Pressure regulator

Information

  • Patent Grant
  • 6619308
  • Patent Number
    6,619,308
  • Date Filed
    Tuesday, August 14, 2001
    23 years ago
  • Date Issued
    Tuesday, September 16, 2003
    21 years ago
Abstract
A variable device for regulating the outlet pressure of a fluid from a valve body, includes a pressure-sensing chamber having a wall formed by a resilient self-restoring diaphragm which is responsive to pressure in the chamber. A valve element connected to the diaphragm controls flow into the chamber. Increased pressure in the chamber decreases the flow into the chamber and decreasing pressure increases flow whereby fluid flow out from the chamber is maintained at a desired pressure. The outlet pressure is adjusted by deflecting the diaphragm in a direction to open the valve while permitting a section of the diaphragm connected to the valve member to remain responsive to the pressure in the chamber. An adjustment cover is provided to adjustably deflect the diaphragm and includes a catch mechanism to allow adjustment of the fluid outlet pressures and also retain the device at a desired value. An indicator arrangement may be provided to visually indicate the fluid outlet pressure.
Description




FIELD OF THE INVENTION




This invention relates to fluid pressure regulators, and particularly to regulators well suited for controlling the output pressure of elastomeric balloon or mechanical pumps. More specifically, the present invention relates to a variable fluid pressure regulator which allows for convenient adjustment of fluid outlet pressure.




BACKGROUND OF THE INVENTION




Pressure regulators that reduce or cut off inlet flow of a fluid when the outlet pressure starts to exceed a predetermined maximum and that open or increase flow when the outlet pressure has been sufficiently reduced are well known in the art. Such regulators generally include a coil spring that biases a valve member open, and a pressure-sensing element responsive to excess inlet pressure which closes the valve member. In this arrangement, increasing liquid pressure compresses the spring to force the valve member towards a valve seat. As the valve member approaches the valve seat, liquid flow through the regulator becomes more restricted. When the defined pressure level is reached, further flow restriction is stopped, or the valve member contacts the valve seat to cut off flow. When the output pressure drops below the defined pressure, the valve member moves away from the valve seat and flow increases. This cycle is rapidly repeated over and over to maintain the output pressure at the desired setting.




Numerous pressure regulating devices teach the use of a coil spring, such as U.S. Pat. No. 3,412,650 by Stang, U.S. Pat. No. 3,547,427 by Kelly, U.S. Pat. No. 3,603,214 by Murrell, U.S. Pat. No. 3,747,629 by Bauman, U.S. Pat. No. 3,825,029 by Genbauffe, U.S. Pat. No. 4,074,694 by Lee, U.S. Pat. No. 4,621,658 by Buezis et al., U.S. Pat. No. 4,744,387 by Otteman, U.S. Pat. No. 5,141,022 by Black, and U.S. Pat. No. 5,732,736 by Ollivier. However, a need exists for a pressure regulator device without a spring coil, thereby resulting in a more reliable device with fewer parts which is easier to assemble and costs less.




The majority of the subject pressure regulators of the above-referenced patents are manufactured to provide a single, specific fluid outlet pressure or be adjustable between a high and a low setting. However, there also exists a need for a variable pressure regulator device that allows for the selection, from a range of values, of a desired fluid outlet pressure by a user. This capability is particularly desirable in connection with small pumps used in the medical field wherein fluids are being dispensed to a patient.




SUMMARY OF THE INVENTION




A goal of preferred embodiments is to provide a simplified pressure regulator having fewer parts thereby making it easier to assemble, less expensive and less likely to break. Instead of having the traditional springs located above and below a flexible diaphragm, a resilient diaphragm is employed that by itself controls input flow and regulates output pressure. The diaphragm is made of an elasticomeric material, and is designed not only to act as a diaphragm, but also to replace the pressure sensing spring and the valve seat spring.




Preferably, the diaphragm is manufactured to be flat, however, after installation into the regulator, an adjuster is moved to deflect the diaphragm. The amount of deflection corresponds with the desired outlet fluid pressure. The diaphragm resists deflection when outlet pressure is less than the desired level, but flexes towards a closed position when the outlet pressure exceeds this level. Thus, this diaphragm uniquely has the additional advantage of functioning as a spring without having any of the disadvantages.




Additionally, a preferred embodiment of the fluid pressure regulator includes a cover, which engages the adjuster such that rotation of the cover results in rotation of the adjuster to deflect the diaphragm and adjust the fluid outlet pressure, as described above. Such a construction advantageously allows convenient adjustment of the fluid outlet pressure by medical personnel and, thus, permits the variable fluid regulator to accommodate a variety of fluid dispensing needs.











BRIEF DESCRIPTION OF THE DRAWINGS




These and other features of the present invention will be better understood by reference to the following detailed description when considered in conjunction with the accompanying drawing wherein:





FIG. 1

is a cross-sectional view of a preferred embodiment of a pressure regulator;





FIG. 2

is a cross-sectional view of an additional embodiment of a pressure regulator;





FIG. 3

is an exploded, perspective view of the pressure regulator of

FIG. 2

as viewed from above;





FIG. 4

is an exploded, perspective view of the pressure regulator of

FIG. 2

as viewed from below;





FIG. 5

is a cross-sectional view of another embodiment of a pressure regulator;





FIG. 6

is an exploded, perspective view of the pressure regulator of

FIG. 5

as viewed from above;





FIG. 7

is an exploded, perspective view of the pressure regulator of

FIG. 5

as viewed from below.











DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT




Referring to the drawings, the pre-set pressure regulator, indicated generally by the numeral


10


, comprises a base


15


, a resilient wall or diaphragm


20


, a retainer


25


, and an initial adjuster in the form of a cap


30


. The base


15


has an inlet


35


where fluid is introduced into the regulator


10


and an outlet


40


where the fluid exits at the desired pressure. A central, axial passage


45


extends through the base


15


, and is in fluid communication with the inlet


35


. The diameter of the open end at the top of the passage


45


which is smaller than the lower portion forms a valve seat


50


. A plug


55


closes the lower end of the passage.




The top surface of the base


15


is concave and forms the lower boundary of a fluid pressure-sensing chamber


60


. The perimeter of the top surface of the base member has an angled, annular shoulder


65


which defines a seating and gripping surface for the diaphragm


20


. The shoulder


65


has an externally threaded lip


70


which mates with interior threads on the retainer


25


, which is generally ring shaped. The outlet conduit


40


in fluid communication with the chamber


60


extends from the top surface of the base


15


to an exterior surface of the base


15


.




The diaphragm


20


is a generally circular, preferably generally flat member which has an outer annular portion clamped between the base shoulder


65


and a flat annular surface


90


on the retainer


25


to seal that area. This causes the bottom surface of the diaphragm to form the upper boundary of the pressure-sensing chamber


60


. The diaphragm is preferably made of an elastomeric material, such as silicone so that it will be responsive to fluid pressure changes in the chamber


60


and has a significant “memory” so that it is self-restoring. Depending from the diaphragm


20


is an integral valve stem


75


which extends axially through the chamber


60


and into the passage


45


. A valve element


80


on the lower end of the valve stem is positioned in the passage


45


to cooperate with the valve seat


50


. The valve element is preferably ball-shaped as illustrated, but may be in the form of a disk or other suitable shape that will properly mate with the valve seat. During assembly, the valve element


80


may be lubricated with alcohol to enable it to be pushed through the valve seat into the passage


45


.




The retainer


25


may be ultrasonically welded to the base


15


if desired. An annular area


95


of the retainer


25


slopes upwardly, and inwardly to an interiorly threaded collar


105


, which is part of the retainer. The adjuster cap


30


has a flat upper wall


110


and a cylindrical flange


115


extending downward into the collar


105


. The exterior surface of the flange


115


is threaded to mate with the threads of the collar


105


. The cap


30


is adjusted so that its lower annular end contacts the top surface of the diaphragm


20


. The circular, central section of the diaphragm, which is bounded by the cylindrical flange


120


, is responsive to fluid pressure in the chamber


60


. The loading by the adjusting cap


30


pushes the diaphragm


20


downward, thereby unseating the valve element


80


, as shown in the drawing. The adjuster may also be in sliding or cam-like engagement with the retainer.




The upper surface of the diaphragm


20


and the initial adjusting cap


30


form an upper interior space


130


that is separated from the pressure-sensing chamber


60


by the diaphragm


20


. Vents


125


extend through the flat surface


110


of the adjusting cap


30


to prevent pressure build-up in the upper interior space


130


, and to facilitate turning the adjuster cap


30


when setting the desired pressure.




The base


15


, plug


55


, adjusting cap


30


, and retainer


25


are preferably made of polyvinyl chloride, but may be made of other durable, inexpensive materials known to those of ordinary skill in the art.




When the diaphragm


20


is assembled within the pressure regulator


10


, between the angled shoulder


65


of the base


15


and the flat surface


90


of the retainer


25


, the valve member


80


is seated in a sealed closed position. After a pressure source is attached to the inlet


35


, the cap


30


is advanced against the diaphragm causing the annular tip of the cap flange


115


to deflect the diaphragm


20


, thereby unseating the valve element


80


from the valve seat


50


. While the valve element


80


is unseated, fluid travels through the inlet


35


and the valve seat


50


, flows into the fluid sensing chamber


60


, and out through outlet


40


. The cap is adjusted until the desired outlet pressure is attained. For a preset pressure device, a suitable adhesive or the like is applied to the threads at


115


to prevent changes in the output pressure setting.




When the pressure of the fluid in the chamber


60


exerts a force against the bottom of the diaphragm


20


greater than the desired value initially set by the adjusting cap


30


, a force imbalance occurs. The force of the fluid in the chamber


60


pushes the resilient central section of the diaphragm


20


upward causing the valve member


80


to move in a flow-reducing or flow stopping direction towards the valve seat


50


. When the outlet pressure drops below the desired level, the resilient diaphragm central section moves the valve member


80


away from the valve seat


50


and fluid flow into the chamber


60


increases. The resiliency of diaphragm


20


provides its central section the self-restoring flexibility to respond to the pressure of the fluid in the fluid pressure-sensing chamber


60


. Consequently, diaphragm


20


is an active member responsive to pressure changes without the need for a conventional spring.




The valve stem and the valve may be made of the same material as the diaphragm


20


and the valve member


80


, and may be made as a one piece unit. However, a valve stem


75


made from a material stiffer than that used to make the diaphragm


20


is better able to maintain a constant pressure over a wider range of input pressures. To increase stiffness and obtain this improved effect, a rigid pin (not shown) may be inserted into the valve stem


75


, after the diaphragm


20


is assembled into the valve body but before the adjusting cap


30


is installed. Alternatively, the cross section of the valve stem


75


may be increased over part or all of its length to increase stiffness. Further, the valve stem may be a completely separate part that links a separate valve element to the diaphragm.




The pressure regulator is useful in many applications but is particularly suited to control the output pressure of elastomeric balloon or other mechanical pumps.





FIGS. 2-4

illustrate an additional embodiment of a fluid pressure regulator, indicated generally by the reference numeral


10


′. The pressure regulator


10


′ is similar in construction and function to the pressure regulator


10


of FIG.


1


. Accordingly, like reference numerals will be used to denote like components, except that a (′) will be added.




With similarity to the embodiment of

FIG. 1

, pressure regulator


10


′ comprises a valve body including a base


15


′ and a retainer


25


′, a resilient wall or diaphragm


20


′, and an adjuster in the form of a cap


30


′. The base


15


′ has an inlet


35


′ where fluid is introduced into the regulator


10


′ and an outlet


40


′ where the fluid exits at the desired pressure. A central, axial passage


45


′ extends through the base


15


′, and is in fluid communication with the inlet


35


′. The diameter of the open end at the top of the passage


45


′, which is smaller than the lower portion, forms a valve


50


′. A plug


55


′ closes the lower end of the passage.




As with the embodiment of

FIG. 1

, the diaphragm


20


′ of the present pressure regulator


10


′ is clamped between the base


15


′ and the retainer


25


′. Therefore, the bottom surface of the diaphragm


20


′ forms the upper boundary of the pressure sensing chamber


60


′. An upper surface of the base


15


′ forms the lower boundary of the pressure sensing chamber


60


′. Depending from the diaphragm


20


′ is an integral valve stem


75


′, which extends axially through the chamber


60


′ and into the passage


45


′. A valve element


80


′ on the lower end of the valve stem is positioned in the passage


45


′ to cooperate with the valve seat


50


′.




As in the embodiment of

FIG. 1

, the adjuster cap


30


′ of the present pressure regulator


10


′ is threadably engaged within a central portion of the retainer


25


′. The adjuster


30


′ may be advanced or retracted relative to the retainer


25


′ such that a lower annular end


120


′ contacts the top surface of the diaphragm


20


′. Advancing or retracting the adjuster


30


′ alters the force necessary to close the valve element


80


′ against the valve seat


50


′, thereby adjusting the fluid outlet pressure of the pressure regulator


10


′, as described above with respect to the embodiment of FIG.


1


.




The pressure regulator


10


′ of

FIGS. 2-4

additionally comprises a cover


150


. Preferably, the cover


150


is rotatably supported on the retainer


25


′ and engages the adjuster


30


′ such that the adjuster


30


′ is fixed for rotation therewith. Thus, rotation of the cover


150


results in corresponding rotation of the adjuster


30


′ such that the deflection of the diaphragm


20


′ is altered, thereby adjusting the fluid outlet pressure.




With reference to

FIGS. 3 and 4

, the cover


150


preferably includes a plurality of flexible lock tabs


152


. The lock tabs


152


engage the retainer


25


′ to hold the cover


150


in a substantially fixed axial relationship with the retainer


25


′, while allowing rotation with respect thereto.




Each lock tab


152


includes a substantially transversely extending lock surface


154


configured to engage a retaining surface


156


of the retainer


25


′. The retaining surface


156


may be a transversely extending uninterrupted annular surface. However, the retaining surface


156


may also include a series of interrupted surfaces, preferably with the interruptions being less than a width of any one of the flexible lock tabs


152


.




The illustrated pressure regulator


10


′ includes four, equally spaced lock tabs


152


(FIG.


4


), however, a lesser or greater number of lock tabs


156


may be used. Advantageously, the lock tabs


152


and retaining surface


156


construction allow assembly of the cover


150


to the retainer


25


′ without the use of tools or additional fasteners. However, other suitable coupling methods may also be used.




With reference to

FIG. 2

, the cover


150


includes a pair of downwardly extending shafts or pins


157


which engage vent holes


125


′ of the adjuster cap


30


′. The shafts


157


may be of a smaller diameter than that of the vent holes


125


′ such that pressure build-up in the upper chamber


130


′ is avoided.




The pair of shafts


157


fix the adjuster cap


30


′ for rotation with the cover


150


, while simultaneously allowing the adjuster cap


30


′ to move axially with respect to the cover


150


by sliding on the shafts


157


. Thus, when the cover


150


is rotated, the adjuster cap


30


′ both rotates, due to its engagement with the cover


150


via the shafts


157


, and moves axially with respect to the cover


150


, due to its threaded engagement with the retainer


25


′.




The pressure regulator


10


′ also includes a catch, or detent, mechanism


158


arrangement for locating the cover


150


in a desired angular position with respect to the retainer


25


′. Each of a plurality of recesses


160


define a plurality of angular positions relative to the base


15


′. The cover


150


includes a depending flexible tab


162


adjacent the cover periphery. The tab


162


includes an inwardly extending projection


164


(FIG.


4


). The illustrated projection


164


is hemispherical in shape and each of the recesses


160


are substantially semi-cylindrical in shape. However, other suitable mating shapes may also be used, as can be determined by one of skill in the art.




With reference to

FIG. 2

, the catch mechanism


158


is constructed such that the projection


164


is biased into engagement with a recess


160


by the inherent biasing force of the flexible tab


162


. As a result, the cover


150


and thus the adjuster cap


30


′ are held in one of the annular positions defined by the plurality of recesses


160


. When the cover


150


is rotated relative to the base


15


′ with a sufficient force, the projection


164


is disengaged from its current recess


160


and moves into engagement with the next adjacent recess


160


in the direction of rotation of the cap


150


. Preferably, the inherent biasing force of the flexible tab


162


is such that a caregiver and/or patient may rotate the cover


150


by hand, while also inhibiting undesired rotation of the cover


150


due to vibrations or inadvertent contact.




Advantageously, with such a construction, rotation of the cover


150


results in rotation of the adjuster cap


30


′ which, in turn, alters the deflection of the flexible diaphragm member


20


′. As discussed above, the outlet fluid pressure is influenced by the deflection of the flexible diaphragm member


20


′. Accordingly, the pressure regulator


10


′ allows a caregiver and/or patient to easily adjust the fluid outlet pressure to a desired value.




With reference to

FIG. 3

, the fluid pressure regulator


10


′ includes an indicator arrangement


166


, which correlates the angular position of the cover


150


with a resulting fluid outlet pressure. Advantageously, with such a construction the caregiver is able to adjust the variable pressure regulator


10


′ to a proper outlet pressure for a specific fluid being dispensed.




The illustrated indicator arrangement


166


comprises an annular scale


168


on the retainer


25


′. A reference indicia


170


is provided on the cap


150


and, when the cap


150


is assembled to the retainer


25


′, is aligned such that at least a portion of the scale


168


is indicated by the reference indicia


170


. In the illustrated embodiment, the reference indicia


170


comprises a window


172


and an arrow


174


. The window


172


is sized and shaped preferably to display one demarcation of the scale


168


. The arrow


174


allows for rapid identification of the location of the window


172


, and may or may not be provided.




The scale


168


of the illustrated embodiment is an index scale, which provides a relative indication of outlet pressure. Thus, each range of the index scale


168


may correspond to a predetermined value, or a range of values, for the fluid outlet pressure. Alternatively, the scale


168


may provide actual fluid pressure outlet values.




In an alternative arrangement, the scale


168


may be provided on the cap


150


and the reference indicia


170


may be located on the retainer


25


′, or possibly the base


15


′. In this arrangement, the reference indicia


170


may comprise a projection and/or colored region of the retainer


25


′ or base


15


′. Of course, other suitable arrangements for indicating a value on a scale may also be used. As such, it is not intended for the indicator arrangement


166


to be limited simply to the embodiments disclosed herein, but to include other suitable variations.





FIGS. 5-7

illustrate an alternative arrangement of the catch mechanism


158


. In this embodiment, the recesses


160


are defined on an upper annular surface of the retainer


25


′ and the flexible tab


162


is correspondingly located on an upper surface of the cover


150


. In addition, the recesses


160


are generally triangular in cross-section, as viewed in

FIG. 5

, with the radially innermost wall portion being rounded (FIG.


6


). With reference to

FIG. 7

, the projection


164


is semi-cylindrical in shape. Otherwise, the embodiment of

FIGS. 5-7

is similar in construction and function to the embodiment described immediately above.




Although this invention has been described in terms of certain embodiments, other embodiments apparent to those of ordinary skill in the art are also within the scope of this invention. Thus, various changes and modifications may be made without departing from the spirit and scope of the invention. Accordingly, the scope of the invention is intended to be defined only by the claims that follow.



Claims
  • 1. A variable pressure regulator control device comprising:a valve body having a fluid inlet, a fluid outlet, a fluid pressure-sensing chamber, and a valve seat in fluid communication with said inlet and defining an opening into said chamber; a resilient member forming a wall of said chamber which is responsive to pressure in said chamber and which is self-restoring; a valve stem connected to said member and extending through said chamber towards said valve seat; a valve element supported on said valve stem and cooperating with said valve seat, said valve element being located between the valve seat and said fluid inlet; an adjuster mounted to said valve body in a position to deflect said resilient member and move the valve element away from the valve seat while a portion of said resilient member connected to said stem flexes in response to pressure changes within said chamber to control the position of the valve element with respect to the valve seat; wherein said valve body includes a base incorporating said inlet, said outlet, and said valve seat; a retainer mounted atop said base, said retainer having an aperture for receiving said adjuster; and a cover fixing said adjuster for rotation therewith such that deflection of said resilient diaphragm is capable of being adjusted by rotation of said cover.
  • 2. The device of claim 1, additionally comprising a catch mechanism defining a plurality of angular positions relative to said valve body, said catch mechanism being configured to position said cover in one of said plurality of angular positions.
  • 3. The device of claim 2, wherein said catch mechanism comprises a plurality of recesses defined by one of said valve body and said cover, and at least one projection fixed in relation to the other of said valve body and said cover, said at least one projection configured to engage one of said plurality of recesses.
  • 4. The device of claim 3, wherein said at least one projection is biased into engagement with said recess such that rotation of said cover is inhibited in the absence of rotational torque on said cover and rotation of cover is permitted in response to rotational torque on said cover.
  • 5. The device of claim 4, wherein said recesses are defined by said valve body and said at least one projection is fixed for rotation with said cover, said cover additionally comprising at least one flexible tab portion, wherein said at least one projection is defined by a surface of said flexible tab portion.
  • 6. The device of claim 1, additionally comprising an indicator arrangement configured to relate an angular position of said cover with respect to said valve body to a predetermined fluid outlet pressure.
  • 7. The device of claim 6, wherein said indicator arrangement comprises a fluid outlet pressure scale on one of said valve body and said cover, and a reference indicia on the other of said valve body and said cover, said reference indicia capable of being aligned with a demarcation of said fluid outlet pressure scale to achieve a desired fluid outlet pressure.
  • 8. The device of claim 7, wherein said fluid outlet pressure scale comprises an index scale and said demarcations correspond to a range of fluid outlet pressures, said reference indicia comprising a view window approximately sized and shaped to display a single demarcation of said index scale.
  • 9. The device of claim 1, wherein said cover includes at least one flexible lock tab, said flexible lock tab defining a lock surface, said valve body including a retaining surface, said lock surface being configured to engage said retaining surface to substantially fix said cover in an axial position with respect to said valve body.
  • 10. The device of claim 9, wherein said retaining surface is an uninterrupted, annular surface defined by said retainer of said valve body.
  • 11. A method of regulating fluid pressure comprising the steps of:preventing the flow of a fluid through a valve seat into a fluid pressure chamber within a valve body, utilizing a flexible resilient diaphragm forming a wall of said chamber when said diaphragm is not mechanically deflected; deflecting a self-restoring section of said diaphragm to introduce fluid into said fluid chamber; flexing said self-restoring section in response to pressure changes within said chamber; controlling the flow of fluid through said valve seat into said chamber with a valve element mounted to move in response to the flexing of said diaphragm section in a manner such that increasing the pressure in said chamber moves said valve element towards said valve seat and decreasing the pressure in said chamber moves said valve element away from said valve seat; allowing fluid to flow from said chamber to an outlet in said valve body; adjusting the pressure by rotating a cover having an adjuster fixed for rotation therewith relative to said valve body, said adjuster deflecting said diaphragm in a manner to control the flexing of said diaphragm section to obtain a desired outlet pressure; defining a plurality of angular positions relative to said valve body; and positioning said cover in one of said plurality of angular positions.
  • 12. A variable pressure regulator control device comprising:a base having a wall forming a wall of a fluid pressure-sensing chamber, said base further including a fluid inlet in communication with a valve seat opening to the chamber, and a fluid outlet in communication with said chamber; a flexible, resilient diaphragm forming a wall of said chamber; a retainer clamping an annular peripheral portion of said diaphragm between the base and the retainer; a valve element mounted to a central section of said diaphragm cooperating with said valve seat in a manner such that increasing pressure in said chamber moves the valve element in a valve closing direction and decreasing the pressure in the chamber moves the valve element in a valve opening direction; an adjuster threadably connected to said retainer and having a flange which engages said diaphragm so as to deflect the diaphragm towards the valve seat, said flange defining a central section of said diaphragm which is movable in response to fluid pressure within said chamber; and a cover fixing said adjuster for rotation therewith such that rotation of said cover results in axial movement of said adjuster to adjust the deflection of said resilient diaphragm.
  • 13. The device of claim 12, additionally comprising a catch mechanism defining a plurality of angular positions relative to said retainer, said catch mechanism being configured to position said cover in one of said plurality of angular positions.
  • 14. The device of claim 12, additionally comprising an indicator arrangement configured to relate an angular position of said cover with respect to said retainer to a predetermined fluid outlet pressure.
  • 15. The device of claim 12, wherein said cover includes at least one flexible lock tab, said flexible lock tab defining a lock surface, said valve body including a retaining surface, said lock surface being configured to engage said retaining surface to substantially fix said cover in an axial position with respect to said valve body.
  • 16. A variable pressure regulator control device comprising:a valve body having a fluid inlet, a fluid outlet, a fluid pressure-sensing chamber, and a valve seat in fluid communication with said inlet and defining an opening into said chamber; a member forming a movable wall of said chamber which is responsive to pressure in said chamber; a valve element mounted to said member and cooperating with said valve seat in a manner such that increasing pressure in said chamber moves the valve element in a valve closing direction and decreasing the pressure in the chamber moves the valve element in a valve opening direction; an adjuster engaged with said valve body such that rotation of said adjuster deflects said member thereby adjusting a fluid output pressure of said pressure regulator; a cover fixing said adjuster for rotation therewith such that deflection of said member is capable of being adjusted by rotation of said cover.
  • 17. The device of claim 16, additionally comprising a catch mechanism defining a plurality of angular positions relative to said valve body, said catch mechanism being configured to position said cover in one of said plurality of angular positions.
  • 18. The device of claim 17, wherein said catch mechanism comprises a plurality of recesses defined by one of said valve body and said cover, and at least one projection fixed in relation to the other of said valve body and said cover, said at least one projection configured to engage one of said plurality of recesses.
  • 19. The device of claim 18, wherein said at least one projection is biased into engagement with said recess such that rotation of said cover is inhibited in the absence of rotational torque on said cover and rotation of cover is permitted in response to rotational torque on said cover.
  • 20. The device of claim 19, wherein said recesses are defined by said valve body and said at least one projection is fixed for rotation with said cover, said cover additionally comprising at least one flexible tab portion, wherein said at least one projection is defined by a surface of said flexible tab portion.
  • 21. The device of claim 16, additionally comprising an indicator arrangement configured to relate an angular position of said cover with respect to said valve body to a predetermined fluid outlet pressure.
  • 22. The device of claim 21, wherein said indicator arrangement comprises a fluid outlet pressure scale on one of said valve body and said cover, and a reference indicia on the other of said valve body and said cover, said reference indicia capable of being aligned with a demarcation of said fluid outlet pressure scale to achieve a desired fluid outlet pressure.
  • 23. The device of claim 22, wherein said fluid outlet pressure scale comprises an index scale and said demarcations correspond to a range of fluid outlet pressures, said reference indicia comprising a view window approximately sized and shaped to display a single demarcation of said index scale.
  • 24. The device of claim 16, wherein said cover includes at least one flexible lock tab, said flexible lock tab defining a lock surface, said valve body including a retaining surface, said lock surface being configured to engage said retaining surface to substantially fix said cover in an axial position with respect to said valve body.
  • 25. The device of claim 24, wherein said retaining surface is an uninterrupted, annular surface.
PRIORITY INFORMATION

This application is a continuation-in-part of U.S. patent application Ser. No. 09/350,955 filed Jul. 9, 1999, U.S. Pat. No. 6,273,117.

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5954090 Bilbrey Sep 1999 A
6254576 Shekalim Jul 2001 B1
6273117 McPhee Aug 2001 B1
Foreign Referenced Citations (2)
Number Date Country
479042 Jan 1938 GB
524698 Apr 1955 IT
Continuation in Parts (1)
Number Date Country
Parent 09/350955 Jul 1999 US
Child 09/931385 US