asymmetric piston seal for standard applications as K01-P, but due to design with active back-up ring suitable for higher pressure range or larger extrusion gaps. PS 02 for short housing.




  • asymmetric single acting piston lipseal, with the dynamic sealing lip beeing shorter and thinner than the static one in order to avoid drag pressure built up.
  • interference fit on the inside diameter.
  • various materials are available for different purposes.
  • snaps into simple grooves (see notes on installation).
  • best sealing effect across a wide temperature range.
  • the active back up ring on the trailing side of the seal reduces extrusion wearand allows larger gap dimensions respectively higher system pressure.
  • sealing effect enhanced by high recovery rate.
  • for pressures up to 700 bar as a seal between pressurised spaces.
  • good sealing in the low pressure range.
  • excellent static and dynamic sealing.
  • suitable for long travel.
  • little inclination to“stick-slip”.
  • low break-awayload after prolonged periods of standstill.



not bolded symbols; please consult our technical for application limitations


category of profile

machined product only


single acting

the PS 02 seal is designed  for use as a piston seal - either single or double acting where two seals are used ‘back to back’.


area of application: hydraulics

  • reciprocating pistons in hydraulic cylinders.
  • piston seal for applications with large extrusion gap and without special impact load.



  • this seal has the correct functioning dimensions only when unmounted condition, the seal may appear too small.
  • the ratio between  nominal width and sealing height cs/H should not drop below a value of 1/1.25 (essentially according to ISO 5597housings for piston and rod seals).
  • recovery  volume  is limited.
  • design K02-PD with triangular back up ring can lead to installation difficulties.



PS 02  profiles are lip seals designed  to seal pressurised space against the atmosphere or - in case of back to back arrangement with intermediate guidering – to seal between two pressurised spaces, mainly for reciprocating movements. the design is based on applica- tion in standard hydraulic systems with conventional hydraulic oils. the operating parameters are as defined in the sealing data sheet and material data. requirements deviating from these parameters can be met to a certain degree by changing the geometry in the software program.


operating parameters & material

sealing element back-up ring temperature max. surface speed max. pressure 1 hydrolysis dry running wear resistance
 PU POM /PA -30 °C ... +100  °C 0,5 m/s 700 bar (70 MPa) - + +
 HPU  POM / PA -20 °C ... +100  °C 0,5 m/s 700 bar (70 MPa) + + +
 SPU  POM / PA -20 °C ... +100  °C 0,7 m/s 700 bar (70 MPa) + + +
 LTPU POM /  PA -50 °C ... +100  °C 0,5 m/s 700 bar (70 MPa) - + +
GPU POM / PA -30 °C ... +100  °C 0,5 m/s 700 bar (70 MPa) + + +

the stated operation conditions represent general indications. it is recommended not to use all maximum  values simultaneously. surface speed limits apply only to the presence of adequate lubrication film.

1 pressure ratings are dependent on the size of the extrusion gap.

2 POM up to ø260 mm, PA above ø260 mm.

note on special material:

as the temperature limits are determined by POM, using special materials for the back up ring can expand the temperature limits.

++ ... particularly suitable                         o ... conditional suitable

+ ... suitable                                         - ... not suitable

for detailed information regarding chemical resistance please refer to our „list of resistance“. for increased chemical and thermal resistance rubber

materials are to be preferred, attention  should be paid to restrictions for pressure range and wear resistance. for higher gliding  speeds another system should be used (e.g. ptfe materials).

note on special material:

as the temperature limits are determined by POM, using special materials for the back up ring can expand the temperature limits.



gap dimension

operating pressure cs = (ØD - Ød)/2 mm
4 5 7.5 10 12.5 15
safe extrusion gap (mm)
200 bar (20 MPa) 0.62 0.75 0.90 1.15 1.35 1.50
400 bar (40 MPa) 0.27 0.36 0.45 0.55 0.65 0.75
600 bar (60 MPa) 0.17 0.19 0.21 0.23 0.25 0.26
700 bar (70 MPa) 0.05 0.07 0.10 0.13 0.15 0.17


important note:

the above data are maximum value and can’t be used at the same time. e.g. the maximum operating speed depend on material type, pressure, tem- perature and gap value. temperature range also dependent on medium.

the table applies to an operating temperature  of 70 °C. use larger cross sections to increase maximum allowed gap dimension.



surface quality

surface roughness

Rtmax (μm)

Ra (μm)

sliding surface ≤2,5 ≤0,1-0,5
bottom of groove ≤6,3 ≤1,6
groove face ≤15 ≤3


tolerance recommendation

seal housing tolerances
Ød h10


mode of installation

for inside diameters of 40mm and more, the seal can generally be slipped over the piston and snapped into closed grooves. due to occuring de- formation force at installation, assembly aid tools are to be used for large cross-sections. the material deformation should not exceed the value of 20%, otherwise the permanent deformation would be too large.


recommended mounting space:

plastic guiderings (wearbands) have to feature a adequate cutting gap (recommendation:  2-5% of D). if metalic guides are used, spiral grooves shall be provided. smaller values for Hmin will ease the installation (reduced elongation and mounting force) but the height of the retaining col- lar has to be sufficient to assure a stable fit in the housing ( larger than cs/2, smaller retaining collars will increase the danger of eversion of the profile in case of occuring drag pressure).

in order to avoid drag pressure built up in case of back-to-back arrangement, the distance between the seals should be as small as possible.


insertion chamfer:

in order to avoid damage to the piston seal during installation, the piston and the housing is to be chamfered  and rounded  as shown in the

“recommended mounting space” drawing. the size of chamfer depends on the seal type and profile width.

cs (mm) c (mm)
α = 15⁰  ... 20⁰ α = 20⁰  ... 30⁰
4 3.5 2
5 4 2.5
6 4.5 3
7.5 5 4
10 6 5
12.5 8.5 6.5
15 10 7.5
20 13 10

instead of a chamfer, the piston can also be designed with a radius. recommended size of the radius is equal to size of chamfer (R=c).


seal & housing recommendations

please note that we are able to produce those profiles to your specific need or any non standard housing. for detail measurements, please see Jet seal pars  catalog...

the ratio between nominal width and seal height cs/H should not drop below 1/1.25. therefore we recommend the following housing heights.

ØD [mm] Ød [mm] L [mm] cs = (ØD - Ød)/2 [mm]
5 ~ 24,9 ØD - 8 6 4
25 ~ 49,9 ØD - 10 7 5
50 ~ 74,9 ØD - 12 8 6
75 ~ 149,9 ØD - 16 10 7.5
150 ~ 299,9 ØD - 20 12 10
300 ~ 500 ØD - 24 18 12.5
500 ~ 750 ØD - 30 20 15
> 750 ØD - 40 26 20


don’t hesitate to contact our technical department for further information or for special requirements (temperature, speed etc.), so that suitable materi- als and/or designs can be recommended.