Molded plastic cylinder for energy absorbers, fluid cylinders, and the like

A molded plastic cylinder for an energy absorber, fluid cylinder, or the like, which includes a main body portion having a first outer diameter and a first thickness, and an end portion formed integrally with the main body portion and having a second outer diameter which is less than the first diameter and also having a second thickness which is not substantially greater than the first thickness, an internal shoulder located substantially at the junction of the main body portion and the end portion, and an external thread on said main body portion in a low stressed area of said cylinder for attaching said cylinder to an external structure.

BACKGROUND OF THE INVENTION 
The present invention relates to a molded plastic cylinder construction 
which may be used for energy absorbers, fluid cylinders, and the like, 
such as liquid springs, liquid shock absorbers, air cylinders and 
hydraulic cylinders. 
By way of background, plastic cylinders can be used for liquid springs, 
liquid shock absorbers, air cylinders and hydraulic cylinders. However, 
molding of such cylinders is difficult when there are sections of 
substantially different thickness, as there is a tendency for voids to 
form in the thicker portions. It is also difficult to mount plastic 
cylinders on external structure because the relatively low structural 
strength of plastic, as compared with metal, precludes the use of 
conventional attachment arrangements heretofore used with metal cylinders. 
It is with overcoming the foregoing deficiencies of prior plastic 
cylinders that the present invention is concerned. 
SUMMARY OF THE INVENTION 
It is accordingly one object of the present invention to provide a molded 
plastic cylinder construction which can be used for liquid springs, shock 
absorbers, air cylinders and hydraulic cylinders, and which can be 
produced at a low cost. 
Another object of the present invention is to provide a molded plastic 
cylinder which is fabricated by laying the outer wall in the form of a 
helical plastic ribbon to thereby provide maximum hoop stress. 
A further object of the present invention is to provide an improved molded 
plastic cylinder in which the various parts are proportioned so that the 
tendency for the formation of voids in the thicker portions is obviated. 
A still further object of the present invention is to provide an improved 
molded plastic cylinder in which the proportioning of the wall 
automatically results in the fabrication of an internal shoulder. 
Another object of the present invention is to employ a helical thread on 
the external surface of a plastic cylinder for transmitting structural 
loads to said plastic cylinder having a capacity for comparatively low 
stresses, said helical thread having the quality of not substantially 
detracting from the hoop stress resistance of the plastic cylinder. Other 
objects and attendant advantages will be more fully perceived hereafter. 
The present invention relates to a molded plastic body for an energy 
absorber, fluid cylinder, or the like, comprising a main body portion 
having a first outer diameter and a first thickness, and an end portion 
formed integrally with said main body portion and having a second outer 
diameter which is less than said first diameter and also having a second 
thickness which is not substantially greater than said first thickness 
such as to avoid formation of voids in said second thickness, and an 
internal shoulder located substantially at the junction of said main body 
portion and said end portion. The various aspects of the present invention 
will be more fully understood when the following portions of the 
specification are read in conjunction with the accompanying drawings 
wherein:

DESCRIPTION OF THE PREFERRED EMBODIMENTS 
The fluid cylinder 10 of the present invention includes a molded plastic 
cylinder 11 having a main body portion 12 joined to an end body portion 13 
of lesser outer diameter by a neck portion 14. The portion 15 of end 
portion 13 has a thickness which is substantially equal to the thickness 
of main body portion 12, and preferably not substantially greater than the 
thickness of the main body portion 12, but it may be of lesser thickness. 
The criterion for the relative thicknesses of portions 15 and 12 is that 
portion 15 should not be so thick as to cause the formation of voids in 
the thicker portion. End portion 13 has an integral end cap 16 in which a 
bore 17 is formed, the peripheral portion 19 of end cap 16 surrounding 
bore 17 forming an integral seal for piston rod 20. An end wall 21 is 
suitably affixed within main body portion 12 as by sonic welding or 
cementing. 
During the process of assembly of fluid cylinder 10, piston rod 20 is 
inserted through bore 17 from left to right in FIG. 1 before end wall 21 
is installed. At that time piston rod 20 already mounts a piston head 22 
having an O-ring seal 18 mounted in a groove therein. Thereafter, cap 23 
is pressed onto the end of the piston rod 20. Spring 24 is then inserted 
into main body portion 12, and thereafter end wall 21 is secured to main 
body portion 12, as by cementing or sonic welding. As can be seen from 
FIG. 1, piston head 22 is biased against annular shoulder 25 by spring 24. 
This shoulder is formed during the molding process. Fluid cylinder 10 may 
be of the type wherein spring 24 biases end cap 23 against a part to be 
held. When pressurized fluid is forced into chamber 26 through port 27 in 
neck portion 14, piston 20 moves to the left to release the part held by 
end cap 23. A vent 29 is provided in end wall 21 to vent chamber 30. When 
the fluid pressure is released from chamber 26, spring 24 will expand to 
return piston head 22 to the position shown in FIG. 1. 
The fluid cylinder 10 of FIG. 1, with modification, can become a 
double-acting fluid actuator. All that is necessary is to eliminate spring 
24 and use port 29 to admit pressurized fluid. When cylinder 10 is 
modified to be double-acting, when port 27 or 29 is used to admit 
pressurized fluid, the other port will be utilized as a vent. Furthermore, 
when piston 20 is moved to the right at high speed, the impact on shoulder 
25 will be cushioned by the resilience of the plastic material of the 
shoulder and the cylinder 11, thereby eliminating the necessity for use of 
hydraulic shock cushioning devices which might otherwise be necessary on 
other types of cylinders. 
If desired, spring 24 of cylinder 10 may be positioned between piston head 
22 and shoulder 25 so that the piston head is biased against wall 21. When 
constructed in this manner, the introduction of pressurized fluid through 
port 29 will cause piston rod 20 to move to the right to effect a clamping 
action, and when the pressure is relieved at port 29, spring 24 will 
return piston head 22 to its position against wall 21 and thus move the 
piston rod accordingly to terminate the clamping action. 
As stated briefly above, in the past fluid cylinders which were molded of 
plastic had a uniform outer diameter throughout their length, as shown in 
U.S. Pat. No. 4,265,344. However, in such cylinders, the end portion 
analogous to portion 13 of the present cylinder was thicker so that it 
could provide an annular shoulder, such as 25. This sometimes resulted in 
gas pockets being formed at the junction of the thinner and thicker 
portions in the device of U.S. Pat. No. 4,265,344. However, by maintaining 
the wall thickness of end portion 13 substantially equal to and 
substantially no greater than the thickness of wall portion 12, the 
foregoing problem was alleviated. The wall thickness of end portion 13 may 
be less than the thickness of wall portion 12, if desired, provided that 
it will have sufficient hoop strength. The only limitation on the 
thickness of end portion 15 is that it should be sufficiently thick to 
have adequate hoop strength and it should not be substantially thicker 
than the thickness of wall portion 12 so as to avoid formation of gas 
bubbles in the neck portion 14. 
In FIG. 1A, the preferred method of fabricating cylinder 11 is 
schematically shown. This form of fabrication provides the maximum hoop 
stress resistance by causing the gates of the mold to be positioned so the 
flow of plastic is in the form of a continuous helical ribbon, as shown, 
the ribbon merging to form the solid walls, such as shown in FIG. 1. As 
noted above, by forming the cylinder 11 in the foregoing manner, its hoop 
stress resistance is increased. However, the cylinder of FIG. 1 can also 
be formed by conventional injection molding for low stress applications. 
In FIGS. 4 and 5 an energy absorber unit 33 is shown in which the cylinder 
12' was formed in the manner described above relative to FIGS. 1 and 1A, 
and accordingly numerals which are primed will represent structure 
analogous to the unprimed numerals of FIG. 1. The energy absorber device 
33 of FIG. 4 is a spring-shock having the same cylinder construction as 
the fluid cylinder of FIGS. 1 and 1A. Piston head 34 has a plurality of 
bleed bores 35 therein, and a check valve 36 covers bores 35 to prevent 
the flow of compressible fluid in chamber 37 from flowing through bores 35 
when piston head 34 moves to the left against the bias of spring 24'. When 
piston head 34 moves to the left, the flow of compressible fluid will be 
around piston head 34. An annular non-interconnected foam member 40, which 
is located in reduced end portion 13' as shown, reduces in volume as 
piston rod 20' enters cylinder 11'. When piston head 34 moves to the right 
as spring 24' expands after the force which moved piston head 34 to the 
left is released, valve 36 unseats to permit fluid to flow from the right 
of piston head 34 through bores 35 and through opening 39 in valve 36 into 
chamber 37. The external surface of cylinder portion 12' is threaded at 
diametrically opposite portions 41 so that it may be secured to a suitable 
tapped base, without requiring additional brackets. The threads 41 are 
formed on the outside or low stressed portion of the cylinder which is 
subjected to critical hoop bursting stresses, and thus the threads do not 
provide the high stress points which can produce hoop or notch failure. 
Thus, the threads 41 provide large diameter, lightly loaded threads in the 
low stress area of a pressure vessel using a comparatively low strength 
plastic. The sides of cylinder portion 12' may have flats 42 thereon 
throughout their length for gripping by a wrench. 
In FIGS. 6 and 7 another embodiment of the present invention is shown 
wherein the cylinder of the energy absorber unit 42 has the same basic 
structure discussed above relative to FIGS. 1 and 1A but is in the nature 
of a pure liquid spring type of shock absorber. The double primed numerals 
applied to FIGS. 6 and 7 represent structure which is largely identical to 
or analogous to structure of FIG. 1 bearing unprimed numerals, and 
therefore an additional discussion is deemed unnecessary. This embodiment 
differs from that of FIG. 1 in that shoulder 25" and fluid amplified head 
22 are made in accordance with the teachings of U.S. Pat. No. 3,722,640. 
In this instance, a different core pin is used in the molding die to 
provide the tapered shoulder stop 25" and matching complementary piston 
head configuration 22. The tapered shoulder also provides more even 
plastic flow for avoidance of even tiny gas voids in ultra high pressure 
cylinders. In this embodiment chambers 43 and 44 are filled with 
compressible liquid so that as piston rod 20" enters these chambers, the 
liquid will be compressed and when the force on cap 23", which caused 
piston rod 20" to enter, is released, the expansion of the compressible 
liquid within chambers 43 and 44 will cause the piston rod 20" to move to 
the position shown in the drawing wherein piston head 22 abuts annular 
shoulder 25". Preferably main body portion 12" includes threads 45 on 
opposite sides thereof, as described in detail above relative to FIG. 4. 
If desired, shoulder 25 of FIG. 1 may also be of a shape which is 
complementary to the surface of a piston head. 
A preferred plastic for use in all the foregoing embodiments is nylon. 
However, other structural and sealing plastics, such as DELRIN may be used 
which provide high strength and low friction sealing characteristics. 
In addition, suitable high strength composite or metal liners can be used, 
such as disclosed in my copending patent application Ser. No. 370,738, 
filed Apr. 22, 1982. 
While preferred embodiments of the present invention have been disclosed, 
it will be appreciated that the present invention is not limited thereto 
but may be otherwise embodied within the scope of the following claims.