Method and apparatus for self-contained anesthetic gas reclamation

US 7,644,594 B2
Filed: 05/11/2006
Issued: 01/12/2010
Est. Priority Date: 05/13/2005
Status: Active Grant

First Claim

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1. A method of removing and separating gaseous anesthetics from a waste anesthetic gas stream to prevent atmospheric venting of gaseous anesthetics from a healthcare facility, said method comprising the steps of:

receiving said waste anesthetic gas stream from an anesthetizing machine (312, 612) into a chamber (332, 632),detecting a presence of said waste anesthetic gas stream received in said chamber,periodically fluidly coupling said chamber to a collection intake (316, 616) by a selectively isolable flow path (334, 634) in response to said presence of said waste anesthetic gas stream received in said chamber,transferring said waste anesthetic gas stream received in said chamber to said collection intake by said selectively isolable flow path, whereby said chamber and said selectively isolable flow path cooperate to minimize ingress of atmospheric gas into said collection intake when no waste anesthetic gas stream is exiting said anesthetizing machine,cooling said waste anesthetic gas stream transferred to said collection intake by passing said waste anesthetic gas stream over a cooling surface (236, 436A, 436B, 536) characterized by a surface temperature gradient such that said waste anesthetic gas stream passes thereover in a direction from a warmer to a colder temperature, said waste anesthetic gas stream exchanging heat conductively through said cooling surface with a heat transfer fluid, said heat transfer fluid being warmed by said exchange of heat with said waste anesthetic gas stream, said heat transfer fluid being cooled by a refrigeration unit (270, 370, 570, 670),condensing said gaseous anesthetics from said waste anesthetic gas stream,separating said condensed anesthetics from said waste anesthetic gas stream,venting to atmosphere said waste anesthetic gas stream absent said condensed anesthetics.

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Abstract

A method and apparatus are disclosed for recovering and separating anesthetic gas components from waste anesthetic gases to be purged from a healthcare facility. With minimal reliance on the utility infrastructure and supplies of a healthcare facility, the method and apparatus needs only electrical or mechanical power, a source of waste anesthetic gases, and an atmospheric vent in order to operate. A heat exchanger/condenser, which uses a dedicated heat transfer fluid as a refrigerant, is employed to condense anesthetic gas components from the waste anesthetic gases as either liquid condensates or solid frosts. The warmed heat transfer fluid is cooled in a separate refrigeration unit and recycled back to the heat exchanger/condenser. A preferred embodiment of the invention is a self-contained, packaged unit which can be easily accommodated in a physician'"'"'s office, small animal clinic, dental office or other healthcare facility requiring effective waste anesthetic gas management.

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20 Claims

1. A method of removing and separating gaseous anesthetics from a waste anesthetic gas stream to prevent atmospheric venting of gaseous anesthetics from a healthcare facility, said method comprising the steps of:
- receiving said waste anesthetic gas stream from an anesthetizing machine (312, 612) into a chamber (332, 632),detecting a presence of said waste anesthetic gas stream received in said chamber,periodically fluidly coupling said chamber to a collection intake (316, 616) by a selectively isolable flow path (334, 634) in response to said presence of said waste anesthetic gas stream received in said chamber,transferring said waste anesthetic gas stream received in said chamber to said collection intake by said selectively isolable flow path, whereby said chamber and said selectively isolable flow path cooperate to minimize ingress of atmospheric gas into said collection intake when no waste anesthetic gas stream is exiting said anesthetizing machine,cooling said waste anesthetic gas stream transferred to said collection intake by passing said waste anesthetic gas stream over a cooling surface (236, 436A, 436B, 536) characterized by a surface temperature gradient such that said waste anesthetic gas stream passes thereover in a direction from a warmer to a colder temperature, said waste anesthetic gas stream exchanging heat conductively through said cooling surface with a heat transfer fluid, said heat transfer fluid being warmed by said exchange of heat with said waste anesthetic gas stream, said heat transfer fluid being cooled by a refrigeration unit (270, 370, 570, 670),condensing said gaseous anesthetics from said waste anesthetic gas stream,separating said condensed anesthetics from said waste anesthetic gas stream,venting to atmosphere said waste anesthetic gas stream absent said condensed anesthetics.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 19)
- - 2. The method of claim 1 further comprising the step of:
    - compressing said waste anesthetic gas stream to a pressure above atmospheric pressure using a compressor (342, 642) with at least one compression stage.
  - 3. The method of claim 1 wherein said step of condensing said gaseous anesthetics from said waste anesthetic gas stream is conducted at a pressure and temperature to cause said gaseous anesthetics to be condensed as liquids.
  - 4. The method of claim 1 wherein said step of condensing said gaseous anesthetics from said waste anesthetic gas stream is conducted at a pressure and temperature to cause said gaseous anesthetics to be condensed as solids.
  - 5. The method of claim 4 wherein said condensing gaseous anesthetics undergo desublimation onto an outer surface of said cooling surface (236, 536) such that said gaseous anesthetics with a higher desublimation point deposit on a warmer portion (560, 562) of said cooling surface (236, 536) and said gaseous anesthetics with a lower desublimation point deposit on a colder portion (563, 564) of said cooling surface (236, 536).
  - 6. The method of claim 5 further comprising the step of:
    - heating said cooling surface (236, 536) to selectively remove solid anesthetics thereon as liquid anesthetics such that said liquid anesthetics are sequentially separated and collected based upon melt point temperature.
  - 7. The method of claim 2 further comprising the steps of:
    - expanding said waste anesthetic gas stream through an expansion valve (643) prior to atmospheric venting thereof, andcollecting in a receiver (645) liquefied anesthetic components condensed by expanding said waste anesthetic gas stream through said expansion valve.
  - 8. The method of claim 2 further comprising the steps of:
    - expanding said waste anesthetic gas stream through a turbine (344) prior to atmospheric venting thereof, andcollecting in a receiver (345) liquefied anesthetic components condensed by expanding said waste anesthetic gas stream through said turbine.
  - 19. The method of claim 1 wherein said step of condensing said gaseous anesthetics from said waste anesthetic gas stream is conducted at a pressure and temperature to cause at least one of said gaseous anesthetics to be condensed as a solid.

9. A system for preventing atmospheric venting of anesthetic gas components of waste anesthetic gas from a healthcare facility, said system comprising:
- a chamber (332, 632) for receiving said waste anesthetic gas from an anesthetizing machine (312, 612),a detector (340, 640) for detecting a presence of said waste anesthetic gas received in said chamber,an exhaust valve (334, 634) arranged and designed to periodically fluidly couple said chamber to a collection intake (316, 616) in response to said presence of said waste anesthetic gas received in said chamber when detected by said detector, whereby said chamber and said exhaust valve cooperate to minimize ingress of atmospheric gas into said collection intake when no said waste anesthetic gas is exiting said anesthetizing machine,said collection intake (316, 616) arranged and designed to draw said waste anesthetic gas from said chamber via said exhaust valve into a flow line (239, 339, 439, 539, 639),a heat exchanger/condenser (222, 322, 422, 522, 622) arranged and designed to remove said anesthetic gas components from said waste anesthetic gas, said heat exchanger/condenser having an inlet fluidly coupled to said flow line (239, 339, 439, 539, 639) and an outlet fluidly coupled to an atmospheric vent line, said heat exchanger/condenser also having a cooling coil (236, 436A, 436B, 536) positioned therein with an outlet of said cooling coil fluidly coupled to a heat transfer fluid flow line (227, 337, 427, 527, 627), said cooling coil having an inlet and providing a cooling surface characterized by a surface temperature gradient,said heat exchanger/condenser having at least one vessel (224, 324, 424, 524A, 524B, 624) for collecting liquefied anesthetic components removed from said waste anesthetic gas within said heat exchanger/condenser, anda refrigeration unit (270, 370, 570, 670) having an inlet fluidly coupled to said heat transfer fluid flow line (227, 327, 427, 527, 627) from said outlet of said cooling coil and an outlet fluidly coupled via another heat transfer fluid flow line (221, 321, 421, 521, 621) to said inlet of said cooling coil, said refrigeration unit for cooling a heat transfer fluid flowing through said cooling coil.
- View Dependent Claims (10, 11, 12, 13, 14)
- - 10. The system of claim 9 wherein said refrigeration unit (270, 370, 570, 670) further comprises:
    - a compressor (272) for compressing said heat transfer fluid,a heat exchanger (274), said heat exchanger using a coolant to cool said compressed heat transfer fluid, andan expansion valve (276) for decompressing said heat transfer fluid.
  - 11. The system of claim 9 wherein said heat exchanger/condenser (222, 322, 422, 522, 622) further comprises:
    - a first heat exchanger/condenser stage (422A) having an inlet fluidly coupled to said flow line (239, 339, 439, 539, 639) and an outlet, said first heat exchanger/condenser stage having a first cooling coil (436A) positioned therein with an outlet of said first cooling coil fluidly coupled to said heat transfer fluid flow line (227, 327, 427, 527, 627) to said refrigeration unit (270, 370, 570, 670), said first cooling coil (436A) having an inlet, anda second heat exchanger/condenser stage (422B) having an inlet which is fluidly coupled to said outlet of said first heat exchanger/condenser stage (422A) and an outlet fluidly coupled to said atmospheric vent line, said second heat exchanger/condenser stage also having a second cooling coil (436B) positioned therein with an outlet of said second cooling coil fluidly coupled to said inlet of said first cooling coil (436A) and an inlet of said second cooling coil fluidly coupled to said another heat transfer fluid flow line (221, 321, 421, 521, 621) from said refrigeration unit (270, 370, 570, 670).
  - 12. The system of claim 9 further comprising:
    - a compressor (342, 642) having at least one compression stage for elevating said waste anesthetic gas to a pressure higher than atmospheric pressure.
  - 13. The system of claim 12 further comprising:
    - an expansion valve (643) fluidly coupled to said outlet of said heat exchanger/condenser (222, 322, 422, 522, 622), said expansion valve (643) for reducing pressure of waste gas to be vented, anda receiver (645) fluidly coupled between said expansion valve (643) and said atmospheric vent line (646), said receiver (645) for collecting liquefied anesthetic components condensed by reducing said pressure of said waste gas.
  - 14. The system of claim 12 further comprising:
    - a turbine (344) fluidly coupled to said outlet of said heat exchanger/condenser (222, 322, 422, 522, 622), said turbine (344) for reducing pressure of waste gas to be vented, anda receiver (345) fluidly coupled between said turbine (344) and said atmospheric vent line (346), said receiver (345) for collecting liquefied anesthetic components condensed by reducing said pressure of said waste gas.

15. A system for preventing atmospheric venting of anesthetic gas components of waste anesthetic gas from a healthcare facility, said system comprising:
- a chamber (332, 632) for receiving said waste anesthetic gas from an anesthetizing machine (312, 612),a detector (340, 640) for detecting any presence of said waste anesthetic gas received in said chamber,an exhaust valve (334, 634) arranged and designed to periodically fluidly couple said chamber to a collection intake (316, 616) in response to said presence of said waste anesthetic gas received in said chamber when detected by said detector, whereby said chamber and said exhaust valve cooperate to minimize ingress of atmospheric gas into said collection intake when no said waste anesthetic gas is exiting said anesthetizing machine,said collection intake (316, 616) arranged and designed to receive said waste anesthetic gas from said chamber via said exhaust valve, said collection intake fluidly coupled to a flow line (239, 339, 439, 539, 639),a first stage (422A) of a heat exchanger/condenser (222, 322, 422, 522, 622) having an inlet fluidly coupled to said flow line (239, 339, 439, 539, 639) and an outlet, said first stage also having a first cooling coil (436A) positioned therein with an outlet of said first cooling coil fluidly coupled to a heat transfer fluid flow line (227, 327, 427, 527, 627), said first cooling coil (436A) having an inlet,a second stage (422B) of said heat exchanger/condenser (222, 322, 422, 522, 622) having an inlet fluidly coupled to said outlet of said first stage (422A) and an outlet fluidly coupled to an atmospheric vent line, said second stage having a second cooling coil (436B) positioned therein with an outlet of said second cooling coil fluidly coupled to said inlet of said first cooling coil (436A) and an inlet, said first and second cooling coils providing a cooling surface characterized by a surface temperature gradient,said heat exchanger/condenser arranged and designed to remove said anesthetic gas components from said waste anesthetic gas, said heat exchanger/condenser having at least one vessel (224, 324, 424, 524A, 524B, 624) for collecting liquefied anesthetic components removed from said waste anesthetic gas within said heat exchanger/condenser, anda refrigeration unit (270, 370, 570, 670) having an inlet fluidly coupled to said heat transfer fluid flow line (227, 327, 427, 527, 627) from said outlet of said first cooling coil and an outlet fluidly coupled via another heat transfer fluid flow line (221, 321, 421, 521, 621) to said inlet of said second cooling coil, said refrigeration unit for cooling a heat transfer fluid flowing through said first and second cooling coils.
- View Dependent Claims (16, 17, 18, 20)
- - 16. The system of claim 15 further comprising:
    - a compressor (342, 642) having at least one compression stage for elevating said waste anesthetic gas to a pressure higher than atmospheric pressure.
  - 17. The system of claim 16 further comprising:
    - an expansion valve (643) fluidly coupled to said outlet of said second stage (422B) of said heat exchanger/condenser (222, 322, 422, 522, 622), said expansion valve (643) for reducing pressure of waste gas to be vented, anda receiver (645) fluidly coupled between said expansion valve (643) and said atmospheric vent line (646), said receiver (645) for collecting liquefied anesthetic components condensed by reducing said pressure of said waste gas.
  - 18. The system of claim 16 further comprising:
    - a turbine (344) fluidly coupled to said outlet of said second stage (422B) of said heat exchanger/condenser (222, 322, 422, 522, 622), said turbine (344) for reducing pressure of waste gas to be vented, anda receiver (345) fluidly coupled between said turbine (344) and said atmospheric vent line (346), said receiver (345) for collecting liquefied anesthetic components condensed by reducing said pressure of said waste gas.
  - 20. The system of claim 15 wherein said refrigeration unit (270, 370, 570, 670) further comprises:
    - a compressor (272) for compressing said heat transfer fluid,a heat exchanger (274), said heat exchanger using a coolant to cool said compressed heat transfer fluid, andan expansion valve (276) for decompressing said heat transfer fluid.

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Current Assignee
Anesthetic Gas Reclamation LLC
Original Assignee
Anesthetic Gas Reclamation LLC
Inventors
Berry, James M., Morris, Steve
Primary Examiner(s)
DOERRLER, WILLIAM CHARLES

Application Number

US11/432,192
Publication Number

US 20060254590A1
Time in Patent Office

1,342 Days
Field of Search

626/37, 626/17, 625/32, 128/200.24, 128/200.16, 128/203.25, 128/205.12, 423/235
US Class Current

62/617
CPC Class Codes

A61M 16/009   Removing used or expired ga...

A61M 16/0093   by adsorption, absorption o...

A61M 2202/0007   introduced into the body

A61M 2202/0208   Oxygen

A61M 2202/03   Gases in liquid phase, e.g....

A61M 2205/3606   cooled

Method and apparatus for self-contained anesthetic gas reclamation

First Claim

1 Assignment

0 Petitions

Accused Products

Abstract

103 Citations

20 Claims

Specification

Solutions

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Method and apparatus for self-contained anesthetic gas reclamation

First Claim

1 Assignment

Subscription Required

Subscription Required

0 Petitions

Subscription Required

Accused Products

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Abstract

103 Citations

20 Claims

Specification

Subscription Required

Solutions

Use Cases

Quick Links