Pertes de pression

Determining the Pressure Loss of a Hose

When conveying materials pressure-loss is inevitable and must be considered by establishing the required compressor power. Our hoses are flow optimized, exceptionally smooth and the internal bending radius folds in a regular pattern, reducing losses to a minimum. Significantly lowering both the purchase and running costs of the system.

The total pressure-loss consists in the first part of Δp_v, which can be found in the diagrams. A second part Δp_Bogen must be considered and calculated if the hose is installed with bends.

(l = length of the hose, ζ = resistance value see below,
Δ = density e.g. of air is 1,21 kg/m³,
v = velocity of flow):

The resistance value ζ must be calculated for every individual bend:

Example

Pressure-loss of an I.D. 75 mm AIRDUC PUR^® 351 FOOD hose with a velocity flow of 19 m/s (i.e. in the first diagram: Δpv=120 Pa/m). The total length of the system is 12 m with one 90° bend (i.e. φ=90° → k=1) with the minimum bending radius (i.e. Bending Radius + ½ x Ø/ID≈1 → ζ90°=0,51) and a second 180° bend (i.e. φ=180° → k=1,7) constructed with the doubled minimum bending radius (→ ζ90°=0,3):

Average value of Δpv for the following hose types:

• AIRDUC^® 341, 350, 351, 352, 362, 363
• AIRDUC^® 356
• BARDUC^® 381, 382
• NEO 2, SIL 2
• TIMBERDUC^® 533
• NORPLAST^® 379 - 380, 383 - 389

• PROTAPE^® 310, 322, 370, 371
• PROTAPE^® 301, 330, 332
• TIMBERDUC^® 531, 532
• CP 450 - 487
• SuperFlex 372
• EVA 373