Plastic sleeved rotary valve

A rotary valve disc is provided internally of a single continuous length of pipe, and is secured therein by a segmented pipe coupling, thus eliminating requirement for two independent pipes and a separate seating for the valve disc, and permitting a reduction in the wall thickness of the pipe, particularly of pipes of plastics material.

FIELD OF THE INVENTION 
This invention relates to a disc valve for incorporation into a conduit. 
While not limited thereto, the rotary valve of the present invention finds 
particular utility in conduits comprised of pipe fabricated from plastics 
material. The invention also finds equal applicability in iron pipe, and 
also in thin-walled pipe such as stainless steel pipe. 
BACKGROUND OF THE INVENTION 
Rotary valves are well-known in the art, those valves including a valve 
seating, and a valve disc cooperating with the valve seating, the valve 
disc being rotatable externally of the valve between an opened and a 
closed position. 
Segmented pipe couplings also are well-known in the art, those couplings 
including two or more coupling segments having keys that are received 
within cut or roll-formed grooves in the adjacent ends of pipes, and which 
are bolted down onto the pipes by traction bolts, the segmented pipe 
coupling incorporating a sealing gasket that spans the adjacent ends of 
the pipes, and which is forced into compressive engagement therewith upon 
tightening down of the traction bolts. 
It also is previously known from McClennan U.S. Pat. 5,018,704, issued May 
28, 1991 and McClennan U.S. Pat. 5,018,548 also issued May 28, 1991, to 
form a disc valve as a complete unit, which is positioned between the 
adjacent ends of pipes, and, which is then secured in that position by a 
segmented pipe coupling having appropriately configured coupling segments. 
Such a rotary valve and pipe coupling combination, however, is of greatest 
utility when used for coupling metal pipes, and encounters a disadvantage 
when employed with plastics pipes. 
For such a segmented pipe coupling to be secured to the adjacent ends of 
pipes, it is necessary that the ends of the pipes be grooved for them to 
receive the securing keys of the respective coupling segments. 
While this poses no problem in metal pipes, which are of considerable 
strength, and which readily can be grooved by cut-grooving or 
roll-grooving, plastics pipes pose a particular problem in that they are 
structurally considerably less strong than metal pipes, particularly at 
the groove required in the plastics pipe in order to accommodate the keys 
of the coupling segments, that groove commonly having been formed by 
cut-grooving. 
At the cut-groove, the wall thickness of the pipe has been very 
considerably reduced by the depth of the cut-groove. Particularly in 
plastics pipe, this represents a major structural weakness in the piping 
system, unless compensated for by employing plastics pipe having a wall 
thickness that has been increased in thickness by an amount equal to the 
depth of the cut-groove. 
This, however, results in either an increase in the external diameter of 
the plastics pipe if the internal diameter is to be maintained at a 
standard diameter, or conversely, the reduction in the inner diameter of 
the plastics pipe in the event that an increase in the external diameter 
of the plastics pipe is not permissible. 
If the external diameter of the plastic pipe is to be increased, then, this 
requires step-down couplings for connecting the pipe to corresponding 
standard pipe. In the alternative, a decrease in the pipe internal 
diameter results in a reduction in the flow capacity of the assembled pipe 
line. 
An increase in the wall thickness of plastics pipe becomes necessary when 
the segmented pipe coupling is employed to join two independent lengths of 
plastics pipe, which in turn requires the cut-groove in the exterior of 
the respective pipes to be positioned closely adjacent the end of that 
pipe. 
This, however, presents a source of weakness in the plastics pipe, 
particularly in the event that the pipe line is subjected to axial bending 
moments. If the moment is sufficient, this can result in either ripping 
off of the pipe end in the location of the groove, or, deflection, bending 
and other distortions of that portion of the pipe that extends between the 
pipe end and the groove, with a possibility of the pipe pulling out of the 
segmented pipe coupling, possibly with disastrous consequences. 
Clearly, it would be a major advantage if the plastic pipe could continue 
continuously and without interruption through the segmented pipe coupling. 
OBJECT OF THE INVENTION 
It is an object of this invention to provide a rotary valve that is 
supported within a segmented pipe coupling, and in which, the requirement 
for separate pipes is eliminated, the pipe extending continuously through 
the segmented pipe coupling. 
The ends of the pipe extending on opposite sides of the segmented pipe 
coupling can then be secured to adjacent pipes by any convenient means, 
including direct solvent cement joints in the case of plastics piping, or, 
by segmented pipe couplings in the case of metal pipe. 
The major advantage of the present invention is when used in conjunction 
with plastics piping, which is inherently weaker than standard metal pipe, 
and even thin-walled metal pipe such as stainless steel pipe. As will be 
appreciated, the basic concept of the present invention, in certain 
circumstances, also will have application particularly in thin-walled 
metal pipe such as stainless steel pipe, and, in high-pressure 
applications, also in standard metal pipe. 
SUMMARY OF THE INVENTION 
According to the present invention, a rotary valve is provided internally 
of a continuous length of pipe, that length of pipe extending axially 
beyond the valve disc and the securing segmented pipe coupling in both 
axial directions. 
The disc valve is assembled internally of the continuous length of pipe, 
the continuous length of pipe providing the valve seat for the disc valve 
in the absence of a separate seating. 
The disc valve is then located against axial displacement within the pipe 
by means of a segmented pipe coupling, the segmented pipe coupling being 
configured to accommodate a valve spindle for operating the disc valve. 
The resulting construction is that of a unitary pipe, disc valve and 
operating mechanism, the pipe then being connectable to existing piping by 
any suitable means.

DESCRIPTION OF THE PREFERRED EMBODIMENT 
Referring now to FIGS. 1 and 2, the first major component of the rotary 
valve of the present invention is comprised of a pipe 12, which can be 
fabricated from a suitable plastics material, which optionally can be a 
reinforced plastics material, the reinforcements being comprised of woven 
or non-woven glass fibers and the like. The pipe 12 is axially elongate, 
and extends continuously from the end 14 to the end. 16 as a continuous 
hollow cylinder. 
Positioned within the pipe 12, as illustrated centrally of the length of 
the pipe 12, is a valve disc 18, the valve disc comprising a second major 
component of the rotary valve of the present invention, the valve disc 18 
being supported for rotary movement within the pipe by a journal 20, and 
rotatable within the pipe by means of a spindle 22, which is journaled in 
a bearing 24, the spindle being rotatable by an operating handle 26. 
Movement of the handle 26 between an opened and a closed position causes 
the valve disc 18, which is shown in the open position, to rotate through 
90.degree. into a position in which it extends transversely of the pipe 
12, and provides a complete closure for the pipe 12. 
As is well-known in the art, the valve disc can be provided with sealing 
lands 28 formed of a resilient material, the sealing lands 28, in the 
closed position of the valve disc, acting to seal against the inner 
circumference of the pipe 12. 
Surrounding the pipe 12 is the third major component of the assembly, this 
being comprised of segmented couplings 30 and 32, which are bolted onto 
the external circumference of the pipe 12 by means of traction bolts 34. 
The segmented couplings 30 and 32 each have retaining keys 36 on the inner 
circumference thereof, which are received in grooves cut in the outer 
circumference of the pipe 12, thus to inhibit axial movement of the 
coupling members 30 and 32 axially of the pipe 12, as opposed to the 
normal function of the keys 36, which is to retain adjacent ends of pipes 
against axial displacement relative to each other, i.e., the segmented 
coupling 30 and 32 merely functions as a support and retainer for the 
spindle 22 of the valve disc 18. 
Bellville washers 38 are provided on the valve spindle 22, and provide for 
positive locking of the operating handle 26 in either of its fully opened 
or fully closed positions, a detent 40 being provided on the underside of 
the handle 26, which is received in sockets [not shown]provided in the 
plate 42, over which the handle 26 and the detent 40 is angularly movable. 
O rings 42 are provided on the bearing 24 and the journal 20, in order to 
prevent fluid flow through the apertures 44 provided in the wall of the 
tube 12, the apertures 44 being configured as valve seats for the portions 
of the valve disc adjacent the journal 20 and the spindle 22. 
Optionally, and as shown in FIG. 3, a mastic cement 46 can be provided in 
the grooves that receive the keys 36 of the respective coupling segments 
30 and 32, the mastic 46 acting to inhibit movement of the coupling 
axially of the pipe 12. 
Assembly of the valve disc into the pipe 12 is accomplished in the absence 
of the coupling segments 30 and 32, and, the absence of the bearing 24. 
The valve disc 18 when in the position shown in FIGS. 1 and 2, is passed 
axially within the pipe 12, until such a time as its spindle is aligned 
with an aperture 44, at which time the valve disc is rotated about the 
central axis of the valve disc to bring the spindle 22 into position 
within one of the apertures 44. The journal 20 is then inserted through 
one of the apertures into engagement with the socket 48 of the valve disc, 
and, the bearing 24 is then inserted through the aperture 44 at the 
opposite diameter of the tube 12 for it to be positioned in surrounding 
relation with the spindle 22 of the valve disc 18. 
The coupling segments 30 and 32 are then applied to the pipe in correct 
alignment with the journal 20 and the spindle 22, subsequent to which the 
traction bolts 34 are applied and torqued down, this completing the 
assemblage of the pipe and rotary valve combination. 
As will be apparent, the pipe 12 does not necessarily need to be fabricated 
from plastics material. It could be standard metal pipe, or equally well 
be thin-walled pipe, or thin-walled stainless steel pipe. Further, and as 
will be readily apparent, the actuator for the valve can be of any form, 
including a screw and gear right-angled drive, which optionally is 
manually operable or electrically driven. 
In use, the pipe 12 together with the totally assembled valve disc and 
segmented coupling is connected into a piping system. Optionally, the 
remainder of the piping system also can be formed of plastics pipe, or, it 
can be comprised of metal pipe. If the piping system is comprised of 
plastics pipe, then, the pipe 12 can be connected either by butt 
cementing, solvent cementing or butt fusing to an adjacent pipe, or, can 
be connected thereto by a compatible segmented pipe coupling, or, 
similarly can be connected to step-up or step-down connectors, all of 
which are well-known in the art.