USA

USA Hydraulics

We offer you the design and manufacturing of a standard range of high accuracy rotary Flow Dividers which contain ground gears and lapped finishes with emphasis on accurate division and high pressure rating.

Special applications for example, Stainless Steel Flow dividers, can be manufactured for highly corrosive environments.

Small quantities and specific designs can be accomodated.

For assistance, advise or to place an order please speak with our sales team on 704-900-8167

 

Applications

Flow dividers have a number of usages, which are usually either turning, lifting or clamping.

When used with hydraulic cylinders examples include:

  1. Lifting platforms

Waste compactors

Hydraulic press/stamping

Railway track laying

Agricultural machinery

Pipe/drill clamping (oil industry)

Split level trailers/car transporters

They can also be used with hydraulic motors, examples include:

Conveyers and distribution rollers in many industries.

Flow dividers are also used on tunnelling equipment for various hydraulic operations, and also to feed lubrication to the cutting head.

Selecting a flow divider

Although speed of rotation can be as low as 750 rpm and the maximum is 3000 rpm, a flow divider should be selected which will pass the required flows in the range 1000 to 2000 rpm for maximum efficiency.

Equal flow divider - Having decided on the separate flow ratio the sum of which will give total input flow, refer to the table "Equal Element Units" to select a divider which will pass these flow rates at or near to 1500 rpm. If the flow is variable, calculate speed of rotation which will occur at both maximum and minimum input and ensure that these speeds fall within 750 to 3000 rpm.

Unequal flow dividers - Refer to the table of individual elements to select those which will pass the desired flows at or near to 1500 rpm, bearing in mind that all the elements in a flow divider rotate at the same speed. Thus having calculated the speed of one of the elements according to its flow rate, select the other elements to provide their required flows at that speed. If this proves impractical repeat the process, starting with another of the required outputs. It is not always possible to obtain precisely all the required outputs as this would call for an infinite number of element sizes so some compromise is often required. However, in practical terms, any combination of outputs from 1.5 lpm up to a total input of 27 lpm per section (for FDR) and from 9 lpm up to a total input of 90 lpm per section (for FDL) can be provided for.

Ordering Code Example
For an unequal Flow Divider: FDR 4/2.4.4.9
This is a 4 section unit with; one 2cc section, two 4cc sections and one 9cc section.
Total Input flow @ 1500 rpm—25.5 litre/min. which gives four Output Flows of 3, 6, 6 & 13.5 lpm.

Calculation of Inlet Pressure
The product of inlet pressure and flow is equal to the sum of the products of outlet pressures and flows plus the pressure required to cause the flow divider to rotate.

i.e. PQ = P1Q1 + P2Q2 + P3Q3 + PR
when
P= inlet pressure
Q = inlet flow
P1,P2,P3 etc. are outlet pressures
Q1,Q2,Q3 etc. are the respective outlet flows 

PR is the pressure required to rotate the flow divider Tests have shown that PR varies slightly according to the size and number of elements, but for practical purposes it can be assumed to be 5 bar (72.5psi) for standard ISO VG32 hydraulic fluid at 40ºC 
Thus if the 4 element unit shown as a coding example here have output pressure of 60,120,25 and 50 bar respectively the inlet pressure would be:

60x3 + 120x6 + 25x6 + 50x13.5 + 5 = 65.5 bar
28.5 

The same formula can be used for imperial units provided these are used throughout the calculation. For more information see pressure drop graphs.

Slip Losses - Because there must be some clearance for the gears to rotate some internal leakage is inevitable and this causes some inaccuracy in flow division. The amount of "slip" is a function of flow and pressure drop through each section and is affected by viscosity.

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