Information
-
Patent Grant
-
6254366
-
Patent Number
6,254,366
-
Date Filed
Tuesday, June 13, 200024 years ago
-
Date Issued
Tuesday, July 3, 200123 years ago
-
Inventors
-
Original Assignees
-
Examiners
Agents
- Luck; Gregory M.
- Sankey & Luck, L.L.P.
-
CPC
-
US Classifications
Field of Search
US
- 418 119
- 418 2066
- 418 114
- 418 147
- 277 357
- 277 402
- 277 549
- 277 551
- 277 562
-
International Classifications
-
Abstract
A replaceable seal for a rotor in a rotary fluid machine has a unitary body with integrally formed longitudinal and radial seal portions secured by a friction fit in grooves in the rotor. The longitudinal seal portion includes an outwardly biased seal lip, and an elongated body portion fitting within the groove in the rotor. The elongated body portion has a pair of anchor elements connected by a flat arm element. The radial seal portion has an outwardly biased seal lip, and a retainer post securing the seal in a cavity in the rotor.
Description
FIELD OF THE INVENTION
This invention relates to a replaceable seal, and more particularly, to a replaceable seal for a rotary fluid machine such as a pump or turbine.
BACKGROUND OF THE INVENTION
Rotary fluid machines, such as turbines or pumps, have been developed to measure the quantity of fluid that flows past a point, or inject predetermined quantities of liquid additives into liquid flow streams. Such devices can be used, for example, to add materials such as iodine or io: chlorine to drinking water or liquid fertilizer concentrate to irrigation water. They frequently employ one or two rotors or vanes that rotate in a housing or flow conduit. Turbines frequently employ rotors having close tolerances between the ends of the blades and the stator, while pumps frequently employ rotors with ends that engage the housing.
Most rotary fluid machines experience a degree of leakage during ordinary operation. This leakage increases as the rotors began to wear. Leakage generally occurs in both the radial and axial directions with respect to the rotors. Seals have been provided to minimize leakage, but are not completely effective.
It is important that the leakage in a pump or turbine be minimized. The head pressure that a pump or turbine can deliver is largely determined by the efficiency with which the leakage around the seals can be controlled. In addition, in certain applications, contamination of fluids being pumped or metered must be avoided.
When the leakage around the seals becomes significant, the seals must be replaced. This is a difficult task, particularly because it is generally not clear which seals are leaking, thus requiring some seals to be replaced that were not leaking.
SUMMARY OF THE INVENTION
In accord with the present invention, a seal for a rotor in a rotary fluid machine comprises a longitudinal seal portion secured in a longitudinal groove in the rotor by a friction fit, and a radial seal portion secured in a radial groove in the rotor by a friction fit. The longitudinal seal portion and the radial seal portion integrally form a unitary seal body.
In accord with another aspect of the present invention, a replaceable sealing system for a rotor in a rotary fluid machine comprises a pair of seals, each secured in radial and longitudinal grooves in the rotor. The seals have a unitary integrally formed body with a longitudinal seal portion and a radial seal portion. The longitudinal seal portion is dimensioned to make a secure friction fit in the longitudinal groove in the rotor, and the radial seal portion is dimensioned to make a secure friction fit in the radial groove in the rotor.
In accord with yet another aspect of the present invention, the improvement in a rotary fluid machine comprises a unitary replaceable seal with an integrally formed longitudinal seal portion secured by a friction fit in a longitudinal groove in the rotor, and an integrally formed radial seal portion secured by a friction fit in a radial groove in the rotor.
In accord with still a further aspect of the present invention, a replaceable seal for a rotor in a flow meter comprises a longitudinal seal portion secured by a friction fit in a longitudinal groove in the rotor. The longitudinal seal portion includes an outwardly biased seal lip, and an elongated body portion dimensioned to fit within the groove in the rotor and removably secure the seal in the rotor. The elongated body portion has a pair of anchor elements connected by a flat arm element. A radial seal portion is secured by a friction fit in a radial groove in the rotor, and has an outwardly biased seal lip. A retainer post is connected to the seal lip and is dimensioned to fit within a cavity in the rotor and removably secure the seal in the rotor. The retainer post is generally L-shaped, with a radial portion connected to the seal lip and mating with the radial groove in the rotor, and a longitudinal portion mating with a longitudinal bore in the rotor. The longitudinal seal portion and the radial seal portion integrally form a unitary seal body.
BRIEF DESCRIPTION OF THE DRAWINGS
The attached drawings illustrate preferred embodiments of the invention, in which:
FIG. 1
is a cutaway plan view of a rotary fluid machine such as a meter showing the rotors with the seals of the present invention;
FIG. 2
is a cutaway perspective view of the rotary fluid machine of
FIG. 1
illustrating the rotors and seals;
FIG. 3
is a fragmentary side view of the rotary fluid machine taken along the line
3
—
3
of
FIG. 1
;
FIG. 4
is a perspective view of a rotor with one of the seals removed;
FIG. 5
is a perspective top view of a seal; and
FIG. 6
is a perspective bottom view of the seal of FIG.
5
.
DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS
Referring to the drawings, and particularly to
FIG. 1
thereof, there is shown a rotary fluid machine
10
such as a flow meter that includes a pair of rotors
12
,
14
each rotatably mounted by a shaft
16
,
18
in a housing
20
. A suction fitting
22
supplies a vacuum to an injector
24
. The rotors
12
,
14
provide reciprocating motion to the injector
24
via the shafts
16
,
18
through crankshafts connected to the shafts
16
,
18
. The reciprocating motion of the crankshafts
12
,
14
injects materials, such as chlorine or iodine, into the fluid path and at or beyond an exhaust outlet
28
. The rotation of rotors
12
,
14
is provided by the flow of fluid through the housing
20
. In the illustrated embodiment, fluid flows from the intake inlet
26
, rotates the rotors
12
,
14
, and then flows out the exhaust outlet
28
.
As seen in
FIG. 2
, each rotor
12
,
14
includes a plurality of seals
30
a
,
30
b
positioned in corresponding interconnected longitudinal and radial grooves
32
,
34
formed in the teeth or vanes
36
thereof. In the preferred embodiment, each seal
30
a
,
30
b
has a unitary integral body with a longitudinal portion
38
secured by a friction fit in the longitudinal groove
32
in the rotor
14
and a radial portion
40
disposed by a friction fit in the radial groove
34
in the rotor
14
. Each longitudinal groove
32
has a pair of seals
30
a
,
30
b
disposed therein, with one seal
30
a
providing a sealing action along one radial edge of the rotor
14
and one half of the length of the longitudinal groove
32
.
As seen most clearly in
FIG. 3
, the rotors
12
,
14
are mounted in the housing
20
with relatively close tolerances between the ends
44
of the vanes or teeth
36
and the housing
20
. The depicted flow meter
10
has a pair of rotors
12
,
14
, each cooperating with the other and turning in opposite directions. The upper rotor
12
of
FIG. 3
turns in the clockwise direction, as indicated by the arrow C, while the lower rotor
14
turns in the counterclockwise direction, as indicated by the arrow A.
In order to ensure adequate sealing between the rotors
12
,
14
and the housing
20
, it has been found that a minimum of two teeth or vanes
36
, and corresponding four seals
30
a
,
30
b
, must be in contact with the housing
20
at one time. The seals
30
a
,
30
b
contact a portion of the housing
20
commonly identified as the sealing range
46
.
As seen most clearly in
FIGS. 5 and 6
, each seal
30
a
is formed of a unitary integral body with the longitudinal seal portion
38
and the radial seal portion
40
. The longitudinal seal portion
38
includes a flexible longitudinal seal lip
48
that is outwardly biased to contact the housing
20
(see
FIGS. 2 through 4
) and prevent leakage around the rotor
12
along the lateral edge thereof. The longitudinal seal portion
38
further includes a pair of anchor elements
50
,
52
for anchoring or securing the seal
30
a
in the rotor
12
. A flat arm element
54
connects the anchor elements
50
,
52
(see FIG.
6
).
The anchor elements
50
,
52
are dimensioned so that the distal ends
56
,
58
thereof act as stop elements for the biasing movement of a radial seal lip
60
. When the seal
30
a
is disposed in the housing
20
, the radial seal lip
60
(and horizontal seal lip
48
as well) are compressed to provide the requisite sealing action. The distal ends
56
,
58
of the anchor elements
50
,
52
prevent the radial seal lip
60
from moving too far inward (i.e., towards the inner portion of the rotor
12
) and thereby damaging same.
The provision of a pair of anchor elements
50
,
52
connected by a flat arm element
54
permits the longitudinal seal portion
38
to flex and form a good friction fit in the longitudinal
20
groove
32
of the rotor
12
. This structure is advantageous because it maintains a close approximation of a constant wall thickness, thereby improving manufacturability due to the flow characteristics of the plastic used in the molding process. In addition, the flexibility of the longitudinal seal portion
38
allows for relatively lower tolerance standards to be applied to the shape of the longitudinal groove
32
of the rotor
12
, since a tight fit can be obtained due to the flexing of the longitudinal seal portion
38
. Finally, the disclosed structure is lighter in weight and less expensive to manufacture than a solid longitudinal seal portion
38
would otherwise be.
The seal
30
a
includes an L-shaped retainer post
62
to lock the seal
30
a
in the rotor
12
. The radial seal portion
40
is a friction fit in the radial groove
42
of the rotor
12
and includes the outwardly biased radial seal lip
60
that mates with the housing
20
and prevents leakage therearound. The retainer post
62
includes a longitudinal portion
64
disposed in a longitudinal bore
66
in the rotor
12
(see FIG.
4
). The longitudinal portion
64
of the retainer post
62
locks the seal
30
a
in the rotor
12
and prevents the seal
30
a
from being accidentally dislodged therefrom. A radial portion
68
is connected to the radial seal lip
60
and is friction fit into the radial groove
34
.
It will be appreciated that the seals
30
a
,
30
b
of the present invention may be easily replaced in the rotor
12
,
14
. The old seal
30
a
is removed by applying a lateral force along the longitudinal seal portion
38
, preferably by pulling on the radial seal portion
40
. The anchor elements
50
,
52
are then inserted in the longitudinal groove
32
of the rotor
12
, and seal
30
a
slides in the longitudinal groove
32
until the radial seal portion
40
is press fit into the radial groove
34
of the rotor
12
. The locking element
64
then locks the seal
30
a
in the rotor
12
,
14
, preventing accidental dislodgment.
It is to be further appreciated that, with an embodiment of the present invention, it is unnecessary to identify whether the longitudinal
38
seal or the radial
40
seal is causing the leakage, as both are replaced simultaneously.
For purposes of exemplification, particular embodiments of the invention have been shown and described according to the best present understanding thereof. However, it will be apparent that various changes and modifications in the arrangement and construction of the parts thereof may be made without departing from the spirit and scope of the invention as defined in the appended claims.
Claims
- 1. A seal for a rotor in a rotary fluid machine comprising:a longitudinal seal portion secured in a longitudinal groove in said rotor by a friction fit; a radial seal portion secured in a radial groove in said rotor by a friction fit; wherein said longitudinal seal portion and said radial seal portion integrally form a unitary seal body.
- 2. The seal of claim 1, wherein said longitudinal seal portion includes an outwardly biased seal lip.
- 3. The seal of claim 2, wherein said radial seal portion includes an outwardly biased seal lip.
- 4. The seal of claim 3, wherein said longitudinal seal portion includes an elongated body portion dimensioned to fit within said groove in said rotor and removably secure said seal in said rotor.
- 5. The seal of claim 4, wherein said elongated body portion includes a stop element to limit the inward movement of said seal lip of said radial seal portion.
- 6. The seal of claim 5, wherein said elongated body portion comprises a pair of anchor elements connected by a flat arm element.
- 7. The seal of claim 6, wherein said radial seal portion includes a locking element connected to said seal lip and dimensioned to fit within a cavity in said rotor and removably secure said seal in said rotor.
- 8. The seal of claim 7, wherein said locking element comprises a retainer post.
- 9. The seal of claim 8, wherein said retainer post is generally L-shaped, with a radial portion connected to said seal lip and mating with said radial groove in said rotor, and a longitudinal portion mating with a longitudinal bore in said rotor.
- 10. A replaceable sealing system for a rotor in a rotary fluid machine, said rotor having a longitudinal groove connected to a radial groove on each end thereof comprising:first and second seals removably secured in said grooves in said rotor, each of said seals having a unitary integrally formed body with a longitudinal seal portion and a radial seal portion, said longitudinal seal portion dimensioned to make a secure friction fit in said longitudinal groove in said rotor, and said radial seal portion dimensioned to make a secure friction fit in said radial groove in said rotor.
- 11. The sealing system of claim 10, wherein said longitudinal seal portion includes an outwardly biased seal lip.
- 12. The sealing system of claim 11, wherein said radial seal portion includes an outwardly biased seal lip.
- 13. The sealing system of claim 12, wherein said longitudinal seal portion includes an elongated body portion dimensioned to fit within said groove in said rotor and removably secure said seal in said rotor.
- 14. The sealing system of claim 13, wherein said elongated body portion includes a stop element to limit the inward movement of said seal lip of said radial seal portion.
- 15. The sealing system of claim 14, wherein said elongated body portion comprises a pair ofanchor elements connected by a flat arm element.
- 16. The sealing system of claim 15, wherein said radial seal portion includes a locking portion dimensioned to fit within a cavity in said rotor and removably secure said seal in said rotor.
- 17. The sealing system of claim 16, wherein said locking portion comprises a retainer post.
- 18. The sealing system of claim 17, wherein said retainer post is generally L-shaped, with a radial portion connected to said seal lip and mating with said radial groove in said rotor, and a longitudinal portion mating with a longitudinal bore in said rotor.
- 19. In a rotary fluid machine with a rotor, the improvement comprising a unitary replaceable seal with an integrally formed longitudinal seal portion secured by a friction fit in a longitudinal groove in said rotor, and an integrally formed radial seal portion secured by a friction fit in a radial groove in said rotor.
- 20. The improvement of claim 19, wherein said longitudinal seal portion includes an outwardly biased seal lip.
- 21. The improvement of claim 20, wherein said radial seal portion includes an outwardly biased seal lip.
- 22. The improvement of claim 21, wherein said longitudinal seal portion includes an elongated body portion dimensioned to fit within said groove in said rotor and removably secure said seal in said rotor.
- 23. The improvement of claim 22, wherein said elongated body portion includes a stop element to limit the inward movement of said seal lip of said radial seal portion.
- 24. The improvement of claim 23, wherein said elongated body portion comprises a pair of anchor elements connected by a flat arm element.
- 25. The improvement of claim 24, wherein said radial seal portion includes a locking element connected to said seal lip and dimensioned to fit within a cavity in said rotor and removably secure said seal in said rotor.
- 26. The improvement of claim 25, wherein said locking element comprises a retainer post.
- 27. The improvement of claim 26, wherein said retainer post is generally L-shaped, with a radial portion connected to said seal lip and mating with said radial groove in said rotor, and a longitudinal portion mating with a longitudinal bore in said rotor.
- 28. A replaceable seal for a rotor in a flow meter comprising:a longitudinal seal portion secured by a friction fit in a longitudinal groove in said rotor, said longitudinal seal portion including an outwardly biased seal lip, and an elongated body portion dimensioned to fit within said groove in said rotor and removably secure said seal in said rotor, said elongated body portion having a pair of anchor elements connected by a flat arm element; a radial seal portion secured by a friction fit in a radial groove in said rotor, said radial seal portion including an outwardly biased seal lip, and a retainer post connected to said seal lip and dimensioned to fit within a cavity in said rotor and removably secure said seal in said rotor, said retainer post being generally L-shaped, with a radial portion connected to said seal lip and mating with said radial groove in said rotor, and a longitudinal portion mating with a longitudinal bore in said rotor; wherein said longitudinal seal portion and said radial seal portion form a unitary seal body.
- 29. The replaceable seal of claim 28, wherein said elongated body portion includes a stop element to limit the inward movement of said seal lip of said radial seal portion.
US Referenced Citations (4)