Hydraulic Hose Sizing: Difference between revisions
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The 28 hp Briggs & Stratton engine HP is rated at 3600 RPM. With 97% pump efficiency, pump displacement is: | The 28 hp Briggs & Stratton engine HP is rated at 3600 RPM. With 97% pump efficiency, pump displacement is: | ||
:CIPR = 16 × 231 * 0.97 / | :CIPR = 16 × 231 * 0.97 / 3200 = 1.12 in³ / Rev | ||
The 28 hp Renault engine HP is rated at 3000 RPM. With 97% pump efficiency, pump displacement is: | |||
:CIPR = 16 × 231 * 0.97 / 3000 = 1.19 in³ / Rev | |||
Revision as of 01:30, 10 April 2013
Horsepower to Flow
First of all, we must determine fluid flow rate from the horsepower and pressure.
Horsepower = Pressure × Flow / 1714, or:
- HP = PQ / 1714
- Q = (HP * 1714) / P
Determine the flow rate of a 28 HP power unit delivering 3000 PSI:
- 28 = (3000 * Q) / 1714
- Q = (28 * 1714) / 3000 = 15.997 GPM
Determine the flow rate of a 50 HP power unit delivering 3000 PSI:
- 50 = (3000 * Q) / 1714
- Q = (50 * 1714) / 3000 = 28.5 GPM
Hose Sizing
These are the formulas and guidelines for determining sizes for the three hose types: Pressure, Return and Suction. They are determined from the fluid velocity in each type of hose. There are two sets of recognized values used are:
SAE Values
- Pressure: 15 ft/sec
- Return: 10 ft/sec
- Suction: 4 ft/sec
NFP Association Values
- Pressure: 20 ft/sec
- Return: 15 ft/sec
- Suction: 5 ft/sec
The more conservative SAE values are gaining acceptance in hydraulic designers. The formula for calculating the hose size is as follows:
- V = Q / (3.117 * pi/4 * D ^ 2)
or
- D = (Q / (3.117 * pi/4 * V) ) ^ 1/2
Where:
- V is fluid velocity in ft/sec
- Q is fluid volume in gallons/min
- D is hose inside diameter in inches
Note: The sizing guidelines say to always round up.
Now, let's calculate the hose sizes:
Supply (Pressure) Hose
V = 20 ft/sec and Q is shown for 13, 16, and 28.5 GPM:
- D = (13 GPM / (3.117 * pi/4 * 15 ft/sec) ) ^ 1/2 = 0.595 in
- D = (16 GPM / (3.117 * pi/4 * 15 ft/sec) ) ^ 1/2 = 0.660 880
- D = (28.5 GPM / (3.117 * pi/4 * 15 ft/sec) ) ^ 1/2 = 0.762 in
Return Hose
V = 15 ft/sec and Q is shown for 13, 16, and 28.5 GPM:
- D = (13 GPM / (3.117 * pi/4 * 10 ft/sec) ) ^ 1/2 = 0.728 in
- D = (16 GPM / (3.117 * pi/4 * 10 ft/sec) ) ^ 1/2 = 0.808 in
- D = (28.5 GPM / (3.117 * pi/4 * 10 ft/sec) ) ^ 1/2 = 1.07 in
Suction Hose
V = 5 ft / sec and the Q is shown for 13, 16 and 28.5 GPM:
- D = (13 GPM / (3.117 * pi/4 * 4 ft/sec) ) ^ 1/2 = 1.15 in
- D = (16 GPM / (3.117 * pi/4 * 4 ft/sec) ) ^ 1/2 = 1.28 in
- D = (28.5 GPM / (3.117 * pi/4 * 4 ft/sec) ) ^ 1/2 = 1.70 in
Pump Displacement (Cubic Inch Per Revolution, or CIPR)
Calculate the displacement for a fixed displacement as follows:
- CIPR = Flow Rate (in GPM) × 231 x Pump Efficiency / Pump RPM, or:
- CIPR = GPM × 231 * PE / RPM
Note: The generally accepted value for pump efficiency is 97%.
The 28 hp Briggs & Stratton engine HP is rated at 3600 RPM. With 97% pump efficiency, pump displacement is:
- CIPR = 16 × 231 * 0.97 / 3200 = 1.12 in³ / Rev
The 28 hp Renault engine HP is rated at 3000 RPM. With 97% pump efficiency, pump displacement is:
- CIPR = 16 × 231 * 0.97 / 3000 = 1.19 in³ / Rev
The 50 hp Briggs & Stratton engine HP is rated at 3000 RPM. With 97% pump efficiency, pump displacement is:
- CIPR = 28.5 × 231 * 0.97 / 3000 = 2.12 in³ / Rev