US2232899A - Automatic drain valve device - Google Patents

Automatic drain valve device Download PDF

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US2232899A
US2232899A US270524A US27052439A US2232899A US 2232899 A US2232899 A US 2232899A US 270524 A US270524 A US 270524A US 27052439 A US27052439 A US 27052439A US 2232899 A US2232899 A US 2232899A
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chamber
fluid
reservoir
pressure
seat
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US270524A
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Burton S Aikman
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Westinghouse Air Brake Co
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Westinghouse Air Brake Co
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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F16ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
    • F16TSTEAM TRAPS OR LIKE APPARATUS FOR DRAINING-OFF LIQUIDS FROM ENCLOSURES PREDOMINANTLY CONTAINING GASES OR VAPOURS
    • F16T1/00Steam traps or like apparatus for draining-off liquids from enclosures predominantly containing gases or vapours, e.g. gas lines, steam lines, containers
    • F16T1/12Steam traps or like apparatus for draining-off liquids from enclosures predominantly containing gases or vapours, e.g. gas lines, steam lines, containers with valves controlled by excess or release of pressure
    • F16T1/14Steam traps or like apparatus for draining-off liquids from enclosures predominantly containing gases or vapours, e.g. gas lines, steam lines, containers with valves controlled by excess or release of pressure involving a piston, diaphragm, or bellows, e.g. displaceable under pressure of incoming condensate
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10TTECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
    • Y10T137/00Fluid handling
    • Y10T137/2931Diverse fluid containing pressure systems
    • Y10T137/3003Fluid separating traps or vents
    • Y10T137/3102With liquid emptying means
    • Y10T137/3105Self-emptying
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10TTECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
    • Y10T137/00Fluid handling
    • Y10T137/794With means for separating solid material from the fluid
    • Y10T137/7976Plural separating elements

Definitions

  • This invention relates to an automatic drain valve for use on a reservoir or receiver for fluid under pressure and which operates to release moisture from this receiver or reservoir.
  • fluid pressure systems such as fluid pressure brake systems
  • air from the atmosphere is compressed and is stored in a reservoir or receiver from which fluid is withdrawn during operation of the brake equipment.
  • a reservoir or receiver from which fluid is withdrawn during operation of the brake equipment.
  • Another object of the invention is to provide a valve device automatically operable in response to variations in the pressure of the fluid in a reservoir or receiver for controlling a communication through which liquid may be released from the reservoir or receiver.
  • a further object of the invention is to provide a valve device of the type described which releases fluid from the receiver in limited volumes so that the supply of fluid in the receiver will not be unduly depleted by operation of the valve device.
  • a still further objectof the invention is to provide a valve device of the type referred to which is of rugged construction, and in which the elements are of such design as not to be damaged, if water present in the device freezes.
  • the drain valve device provided by my invention is mounted in a threaded opening in the lowermost portion of the reservoir or receiver I,
  • the body casing 2 has a tubular threaded portion 8 adapted to be received by the threaded 5 opening in the reservoir I.
  • the body has an annular chamber 1 formed therein which is in constant communication with the reservoir I through said tubular portion 8. l
  • the opposite end of the chamber is provided with a screw-threaded opening 8.
  • an annular flange 9 is provided at an intermediate point in the chamber I. A portion of this flange is adapted to form a valve seat II and a portion Ill above the valve seat is provided with screw- 15 threads.
  • the strainer portion 3 may comprise a cylindrical tubular wall member l2 made of perforated metal, such as, close mesh wire, which is closed at one end by a metal plate [3.
  • the tubular 20 member is supported at the opposite end by a metal ring it which is provided with screwthreads on its outer circumference. Both of said parts l3 and I may be secured to the wall member l2 in any suitable manner.
  • This strainer portion is screw-threaded into the threaded portion of flange 9 with the closed end projecting into the chamber I, asshown in the accompanying drawing.
  • the chamber I is closed by the cover portion 30 5 which is screw-threaded into the open end of the chamber 1 at 8.
  • the cover portion is provided with a chamber l5 into which one or more ribs 15 extend from the inside wall thereof and form a central boss 35 ll. At the bottom of the cover there is provided a release passage 22 which extends therethrough.
  • the valve portion 4 comprises a thin flexible diaphragm valve i9 interposed between the cham- 40 bers I and i5 and which is adapted to seat at its perimeter on the valve seat ll provided on the annular flange 9 in chamber 1.
  • a valve stem I8 is secured at one end to the center of the diaphragm valve l9 and extends through an 45 opening in the boss H.
  • the opposite end of the stem l8 has a substantially conical face thereon indicated at 20, which is adapted to seat upon a seat 2
  • the length of the stem I8 is such that when the valve portion 4 is assembled in operative position, that is, with the conical valve face 20 of the stem l8 engaging the seat 2
  • fluid under pressure is supplied to the reservoir I and it flows through the tubular portion 6 to the chamber 1 of the drain valve device. From this chamber fluid under pressure flows through the strainer member I2, which functions to remove foreign particles from the fluid passed therethrough, and thus prevents particles of dirt and dust from accumulating on the valve seat It. Thereby insuring that the diaphragm I9 will seat properly on said seat when it is so intended. After passing through the strainer the fluid under pressure exerts force on the upper face of the diaphragm I9 to flex it downwardly, away from the seat II.-
  • the force exerted by the fluid under pressure in the chamber I5 together with the force exerted by the diaphragm I9 overcomes the opposing force of the fluid under pressure in the chamber 1 and reservoir I on the opposite side of the diaphragm.
  • the diaphragm I9 is thereupon flexed upwardly until it seats on the seat II and cuts off the further supply of fluid under pressure from the chamber I and reservoir I to the chamber I5.
  • the volume of fluid released from the chamber I5 before the pressure of the fluid in this chamber is reduced to a value slightly below the pressure of the fluid in the reservoir is relatively maintain the diaphragm small because of the relatively small volume of the chamber I5.
  • the diaphragm I9 On an increase in the pressure of the fluid in chamber I5 substantially to the pressure of the fluid in the chamber I, the diaphragm I9 will be flexed upwardly by this fluid under pressure, until it engages the seat I I, to cut off the flow of fluid from the chamber I and reservoir I to the chamber I5.
  • the diaphragm On a subsequent increase in the pressure of the fluid in the reservoir I and connected chamber I, the diaphragm is flexed downwardly against the opposing force of the fluid under pressure in chamber
  • this pressure is increased substantially to the pressure of the fluid in chamber 1 and reservoir I, the diaphragm is thereafter again flexed upwardly until it engages theseat II.
  • the drain valve device On the next reduction in the.pressure. of the fluid in the reservoir l and connected chamber 1, the drain valve device operates as described in detail above to again release liquid from the chamber I5, and this cycle of operation is repeated on subsequent fluctuation in the pressure of the fluid in the reservoir I.
  • the volume of fluid, either liquid or gaseous, released by the drain valve device on each fluctuation of the pressure of the fluid in the reservoir is relatively small. Therefore, the fluid under pressure in the reservoir I will not be unduly depleted by operation of the drain valve device.
  • the amount discharged by the drain valve device on each operation thereof is, however, proportioned so that the drain valve device is enabled to maintain the reservoir l substantially free from moisture.
  • this drain valve device operates automatically in response to variations in the pressure of the fluid in reservoir I, and that it requires no attention on the part of the operator of the fluid pressure system with which it is associated.
  • a drain valve device for a reservoir, in combination, a body having a first chamber and a second chamber therein and having a release passage surrounded by a seat and communicating with said second chamber, another seat associated with said body, a valve member having a face thereon adapted to engage the seat surrounding the release passage, a diaphragm subject to the opposing pressures of the fluid in said first chamber and of the fluid in said second chamber adapted to engage said other seat to, control communication from said first chamber to said second'chamber and to urge said valve member into engagement with the seat surrounding said passage.
  • a drain valve device for a reservoir, in combination, a body having a chamber therein and having a. release passage surrounded by a seat and communicating with said chamber, another seat associated with said body, a. valve member having a face thereon adapted to engagethe seat surrounding said passage, a diaphragm subject to the opposing pressures of the fluid in the reservoir and'in said chamber, said diaphragm being adapted to engage said other seat and control the fiow of fluid from said reservoir to said chamber and to urge said valve member into engagement with the seat surrounding said release passage.
  • a drain valve device for a reservoir, in combination, a body having a chamber therein and having a release passage surrounded by a seat communicating with said chamber, 9. diaphragm subject to the opposing pressures of the fluid in the reservoir and in said chamber, a second seat on the body, said diaphragm controlling a passage surrounded by said second seat, a valve member carried by said diaphragm and having a face thereon adapted to engage the seat surrounding said release passage, and a strainer interposed between the reservoir and said second seat and adapted to remove foreign particles from the fluid under pressure flowing from said reservoir through the passage surrounded by said second seat.
  • a drain valve device for a reservoir, in combination, a body having a first chamber and a second chamber therein, a valve seat formed on the body between said chambers, a thin flexible valve adapted to cooperate with said seat, said thin flexible valve being subject on one side to the pressure of the fluid in the flrst chamber and subject on the other side to the fluid under pressure in the second chamber and operative upon an increase in pressure in said first chamber to a value exceeding the pressure of the fluid in the second chamber for opening a communication through which liquid accumulated in said reservoir may drain to said second chamber and through which fluid under pressure may be supplied to said second chamber, and operative upon a reduction in the pressure of the fluid in said first chamber to a value below the pressure of the fluid in said second chamber to close said communication and open another communication through which liquid may drain from said second chamber.
  • a drain valve device for a reservoir or the like, in combination, a body provided with two chambers and having an annular valve seat located between said chambers and also provided with a passage leading to the atmosphere. a valve normally closing said passage, and a thin flexible valve cooperating with said seat and subject to the opposing pressures in said chambers, and operative in response to an increase in the pressure in one 01' said chambers to establish a communication from said one chamber to the other chamber and operative upon substantially equalization of the pressures in the two chambers to close said communication, said thin flexible valve being further operative upon a decrease in the pressure of fluid in said one chamber to actuate said valve to open the passage leading to the atmosphere.

Description

Feb. 25, 1941. s AIKMAN 2,232,899
AUTOMATIC DRAIN VALVE DEVICE Filed April 28, 1959 i Will /77777172 I5 I9 I8 20 22 21 INVENTOR BURTON SAIKMAN ATTORN EY Patented Feb. 25, 1941 UNITED STATES PATENT OFFICE I 2,232,899 AUTOMATIC DRAIN VALVE DEVICE Application April 2a, 1939, Serial No. 270,524
5 Claims.
This invention relates to an automatic drain valve for use on a reservoir or receiver for fluid under pressure and which operates to release moisture from this receiver or reservoir.
In the operation of fluid pressure systems, such as fluid pressure brake systems, air from the atmosphere is compressed and is stored in a reservoir or receiver from which fluid is withdrawn during operation of the brake equipment. As a result ofthe supply of fluid under pressure to and the release of fluid under pressure from the reservoir, water is deposited in the reservoir and unless it is periodically drained away it accumulates in the reservoir and reduces its volume,
and also may freeze and cause injury to the equipment.
It is an object of this invention to provide valve means adapted to be employed to release liquid which accumulates in the reservoir of a 0 fluid pressure system.
Another object of the invention is to provide a valve device automatically operable in response to variations in the pressure of the fluid in a reservoir or receiver for controlling a communication through which liquid may be released from the reservoir or receiver.
A further object of the invention is to provide a valve device of the type described which releases fluid from the receiver in limited volumes so that the supply of fluid in the receiver will not be unduly depleted by operation of the valve device.
A still further objectof the invention is to provide a valve device of the type referred to which is of rugged construction, and in which the elements are of such design as not to be damaged, if water present in the device freezes.
It is still a further object of the invention to provide an improved automatic drain valve device.
Other objects of the invention and features of novelty will be apparent from the following description taken in connection with the accompanying drawing, the single figure of which is a sectional view showing a drain valve device embodying my invention.
Referring to the drawing, there is illustrated therein a portion of a receiver or reservoir I for a fluid pressure system which is supplied with fluid under pressure by a suitable compressor, not
shown, and from which fluid is withdrawn through a suitable pipe, not shown.
The drain valve device provided by my invention is mounted in a threaded opening in the lowermost portion of the reservoir or receiver I,
and, as shown, comprises a body casing 2, a strainer portion 3, a valve portion 4 and a cover portion 5.
The body casing 2 has a tubular threaded portion 8 adapted to be received by the threaded 5 opening in the reservoir I.
The body has an annular chamber 1 formed therein which is in constant communication with the reservoir I through said tubular portion 8. l The opposite end of the chamber is provided with a screw-threaded opening 8. At an intermediate point in the chamber I, an annular flange 9 is provided. A portion of this flange is adapted to form a valve seat II and a portion Ill above the valve seat is provided with screw- 15 threads.
The strainer portion 3 may comprise a cylindrical tubular wall member l2 made of perforated metal, such as, close mesh wire, which is closed at one end by a metal plate [3. The tubular 20 member is supported at the opposite end by a metal ring it which is provided with screwthreads on its outer circumference. Both of said parts l3 and I may be secured to the wall member l2 in any suitable manner. This strainer portion is screw-threaded into the threaded portion of flange 9 with the closed end projecting into the chamber I, asshown in the accompanying drawing.
The chamber I is closed by the cover portion 30 5 which is screw-threaded into the open end of the chamber 1 at 8.
The cover portion is provided with a chamber l5 into which one or more ribs 15 extend from the inside wall thereof and form a central boss 35 ll. At the bottom of the cover there is provided a release passage 22 which extends therethrough.
The valve portion 4 comprises a thin flexible diaphragm valve i9 interposed between the cham- 40 bers I and i5 and which is adapted to seat at its perimeter on the valve seat ll provided on the annular flange 9 in chamber 1. A valve stem I8 is secured at one end to the center of the diaphragm valve l9 and extends through an 45 opening in the boss H. The opposite end of the stem l8 has a substantially conical face thereon indicated at 20, which is adapted to seat upon a seat 2| formed on the cover 5 surrounding the release passage 22. l l
The length of the stem I8 is such that when the valve portion 4 is assembled in operative position, that is, with the conical valve face 20 of the stem l8 engaging the seat 2| and the outer periphery of the diaphragm l9 engaging 55 the seat II. the central portion of the diaphragm l9 will be flexed upwardly slightly into chamber 7, as shown in the drawing.
In initially charging the equipment, fluid under pressure is supplied to the reservoir I and it flows through the tubular portion 6 to the chamber 1 of the drain valve device. From this chamber fluid under pressure flows through the strainer member I2, which functions to remove foreign particles from the fluid passed therethrough, and thus prevents particles of dirt and dust from accumulating on the valve seat It. Thereby insuring that the diaphragm I9 will seat properly on said seat when it is so intended. After passing through the strainer the fluid under pressure exerts force on the upper face of the diaphragm I9 to flex it downwardly, away from the seat II.-
On downward flexing of the diaphragm I9, fluid under pressure flows past the valve seat II to the chamber I5 in the cover portion 5. This flow continues until the pressure in chamber I5 is substantially equal to the pressure of fluid in chamber 1 and in the reservoir I. During this chargi g period the face 20 on the end of the stem I is pressed more firmly into engagement with the seat on the cover surrounding the release passage 22, so that there is no escape of fluid to the atmosphere.
On an increase in the pressure of fluid in the chamber I5 to a pressure substantially equal to the pressure in the chamber 1 and the reservoir I, the force exerted by the fluid under pressure in the chamber I5, together with the force exerted by the diaphragm I9 overcomes the opposing force of the fluid under pressure in the chamber 1 and reservoir I on the opposite side of the diaphragm. When this occurs the diaphragm I9 is thereupon flexed upwardly until it seats on the seat II and cuts off the further supply of fluid under pressure from the chamber I and reservoir I to the chamber I5.
Any liquid which accumulates in the reservoir I flows by gravity to the lower portion thereof and through the passage in the tubular portion 8 to the chamber I of the drain valve. From thence it flows through the strainer member I2 to the upper face of the diaphragm I9.
On a subsequent reduction in the pressure of the fluid in the reservoir I as a result of the withdrawal of fluid therefrom, there is a reduction in the force exerted by this fluid on the upper side of the diaphragm I9 in opposition to the opposing force of the fluid in the chamber I 5 acting on the lower side of the diaphragm I 9. When this occurs the diaphragm I9 is thereupon flexed upwardly by the fluid under pressure in the chamber 5.
On this movement of the diaphragm I9, the face 20 on the end of the stem I8 is lifted away from the seat 2| surrounding the release passage 22 so as to release fluid from the chamber I5 and thereby reduce the pressure of fluid in this chamber.
On a reduction in pressure of the fluid in the chamber I5 to a value slightly below the pressure of the fluid in the reservoir I, the fluid under pres-- sure in the reservoir I flexes the diaphragm downwardly. This causes the valve face 20 on the end of stem I8 to move into engagement with the seat 2| on the cover, so as to cut oil the release of fluid from the chamber I5.
The volume of fluid released from the chamber I5 before the pressure of the fluid in this chamber is reduced to a value slightly below the pressure of the fluid in the reservoir is relatively maintain the diaphragm small because of the relatively small volume of the chamber I5.
On a subsequent increase in the pressure of the fluid in the reservoir I as a result of the supply of fluid thereto by operation of the compressor, the pressure of the fluid in the reservoir I and in the chamber I will exceed the pressure of the fluid in the chamber I5 on the opposite face of the diaphragm I 9. When the pressure of the fluid in the reservoir I and consequently in chamber 1 has increased to a value slightly above the pressure of the fluid in'the chamber I5, the force exerted on the upper face of the diaphragm by this fluid will exceed the opposing force exerted on the diaphragm by the fluid in chamber I5. Then the diaphragm I9 will flex downwardly against the opposing force of the pressure in chamber I5, while the valve face 20 on the end of the stem I8 is pressed more firmly into engagement with the seat surrounding the release passage 22.
On this flexing of the diaphragm I9 it is moved away from the seat II so as to permit liquid ac cumulated in the chamber above the diaphragm I9 to flow past the valve seat II to the chamber I5 at the opposite sides of the diaphragm. This liquid will flow past the seat into the chamber I5 until the pressure of the fluid trapped in the chamber I5 is increased substantially to the pressure of the fluid in the chamber 1 and reservoir I.
On an increase in the pressure of the fluid in chamber I5 substantially to the pressure of the fluid in the chamber I, the diaphragm I9 will be flexed upwardly by this fluid under pressure, until it engages the seat I I, to cut off the flow of fluid from the chamber I and reservoir I to the chamber I5.
On flexing of the diaphragm I9 upwardly into engagement with the seat II, the face 20 on the end of the stem I8 is held in engagement with the seat 2| surrounding the release passage 22 so as to cut oif the release of fluid from the chamber I5.
On a subsequent reduction in the pressure of the fluid in the reservoir I and chamber I to a predetermined value below the pressure of the fluid in the chamber I5, the force exerted by the fluid under pressure in the chamber 1 on the upper side of the diaphragm is insuflicient to hold this diaphragm against the opposing force of the fluid under pressure in the chamber I5. When this occurs the diaphragm is flexed upwardly and the stem I8 is lifted so that the valve face 20 on the stem I8 is out of engagement with the seat surrounding the release passage 22 and the liquid in the chamber I5 is forced out through the release passage 22 by the fluid under pressure trapped in said chamber.
After a predetermined amount of liquid is released from the chamber I5, the pressure of the fluid remaining in this chamber is insufilcient to I9 flexed upwardly against the opposing force of the fluid under pressure in the chamber 1 and reservoir I. At this time the diaphragm I9 is thereupon moved downwardly by the fluid under pressure in the chamber I until the valve face 20 on the end of the stem I8 engages the seat surrounding the passage 22 so as to cut oil the further release of fluid from the chamber I5.
On a subsequent increase in the pressure of the fluid in the reservoir I and connected chamber I, the diaphragm is flexed downwardly against the opposing force of the fluid under pressure in chamber |5. This permits the liquid which has accumulated in the chamber I on the upper face of the diaphragm. I9 to flow therefrom past the valve seat II to the chamber Hi to increase the pressure of the fluid in this chamber. When this pressure is increased substantially to the pressure of the fluid in chamber 1 and reservoir I, the diaphragm is thereafter again flexed upwardly until it engages theseat II.
On the next reduction in the.pressure. of the fluid in the reservoir l and connected chamber 1, the drain valve device operates as described in detail above to again release liquid from the chamber I5, and this cycle of operation is repeated on subsequent fluctuation in the pressure of the fluid in the reservoir I.
It will be seen that the volume of fluid, either liquid or gaseous, released by the drain valve device on each fluctuation of the pressure of the fluid in the reservoir is relatively small. Therefore, the fluid under pressure in the reservoir I will not be unduly depleted by operation of the drain valve device. The amount discharged by the drain valve device on each operation thereof is, however, proportioned so that the drain valve device is enabled to maintain the reservoir l substantially free from moisture.
It will be seen also that this drain valve device operates automatically in response to variations in the pressure of the fluid in reservoir I, and that it requires no attention on the part of the operator of the fluid pressure system with which it is associated.
While one embodiment of the improved automatic drain valve device provided by my in vention has been illustrated and described in detail, it should be understood that the invention is not limited to these details of construction, and that numerous changes and modifications may be made without departing from the scope of the following claims.
Having now described my invention, what I claim as new and desire to secure by Letters Patent is: I
1. In a drain valve device for a reservoir, in combination, a body having a first chamber and a second chamber therein and having a release passage surrounded by a seat and communicating with said second chamber, another seat associated with said body, a valve member having a face thereon adapted to engage the seat surrounding the release passage, a diaphragm subiect to the opposing pressures of the fluid in said first chamber and of the fluid in said second chamber adapted to engage said other seat to, control communication from said first chamber to said second'chamber and to urge said valve member into engagement with the seat surrounding said passage.
2. In a drain valve device for a reservoir, in combination, a body having a chamber therein and having a. release passage surrounded by a seat and communicating with said chamber, another seat associated with said body, a. valve member having a face thereon adapted to engagethe seat surrounding said passage, a diaphragm subject to the opposing pressures of the fluid in the reservoir and'in said chamber, said diaphragm being adapted to engage said other seat and control the fiow of fluid from said reservoir to said chamber and to urge said valve member into engagement with the seat surrounding said release passage.
3. In a drain valve device for a reservoir, in combination, a body having a chamber therein and having a release passage surrounded by a seat communicating with said chamber, 9. diaphragm subject to the opposing pressures of the fluid in the reservoir and in said chamber, a second seat on the body, said diaphragm controlling a passage surrounded by said second seat, a valve member carried by said diaphragm and having a face thereon adapted to engage the seat surrounding said release passage, and a strainer interposed between the reservoir and said second seat and adapted to remove foreign particles from the fluid under pressure flowing from said reservoir through the passage surrounded by said second seat.
4. In a drain valve device for a reservoir, in combination, a body having a first chamber and a second chamber therein, a valve seat formed on the body between said chambers, a thin flexible valve adapted to cooperate with said seat, said thin flexible valve being subject on one side to the pressure of the fluid in the flrst chamber and subject on the other side to the fluid under pressure in the second chamber and operative upon an increase in pressure in said first chamber to a value exceeding the pressure of the fluid in the second chamber for opening a communication through which liquid accumulated in said reservoir may drain to said second chamber and through which fluid under pressure may be supplied to said second chamber, and operative upon a reduction in the pressure of the fluid in said first chamber to a value below the pressure of the fluid in said second chamber to close said communication and open another communication through which liquid may drain from said second chamber.
5. In a drain valve device for a reservoir or the like, in combination, a body provided with two chambers and having an annular valve seat located between said chambers and also provided with a passage leading to the atmosphere. a valve normally closing said passage, and a thin flexible valve cooperating with said seat and subject to the opposing pressures in said chambers, and operative in response to an increase in the pressure in one 01' said chambers to establish a communication from said one chamber to the other chamber and operative upon substantially equalization of the pressures in the two chambers to close said communication, said thin flexible valve being further operative upon a decrease in the pressure of fluid in said one chamber to actuate said valve to open the passage leading to the atmosphere.
' BURTON S. AI'KMAN.
US270524A 1939-04-28 1939-04-28 Automatic drain valve device Expired - Lifetime US2232899A (en)

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Cited By (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2579008A (en) * 1948-05-24 1951-12-18 Shell Dev Interpolymers of unsaturated nitriles
US2627869A (en) * 1944-10-18 1953-02-10 Edward J Whalen Automatic drain valve for air lines
US2662544A (en) * 1950-02-11 1953-12-15 Axel W Hall Drain valve mechanism for fluid pressure systems
US3036592A (en) * 1959-02-16 1962-05-29 Garrett Corp Valve assembly
US3130741A (en) * 1960-11-25 1964-04-28 White S Dental Mfg Co Liquid purging systems
US3516430A (en) * 1967-12-08 1970-06-23 Bendix Westinghouse Automotive Automatic drain valve
US3658085A (en) * 1969-09-02 1972-04-25 Joseph L Cannella Automatic reservoir drain valve
US3817267A (en) * 1971-09-30 1974-06-18 Norgren Co C A Valve device for draining liquid contaminant collected from compressed gas
US4922947A (en) * 1987-07-28 1990-05-08 Abx Automatic membrane drain device for pneumatic circuits
US20070209705A1 (en) * 2006-03-07 2007-09-13 Nichols Randall W Drain valve

Cited By (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2627869A (en) * 1944-10-18 1953-02-10 Edward J Whalen Automatic drain valve for air lines
US2579008A (en) * 1948-05-24 1951-12-18 Shell Dev Interpolymers of unsaturated nitriles
US2662544A (en) * 1950-02-11 1953-12-15 Axel W Hall Drain valve mechanism for fluid pressure systems
US3036592A (en) * 1959-02-16 1962-05-29 Garrett Corp Valve assembly
US3130741A (en) * 1960-11-25 1964-04-28 White S Dental Mfg Co Liquid purging systems
US3516430A (en) * 1967-12-08 1970-06-23 Bendix Westinghouse Automotive Automatic drain valve
US3658085A (en) * 1969-09-02 1972-04-25 Joseph L Cannella Automatic reservoir drain valve
US3817267A (en) * 1971-09-30 1974-06-18 Norgren Co C A Valve device for draining liquid contaminant collected from compressed gas
US4922947A (en) * 1987-07-28 1990-05-08 Abx Automatic membrane drain device for pneumatic circuits
US20070209705A1 (en) * 2006-03-07 2007-09-13 Nichols Randall W Drain valve

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