly convenient because:

       pressure and temperature are relatively easy to measure, with respect to other intensive properties of the fluid; and

       an engineer has a better ability or practical intuition to relate pressure and temperature to practical problems.

      Two intensive variables fully define the status of a liquid. In hydraulic, pressure and temperature are the typical choice for the independent variables used to express the functional between fluid properties.

2.4 Fluid Compressibility: Bulk Modulus

      From the consideration made in the previous paragraphs, the functional dependence of the volume occupied by a certain amount of hydraulic fluid has the following form:

      (2.2)

      The dependence of the volume on the variations of both pressure and temperature can be expressed made with a simple linear equation by considering the first‐order Taylor series expansion:

      (2.3)

In other terms, the deviations from the initial volume V₀ (at the reference conditions p₀, T₀) can be expressed in a linear form by defining the coefficients:

(2.4)

(2.5)

      So

      (2.6)

      The parameter B is known as isothermal bulk modulus of the fluid, and it indicates the tendency of the fluid volume to vary under changes in pressure.

The negative sign in the definition of Eq. (2.4) implies an inverse type relationship, meaning that an increase of pressure causes a reduction in the fluid volume.

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