Hydraulic Fluid Power. Andrea Vacca

Hydraulic Fluid Power - Andrea Vacca


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      Assuming uniform flow at both inlet and outlet sections,

      (3.45)double-integral Underscript upper C upper S Endscripts ModifyingAbove v With right-arrow rho ModifyingAbove v With right-arrow dot d ModifyingAbove upper A With right-arrow equals rho left-parenthesis StartFraction upper Q Over normal upper Omega EndFraction right-parenthesis left-parenthesis StartFraction upper Q Over normal upper Omega EndFraction right-parenthesis normal upper Omega cosine theta ModifyingAbove i With Ì‚ plus left-bracket rho StartFraction upper Q squared Over upper A 1 EndFraction plus rho StartFraction upper Q squared Over normal upper Omega EndFraction sine theta right-bracket ModifyingAbove j With Ì‚

      where ModifyingAbove i With Ì‚ and ModifyingAbove j With Ì‚ are the unit vectors, respectively, along the horizontal and vertical directions. For a rigorous application of the momentum Eq. (3.43), the CV extends outward from the spool exit section A2, until the vena contraction, Ω. This section is defined when the flow is mono‐dimensional (1D), which means parallel velocity streamlines. Only at Ω the uniform flow assumption is valid to describe the flow exiting the CV.

      The flow force Ffl can be seen as the reaction force of the above Fx, which is the force that the fluid exerts to the bounding surfaces of the CV.

      The flow force presents both a stationary component and a transient component. The stationary component corresponds to a given position of the spool or the poppet of the valve and a constant flow rate. The transient component relates to variations of the spool (or poppet) position, as well as flow variations. In typical problems, the transient component is neglected.

      The first term refers to transient conditions, and it can be neglected when studying a stationary condition. Therefore, when studying hydraulic control valves, the second term, is normally the most important one.

      (3.49)upper F Subscript italic f l comma steady Baseline equals minus rho StartFraction upper Q squared Over normal upper Omega EndFraction cosine theta

      According to Eq. (3.48), the amount of the flow force is linked to the flow rate with a quadratic relation, meaning that flow forces can become severe at high flow rates. Additionally, the flow force depends on the exit angle θ of the flow, often referred as flow jet angle, which is usually a quantity difficult to estimate. Luckily, multiple studies on the flow jet angle for different valve geometries are available in the literature, with Merritt's textbook being a meaningful example [32]. According to this source, the angle to be used for geometries such as the one in Figure 3.17 is 69°. This value, however, can be slightly affected by the amount of opening and by the clearance between the spool and the valve body.

      Example 3.3 Flow force evaluation for two different valve designs

      Two different poppet valve designs implement the same flow path. The two valve designs are shown in the figures below. The Case A uses a large diameter to guide the sliding element when compared to Case B.

"Schematic illustration of the two different poppet valve designs case A and case B implementing the same flow path. The Case A uses a large diameter to guide the sliding element when compared to Case B."

      Determine an expression for the flow force acting on the valve poppet respectively for Case A and Case B. Assume that the valve poppet angle θ perfectly guides the flow at the valve exist section Ω.

       Given:

      Poppet valve geometry for two cases (figures above): flow rate Q; exit area Ω; jet force angle θ; and valve pressure drop Δp = p1p2


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