Pneumatic Cylinders: Series P5T Short Stroke Thrusters
Pneumatic Cylinders: Series P5T Short Stroke Thrusters
Pneumatic Cylinders: Series P5T Short Stroke Thrusters
Series P5T
Short Stroke Thrusters
Catalogue PDE2557TCUK September 2014
PDE2557TCUK
P5T Short Stroke Thrusters
Speed *** ** **
Weight *** ** **
Important Note
Before attempting any external or internal work
All technical data in this catalogue are typical
on the cylinder or any connected components,
data only.
make sure the cylinder is vented and disconnect
Air quality is essential for maximum cylinder
the air supply in order to ensure isolation of the
service life (see ISO 8573).
air supply.
WARNING
FAILURE OR IMPROPER SELECTION OR IMPROPER USE OF THE PRODUCTS AND/OR SYSTEMS DESCRIBED HEREIN OR RELATED ITEMS CAN CAUSE DEATH, PERSONAL INJURY AND
PROPERTY DAMAGE.
This document and other information from Parker Hannifin Corporation, its subsidiaries and authorized distributors provide product and/or system options for further investigation by users having technical expertise.
It is important that you analyze all aspects of your application and review the information concerning the product or system in the current product catalog. Due to the variety of operating conditions and applications
for these products or systems, the user, through its own analysis and testing, is solely responsible for making the final selection of the products and systems and assuring that all performance, safety and warning
requirements of the application are met. The products described herein, including without limitation, product features, specifications, designs, availability and pricing, are subject to change by Parker Hannifin
Corporation and its subsidiaries at any time without notice.
SALE CONDITIONS
The items described in this document are available for sale by Parker Hannifin Corporation, its subsidiaries or its authorized distributors. Any sale contract entered into by Parker will be governed by the provisions
stated in Parker’s standard terms and conditions of sale (copy available upon request).
Contents Page
Magnetic piston as
standard.
Non-contact sensing
All cylinders are supplied with a magnetic piston as standard,
for non-contact sensing. Electronic type sensors and reed
switches are available. They are supplied with either flying lead
or cable plug connector.
Options
In addition to the standard designs, a number of variants of the
P5T range are available to special order, to provide effective Double acting, connections at rear.
solutions in a large number of applications.
Cylinders with special strokes
Cylinders with two fixing plates
Cylinders with adjustable stops, with cushioning
High-temperature cylinders for the temperature range of -10°C
to +150°C (not magnetic piston).
Double acting with one fixing plate adjustable end stops with
cushioning, connections on side, on top or at rear.
For best possible service life and trouble-free operation, ISO 8573-1 1 0,1 0,1 -70 0,01
quality class 3.4.3 should be used. This means 5 µm filter (standard
filter) dew point +3 ºC for indoor operation (a lower dew point should 2 1 1 -40 0,1
be selected for outdoor operation) and oil concentration 1.0 mg oil/m3, 3 5 5 -20 1,0
which is what a standard compressor with a standard filter gives.
4 15 8 +3 5,0
5 40 10 +7 25
6 - - +10 -
Weights in kg
Cylinder Type of bearing Shaft diam. Standard stroke
diam. mm mm 10 25 40 50 75 100 125 150 175 200
16 Plain bearing 10 0,35 0,43 0,51 0,57 0,70 0,84
Recirculating ball 8 0,32 0,39 0,46 0,51 0,64 0,76
20 Plain bearing 12 0,76 0,86 0,94 1,11 1,29 1,47
Recirculating ball 10 0,70 0,80 0,86 1,03 1,19 1,36
25 Plain bearing 16 1,13 1,39 1,65 1,91 2,17 2,43
Recirculating ball 12 0,98 1,20 1,43 1,65 1,88 2,11
32 Plain bearing 20 1,67 2,07 2,46 2,86 3,26 3,65 4,05 4,45
Recirculating ball 16 1,51 1,86 2,21 2,56 2,91 3,27 3,62 3,97
40 Plain bearing 20 2,00 2,42 2,84 3,26 3,68 4,10 4,52 4,84
Recirculating ball 16 1,82 2,20 2,57 2,95 3,32 3,70 4,08 4,45
50 Plain bearing 25 2,63 3,22 3,81 4,40 4,99 5,59 6,18 6,77
Recirculating ball 20 2,35 2,87 3,39 3,92 4,44 4,96 5,48 6,01
63 Plain bearing 25 3,29 3,98 4,66 5,34 6,02 6,71 7,39 8,07
Recirculating ball 20 2,99 3,60 4,22 4,83 5,45 6,06 6,67 7,29
80 Plain bearing 30 6,06 7,12 8,18 9,24 10,30 11,36 12,42 13,48
Recirculating ball 25 5,66 6,63 7,61 8,58 9,56 10,53 11,51 12,49
100 Plain bearing 35 10,69 12,03 13,37 14,47 16,05 17,39 18,73 20,08
Recirculating ball 30 10,16 11,40 12,64 13,89 15,13 16,37 17,61 18,85
4000
3800
11 –/16 3600
3400
3200
10 –/15 3000
Ø200 2800
–/14 2600
9 2400
2200
–/13 2000
8 1800
Ø160
–/12 1600
7 14/11 1400
1200
3 Ø125
6 12/10
1000
800
Ø100 5
10/8
2 Ø80 4
400
Ø63 8/6
3
200
1 Ø50
Ø40 2 6/4
Ø32 5/3
Ø25
Ø20 1 4/2,7
Ø16
Ø10
1) The “equivalent throttling bore“ is a long throttle (for example a tube) or a series of throttles (for example, through a valve)
converted to a short throttle which gives a corresponding flow rate. This should not be confused with the “orifice“ which is
sometimes specified for valves. The value for the orifice does not normally take account of the fact that the valve contains a
number of throttles.
2) Qn is a measure of the valve flow capacity, with flow measured in litre per minute (l/min) at 6 bar(e) supply pressure and 1 bar
pressure drop across the valve.
Example 1 : Which tube diameter should be used? Valve series with respective flows in Nl/minute
A 50 mm bore cylinder is to be operated at 0.5 m/s. The
Valve series Qn in Nl/Min
tube length between the valve and cylinder is 2 m. In the
diagram we follow the line from 50 mm bore to 0.5 m/s and Valvetronic Solstar 33
get an “equivalent throttling bore“ of approximately 4 mm. Interface PS1 100
We continue out to the right in the chart and intersect the line
Adex A05 173
for a 2 m tube between the curves for 4 mm (6/4 tube) and 6
Moduflex size 1, (2 x 3/2) 220
mm(8/6 tube). This means that a 6/4 tube throttles the velocity
Valvetronic PVL-B 5/3 closed centre, 6 mm push in 290
somewhat, while an 8/6 tube is a little too large. We select the
8/6 tube to obtain full cylinder velocity. Moduflex size 1, (4/2) 320
B43 Manual and mechanical 340
Example 2 : What cylinder velocity will be obtained? Valvetronic PVL-B 2 x 2/3, 6 mm push in 350
A 80 mm bore cylinder will be used, connected by 8 m 12/10 Valvetronic PVL-B 5/3 closed centre, G1/8 370
tube to a P2L-B valve. What cylinder velocity will we get? We Compact Isomax DX02 385
refer to the diagram and follow the line from 8 mm tube length Valvetronic PVL-B 2 x 3/2 G1/8 440
up to the curve for 12/10 tube. From there, we go horizontally Valvetronic PVL-B 5/2, 6 mm push in 450
to the curve for the Ø80 cylinder. We find that the velocity will Valvetronic PVL-B 5/3 vented centre, 6 mm push in 450
be about 0.5 m/s. Moduflex size 2, (2 x 3/2) 450
Flowstar P2V-A 520
Example 3 : What is the minimum inner diameter and
Valvetronic PVL-B 5/3 vented centre, G1/8 540
maximum lenght of tube?
Valvetronic PVL-B 5/2, G1/8 540
For a application a 125 mm bore cylinder will be used.
Valvetronic PVL-C 2 x 3/2, 8 mm push in 540
Maximum velocity of piston rod is 0.5 m/s. The cylinder will be
Adex A12 560
controlled by a P2L-D valve. What diameter of tube can be
Valvetronic PVL-C 2 x 3/2 G1/8 570
used and what is maximum lenght of tube.
We refer to the diagram. We start at the left side of the diagram Compact Isomax DX01 585
cylinder Ø125. We follow the line until the intersection with the VIKING Xtreme P2LAX 660
velocity line of 0.5 m/s. From here we draw a horizontal line in Valvetronic PVL-C 5/3 closed centre, 8 mm push in 700
the diagram. This line shows us we need an equivalent throt- Valvetronic PVL-C 5/3 vented centre, G1/4 700
tling bore of approximately 10 mm. Following this line horizon- B3-Series 780
tally we cross a few intersections. These intersections shows Valvetronic PVL-C 5/3 closed centre, G1/4 780
us the minimum inner diameter (rightside diagram) in combina- Moduflex size 2, (4/2) 800
tion with the maximum length of tube (bottomside diagram). Valvetronic PVL-C 5/2, 8 mm push in 840
Valvetronic PVL-C 5/3 vented centre, 8 mm push in 840
For example:
Valvetronic PVL-C 5/2, G1/4 840
Intersection one: When a tube (14/11) will be used,
the maximum length of tube is 0.7 meter. Flowstar P2V-B 1090
Intersection two: When a tube (—/13) will be used, ISOMAX DX1 1150
the maximum length of tube is 3.7 meter. B53 Manual and mechanical 1160
Intersection three: When a tube (—/14) will be used, B4-Series 1170
the maximum length of tube is 6 meter. VIKING Xtreme P2LBX 1290
B5-Series, G1/4 1440
Example 4 : Determining tube size and cylinder Airline Isolator Valve VE22/23 1470
velocity with a particular cylinder and valve? ISOMAX DX2 2330
For an application using a 40 mm bore cylinder with a valve VIKING Xtreme P2LCX, G3/8 2460
with Qn=800 Nl/min. The distance between the cylinder and VIKING Xtreme P2LDX, G1/2 2660
valve has been set to 5 m.
Tube dimension: What tube bore should be selected to obtain ISOMAX DX3 4050
the maximum cylinder velocity? Start at pipe length 5 m, follow Airline Isolator Valve VE42/43 5520
the line up to the intersection with 800 Nl/min. Select the next Airline Isolator Valve VE82/83 13680
largest tube diameter, in this case Ø10/8 mm.
Cylinder velocity: What maximum cylinder velocity will be
obtained? Follow the line for 800 Nl/min to the left until it inter-
sects with the line for the Ø40 mm cylinder. In this example, the
speed is just above 1.1 m/s.
R C
GG
+0,025
2 x ∅V –0,000
J depth W A+stroke
LL M+stroke
+0,025
2 x ∅V –0,000
J/2 (M+stroke)/2 depth W
EE
GG
4 x AA HH
depth CC
2xF
MM
KK DD Z B P S U
NN H
2 x FF
∅D
groove for
sensor N T/2
EE 4 x AA
depth BB 4 x AA
K
PP T
G E
2xF
+0,025
2 x ∅V –0,000
Note!
depth W The P5T cylinder with bore 16 mm has only one groove for sensors.
When 2 sensors are used for stroke 25 mm or shorter, sensors with 90
degree cable outlet has to be used, see page 23.
Cylinder Stroke L
diam mm mm mm L + Stroke
16 10 36,2
25, 40, 50, 75 60,2
100 75,2
20 25, 40, 50, 75 66,9
100, 125 91,9
25 25, 50, 75, 100 69,9
125, 150 91,9
32 25, 50, 75, 100 77,9
125, 150, 175, 200 116,0
40 25, 50, 75, 100 77,9
125, 150, 175, 200 116,0
50 25, 50, 75, 100 84,0
125, 150, 175, 200 124,1
63 25, 50, 75, 100 84,0
125, 150, 175, 200 124,1
80 25, 50, 75, 100 101,8
125, 150, 175, 200 140,0
100 25 122,8
50, 75, 100 120,3
125, 150, 175, 200 158,4
XX
RR
Maximum load
d
P5T cylinders can absorb the same load, irrespective of how it
is installed. The loading diagram is based on a service life for
the cylinder of at least 10 million cycles. At higher loadings, the
service life will be reduced.
Example d
Estimate the load limit for a P5T-16 with plain bearing and
stroke + d = 75 mm has load capacity 50 N.
d
200 250
150 Plain bearing
Plain bearing 200
Plain bearing 150 Ball bearing
100 Ball bearing 150
Ball bearing 100
100
50
50
50
0 0 0
0 50 100 150 200 0 50 100 150 200 0 50 100 150 200
Stroke + d [mm] Stroke + d [mm] Stroke + d [mm]
Cylinder bore 32 mm Cylinder bore 40 mm Cylinder bore 50 mm
Load [N] Load [N] Load [N]
400 400 500
100 100
100
0 0 0
0 50 100 150 200 0 50 100 150 200 0 50 100 150 200
Stroke + d [mm] Stroke + d [mm] Stroke + d [mm]
Cylinder bore 63 mm Cylinder bore 80 mm Cylinder bore 100 mm
Load [N] Load [N] Load [N]
500 1000 1500
Plain bearing Plain bearing Plain bearing
400 800 1200
Ball bearing Ball bearing Ball bearing
300 600 900
0 0 0
0 50 100 150 200 0 50 100 150 200 0 50 100 150 200
Stroke + d [mm] Stroke + d [mm] Stroke + d [mm]
Example:
A wrist rotate mechanism symmetrically grabs and rotates a
part. The mechanism exerts a 20 Nm torque on a P5T-50 with
25mm stroke. The center of gravity for the wrist rotate mecha-
nism is 25mm from the face of the P5T-50.
The "stroke + d" dimension equals 50mm (25 + 25). The
P5T-50 with plain bearing will have adequate torsional capacity
(22.5 Nm).
0 0 0
0 50 100 150 200 0 50 100 150 200 0 50 100 150 200
Stroke + d [mm] Stroke + d [mm] Stroke + d [mm]
Cylinder bore 32 mm Cylinder bore 40 mm Cylinder bore 50 mm
Torque [Nm] Torque [Nm] Torque [Nm]
16 20 25
4 5
5
0 0 0
0 50 100 150 200 0 50 100 150 200 0 50 100 150 200
Stroke + d [mm] Stroke + d [mm] Stroke + d [mm]
Cylinder bore 63 mm Cylinder bore 80 mm Cylinder bore 100 mm
Torque [Nm] Torque [Nm] Torque [Nm]
30 80 150
Plain bearing
25 120
Plain bearing 60 Plain bearing
20
Ball bearing 90
Ball bearing
15 40 Ball bearing
60
10
20
30
5
0 0 0
0 50 100 150 200 0 50 100 150 200 0 50 100 150 200
Stroke + d [mm] Stroke + d [mm] Stroke + d [mm]
Example:
A mechanism exerts an asymmetrical load of 15 Nm on a
P5T-50 with 30 mm stroke. The centre of acymetric torque
d = 20 mm. Stroke + d (30+20) = 50 mm.
The P5T-50 with plain bearing will have adequate torsional
capacity (21 Nm).
Plain bearing 8
3
4
Plain bearing
Plain bearing
6
2 Ball bearing Ball bearing
Ball bearing 4
2
1
2
0 0 0
0 50 100 150 200 0 50 100 150 200 0 50 100 150 200
Stroke + d [mm] Stroke + d [mm] Stroke + d [mm]
Cylinder bore 32 mm Cylinder bore 40 mm Cylinder bore 50 mm
Torque [Nm] Torque [Nm] Torque [Nm]
16 20 25
Plain bearing
20
12 15
Plain bearing
Ball bearing Plain bearing 15
8 10 Ball bearing
Ball bearing 10
4 5
5
0 0 0
0 50 100 150 200 0 50 100 150 200 0 50 100 150 200
Stroke + d [mm] Stroke + d [mm] Stroke + d [mm]
Cylinder bore 63 mm Cylinder bore 80 mm Cylinder bore 100 mm
Torque [Nm] Torque [Nm] Torque [Nm]
30 80 150
25 120
60 Plain bearing
20 Plain bearing
Plain bearing 90
15 40 Ball bearing
Ball bearing Ball bearing 60
10
20
30
5
0 0 0
0 50 100 150 200 0 50 100 150 200 0 50 100 150 200
Stroke + d [mm] Stroke + d [mm] Stroke + d [mm]
0 0 0
0 50 100 150 200 0 50 100 150 200 0 50 100 150 200
Eccentricity (y) [mm] Eccentricity (y) [mm] Eccentricity (y) [mm]
Cylinder bore 32 mm Cylinder bore 40 mm Cylinder bore 50 mm
Load [N] Load [N] Load [N]
400 400 500
400
300 300
300
200 200
200
Plain bearing Plain bearing
Plain bearing
100 100
100
Ball bearing Ball bearing Ball bearing
0 0 0
0 50 100 150 200 0 50 100 150 200 0 50 100 150 200
Eccentricity (y) [mm] Eccentricity (y) [mm] Eccentricity (y) [mm]
Cylinder bore 63 mm Cylinder bore 80 mm Cylinder bore 100 mm
Load [N] Load [N] Load [N]
500 1000 1600
400 800
1200
300 600
Plain bearing 800
200 400 Plain bearing
Plain bearing Ball bearing
400
100 200
Ball bearing Ball bearing
0 0 0
0 50 100 150 200 0 50 100 150 200 0 50 100 150 200
Eccentricity (y) [mm] Eccentricity (y) [mm] Eccentricity (y) [mm]
Example:
A P5T-50 unit with a stroke up to 50 mm will stop an object
moving at 0.5 m/s that weighs up to 50 kg.
20
30 60
15
20 40
10
10 20
5
0 0 0
0 0,1 0,2 0,3 0,4 0,5 0,6 0 0,1 0,2 0,3 0,4 0,5 0,6 0 0,1 0,2 0,3 0,4 0,5 0,6
Load speed (v) [m/s] Load speed (v) [m/s] Load speed (v) [m/s]
Cylinder bore 32 mm Cylinder bore 40 mm Cylinder bore 50 mm
Mass [kg] Mass [kg] Mass [kg]
200 200 400
50 50 100
0 0 0
0 0,1 0,2 0,3 0,4 0,5 0,6 0 0,1 0,2 0,3 0,4 0,5 0,6 0 0,1 0,2 0,3 0,4 0,5 0,6
Load speed (v) [m/s] Load speed (v) [m/s] Load speed (v) [m/s]
Cylinder bore 63 mm Cylinder bore 80 mm Cylinder bore 100 mm
Mass [kg] Mass [kg] Mass [kg]
400 600 1000
500 800
300
400
600
200 300
400
200
100
200
100
0 0 0
0 0,1 0,2 0,3 0,4 0,5 0,6 0 0,1 0,2 0,3 0,4 0,5 0,6 0 0,1 0,2 0,3 0,4 0,5 0,6
Load speed (v) [m/s] Load speed (v) [m/s] Load speed (v) [m/s]
Ordering key
P 5 T - C 0 3 2 D G S N 100
* Please note that the load capacity increases for the versions with two fixing plates, due to greater bearing distance.
Standard strokes
Order no. Cylinder diam. Standard stroke (mm)
XXX = Stroke (mm) 10 25 40 50 75 100 125 150 175 200
Double acting
P5T- • 016•G••XXX 16
P5T- • 020•G••XXX 20
P5T- • 025•G••XXX 25
P5T- • 032•G••XXX 32
P5T- • 040•G••XXX 40
P5T- • 050•G••XXX 50
P5T- • 063•G••XXX 63
P5T- • 080•G••XXX 80
P5T- • 100•G••XXX 100
For cylinders with special stroke lengths, use the next longest
standard stroke length with adjustable stop, option E.
Cyl. bore Stroke Order code Cyl. bore Stroke Order code
mm mm mm mm
16 10 P5T-C016DGSN010 50 25 P5T-C050DGSN025
M5 thread 25 P5T-C016DGSN025 G1/4 thread 50 P5T-C050DGSN050
40 P5T-C016DGSN040 75 P5T-C050DGSN075
50 P5T-C016DGSN050 100 P5T-C050DGSN100
75 P5T-C016DGSN075 125 P5T-C050DGSN125
100 P5T-C016DGSN100 150 P5T-C050DGSN150
175 P5T-C050DGSN175
20 25 P5T-C020DGSN025
200 P5T-C050DGSN200
G1/8 thread 40 P5T-C020DGSN040
50 P5T-C020DGSN050 63 25 P5T-C063DGSN025
75 P5T-C020DGSN075 G1/4 thread 50 P5T-C063DGSN050
100 P5T-C020DGSN100 75 P5T-C063DGSN075
125 P5T-C020DGSN125 100 P5T-C063DGSN100
125 P5T-C063DGSN125
25 25 P5T-C025DGSN025
150 P5T-C063DGSN150
G1/8 thread 50 P5T-C025DGSN050
175 P5T-C063DGSN175
75 P5T-C025DGSN075
200 P5T-C063DGSN200
100 P5T-C025DGSN100
125 P5T-C025DGSN125 80 25 P5T-C080DGSN025
150 P5T-C025DGSN150 G3/8 thread 50 P5T-C080DGSN050
75 P5T-C080DGSN075
32 25 P5T-C032DGSN025
100 P5T-C080DGSN100
G1/8 thread 50 P5T-C032DGSN050
125 P5T-C080DGSN125
75 P5T-C032DGSN075
150 P5T-C080DGSN150
100 P5T-C032DGSN100
175 P5T-C080DGSN175
125 P5T-C032DGSN125
200 P5T-C080DGSN200
150 P5T-C032DGSN150
175 P5T-C032DGSN175 100 25 P5T-C100DGSN025
200 P5T-C032DGSN200 G3/8 thread 50 P5T-C100DGSN050
75 P5T-C100DGSN075
40 25 P5T-C040DGSN025
100 P5T-C100DGSN100
G1/8 thread 50 P5T-C040DGSN050
125 P5T-C100DGSN125
75 P5T-C040DGSN075
150 P5T-C100DGSN150
100 P5T-C040DGSN100
175 P5T-C100DGSN175
125 P5T-C040DGSN125
200 P5T-C100DGSN200
150 P5T-C040DGSN150
175 P5T-C040DGSN175
200 P5T-C040DGSN200
Note!
The P5T cylinder with bore 16 mm has only one groove for sensors.
When 2 sensors are used for stroke 25 mm or shorter, sensors with 90
degree cable outlet has to be used, see page 23.
Drop-in sensors
The P1D sensors can easily be installed from the side in the
sensor groove, at any position along the piston stroke.
The sensors are completely recessed and thus mechanically
protected. Choose between electronic or reed sensors and
several cable lengths and 8 mm and M12 connectors.
The same standard sensors are used for all P1D versions.
AC/ DC
Brown Brown
Black Black
Blue Blue
P8S-GCFPX
Brown
Blue
P8S-GRFLX / P8S-GRFLX2
Brown
Blue
LED Torque
0,20 ±0,05Nm
Ordering data
Output/function Cable/connector Weight Order code
kg
Electronic sensors , 10-30 V DC
PNP type, normally open 0,27 m PUR-cable and 8 mm snap-in male connector 0,007 P8S-GPSHX
PNP type, normally open 0,27 m PUR-cable and M12 screw male connector 0,015 P8S-GPMHX
PNP type, normally open 3 m PVC-cable without connector 0,030 P8S-GPFLX
PNP type, normally open 10 m PVC-cable without connector 0,110 P8S-GPFTX
Reed sensors , 10-30 V AC/DC
Normally open 0,27 m PUR-cable and 8 mm snap-in male connector 0,007 P8S-GSSHX
Normally open 0,27 m PUR-cable and M12 screw male connector 0,015 P8S-GSMHX
Normally open 3 m PVC-cable without connector 0,030 P8S-GSFLX
Normally open 10 m PVC-cable without connector 0,110 P8S-GSFTX
Normally closed 5m PVC-cable without connector 2) 0,050 P8S-GCFPX
Reed sensors, 10-120 V AC/DC
Normally open 3 m PVC-cable without connector 0,030 P8S-GRFLX
Reed sensorer, 24-230 V AC/DC
Normally open 3 m PVC-cable without connector 0,030 P8S-GRFLX2
2) Without LED
Dimensions (mm)
12
9
20
P8S-SRTHXD
6,7
Brown
Brown
Blue
Blue Black
Not used/Black
Blue
2
Brown
3 1
–/Blue +/Brown
Black
Signal/Black
3 1
–/Blue +/Brown
Seal kits
Cylinder Standard temperature High temperature
diam. mm Nitrile rubber Fluorocarbon rubber
16 PSK-P5T16 PSK-P5T16F
20 PSK-P5T20 PSK-P5T20F
25 PSK-P5T25 PSK-P5T25F
32 PSK-P5T32 PSK-P5T32F
40 PSK-P5T40 PSK-P5T40F
50 PSK-P5T50 PSK-P5T50F
63 PSK-P5T63 PSK-P5T63F
80 PSK-P5T80 PSK-P5T80F
100 PSK-P5T100 PSK-P5T100F
Grease
Weight Standard temperature High temperature
30 g 9127394541 9127394521
© 2014 Parker Hannifin Corporation. All rights reserved. Catalogue PDE2557TCUK - V4 - September 2014