Air purged optical densitometer

US 7,319,524 B2
Filed: 03/28/2005
Issued: 01/15/2008
Est. Priority Date: 03/28/2005
Status: Expired due to Fees

First Claim

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1. An optical densitometer, comprising:

an optical emitter configured to emit a light beam along an optical axis, the light beam having an optical intensity;

an optical receiver spaced-apart from the optical emitter and configured to receive at least a portion of the emitted light beam, the optical receiver operable, upon receipt of the emitted light beam, to supply a signal representative of the optical intensity of the received light beam; and

an optical path purge device positioned between the optical emitter and the optical receiver, the optical path purge device including;

a first optical port, a second optical port, and an optical passageway extending therebetween, the first and second optical ports and the optical passageway all disposed at least partially along the optical axis to thereby allow light beam transmission therethrough,a purge gas inlet port, a purge gas exhaust port, and a purge gas flow passage extending therebetween, the purge gas inlet port adapted to receive a flow of purge gas having a first fluid velocity, the purge gas flow passage in fluid communication with the optical passageway and disposed at least substantially transverse thereto, the purge gas flow passage configured, upon the purge gas flowing therethrough, to create a differential pressure between the purge gas flow passage and the first and second optical ports that draws gas into the optical passageway via the first and second optical ports,a purge gas inlet section including the purge gas inlet port, a purge gas outlet port, and a purge gas flow passage extending therebetween, the purge gas flow passage configured to increase the fluid velocity of the purge gas flowing therethrough, the purge gas outlet port in fluid communication with the optical passageway and disposed relative thereto such that the increased fluid velocity purge gas exits therefrom substantially transverse to the optical axis, andan exhaust section including an inlet port, the purge gas exhaust port, and an exhaust flow passage extending therebetween, the inlet port in fluid communication with the optical passageway and disposed relative thereto such that at least a portion of the increased fluid velocity purge gas flows through the inlet port and into the exhaust flow passage, the inlet port and at least a portion of the exhaust flow passage forming a venturi throat, whereby the differential pressure is created upon increased fluid velocity purge gas flowing therethrough.

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Abstract

An advanced gas purged optical densitometer that significantly decreases the likelihood of optical component contamination and unstable optical path reduction includes an optical emitter, an optical receiver, and an optical path purge device. The optical emitter emits a light beam along an optical axis, through the optical purge path device and a test fluid. The optical receiver receives the light beam after it traverses the optical path purge device and the test fluid, and supplies a signal representative of intensity of the received light beam. The optical path purge device is configured to prevent contamination of the optical emitter and optical receiver, and to maintain a substantially optical path length of the test fluid.

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18 Claims

1. An optical densitometer, comprising:
- an optical emitter configured to emit a light beam along an optical axis, the light beam having an optical intensity;
  
  an optical receiver spaced-apart from the optical emitter and configured to receive at least a portion of the emitted light beam, the optical receiver operable, upon receipt of the emitted light beam, to supply a signal representative of the optical intensity of the received light beam; and
  
  an optical path purge device positioned between the optical emitter and the optical receiver, the optical path purge device including;
  
  a first optical port, a second optical port, and an optical passageway extending therebetween, the first and second optical ports and the optical passageway all disposed at least partially along the optical axis to thereby allow light beam transmission therethrough,a purge gas inlet port, a purge gas exhaust port, and a purge gas flow passage extending therebetween, the purge gas inlet port adapted to receive a flow of purge gas having a first fluid velocity, the purge gas flow passage in fluid communication with the optical passageway and disposed at least substantially transverse thereto, the purge gas flow passage configured, upon the purge gas flowing therethrough, to create a differential pressure between the purge gas flow passage and the first and second optical ports that draws gas into the optical passageway via the first and second optical ports,a purge gas inlet section including the purge gas inlet port, a purge gas outlet port, and a purge gas flow passage extending therebetween, the purge gas flow passage configured to increase the fluid velocity of the purge gas flowing therethrough, the purge gas outlet port in fluid communication with the optical passageway and disposed relative thereto such that the increased fluid velocity purge gas exits therefrom substantially transverse to the optical axis, andan exhaust section including an inlet port, the purge gas exhaust port, and an exhaust flow passage extending therebetween, the inlet port in fluid communication with the optical passageway and disposed relative thereto such that at least a portion of the increased fluid velocity purge gas flows through the inlet port and into the exhaust flow passage, the inlet port and at least a portion of the exhaust flow passage forming a venturi throat, whereby the differential pressure is created upon increased fluid velocity purge gas flowing therethrough.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11)
- - 2. The densitometer of claim 1, further comprising:
    - an emitter chamber at least partially enclosing the optical emitter and including at least a fluid inlet port and a fluid outlet port, the emitter chamber fluid inlet port adapted to receive a flow of relief gas, the emitter chamber fluid outlet port in fluid communication with the optical path purge device first optical port.
  - 3. The densitometer of claim 1, further comprising:
    - a receiver chamber at least partially enclosing the optical receiver and including at least a fluid inlet port and a fluid outlet port, the receiver chamber fluid inlet port adapted to receive a flow of relief gas, the receiver chamber fluid outlet port in fluid communication with the optical path purge device optical passageway, whereby the light beam passes through the receiver chamber fluid outlet port.
  - 4. The densitometer of claim 1, further comprising:
    - an environmental chamber disposed between the optical emitter and the optical receiver, the environmental chamber including an inner surface that defines a volume in which a measurement gas is disposed, a purge gas inlet port, a first relief gas inlet port, and a second relief gas inlet port, the purge gas inlet port in fluid communication with the optical path purge device purge gas inlet port and adapted to receive the flow of purge gas, the first and second relief gas inlet ports in fluid communication with the optical path purge device optical passageway, whereby the light beam passes through the environmental passageway.
  - 5. The densitometer of claim 1, further comprising:
    - a second optical path purge device positioned between the optical emitter and the optical receiver, the second optical path purge device including;
      
      a first optical port, a second optical port, and an optical passageway extending therebetween along the optical axis, whereby the light beam passes through the optical passageway, anda purge gas inlet port, a purge gas exhaust port, and a purge gas flow passage extending therebetween, the purge gas inlet port adapted to receive a flow of purge gas, the purge gas flow passage in fluid communication with the optical passageway and disposed substantially transverse thereto, the purge gas flow passage configured, upon the purge gas flowing therethrough, to create a differential pressure between the purge gas flow passage and the first and second optical ports.
  - 6. The densitometer of claim 5, wherein the second optical path purge device further comprises:
    - a purge gas inlet section including the purge gas inlet port, a purge gas outlet port, and a purge gas flow passage extending therebetween, the purge gas flow passage configured to increase the fluid velocity of the purge gas flowing therethrough, the purge gas outlet port in fluid communication with the optical passageway and disposed relative thereto such that the increased fluid velocity purge gas exits therefrom substantially transverse to the optical axis; and
      
      an exhaust section including an inlet port, the purge gas exhaust port, and an exhaust flow passage extending therebetween, the inlet port in fluid communication with the optical passageway and disposed relative thereto such that at least a portion of the increased fluid velocity purge gas flows through the inlet port and into the exhaust flow passage, the inlet port and at least a portion of the exhaust flow passage forming a venturi throat, whereby the differential pressure is created upon increased fluid velocity purge gas flowing therethrough.
  - 7. The densitometer of claim 5, further comprising:
    - an emitter chamber at least partially enclosing the optical emitter and including at least a relief gas inlet port and a relief gas outlet port, the emitter chamber relief gas inlet port adapted to receive a flow of relief gas, the emitter chamber relief gas outlet port in fluid communication with the optical path purge device first optical port; and
      
      a receiver chamber at least partially enclosing the optical receiver and including at least a relief gas inlet port and a relief gas outlet port, the receiver chamber relief gas inlet port adapted to receive a flow of relief gas, the receiver chamber relief gas outlet port in fluid communication with the second optical path purge device first optical port.
  - 8. The densitometer of claim 7, wherein the differential pressure draws the flow of relief gas into the emitter and receiver chambers, and into the optical purge device first optical ports.
  - 9. The densitometer of claim 7, further comprising:
    - an environmental chamber disposed between the emitter chamber and the receiver chamber and at least partially enclosing the optical purge devices, the environmental chamber including an inner surface that defines a volume in which a measurement gas is disposed, the environmental chamber further including first and second purge gas inlet ports, each purge gas inlet port in fluid communication with one of the optical path purge device purge gas inlet ports and adapted to receive the flow of purge gas at the first fluid velocity.
  - 10. The densitometer of claim 9, wherein the environmental chamber further includes first and second purge gas outlet ports, each purge gas outlet port in fluid communication with one of the optical path purge device exhaust section exhaust ports.
  - 11. The densitometer of claim 10, wherein the differential pressure draws:
    - (i) the flow of relief gas into the emitter and receiver chambers, and into the optical purge device first optical ports; and
      
      (ii) a portion of the measurement gas into each of the optical purge device second optical ports.

12. An optical densitometer, comprising:
- an optical emitter configured to emit a light beam along an optical axis, the light beam having an optical intensity;
  
  an optical receiver spaced-apart from the optical emitter and configured to receive at least a portion of the emitted light beam, the optical receiver operable, upon receipt of the emitted light beam, to supply a signal representative of the optical intensity of the received light beam;
  
  first and second optical path purge devices positioned between the optical emitter and the optical receiver, each optical path purge device including;
  
  a first optical port, a second optical port, and an optical passageway extending therebetween, the first and second optical ports and the optical passageway all disposed at least partially along the optical axis to thereby allow light beam transmission therethrough,a purge gas inlet port, a purge gas exhaust port, and a purge gas flow passage extending therebetween, the purge gas inlet port adapted to receive a flow of purge gas having a first fluid velocity, the purge gas flow passage in fluid communication with the optical passageway and disposed at least substantially transverse thereto, the purge gas flow passage configured, upon the purge gas flowing therethrough, to create a differential pressure between the purge gas flow passage and the first and second optical ports that draws gas into the optical passageway via the first and second optical ports,a purge gas inlet section including the purge gas inlet port, a purge gas outlet port, and a purge gas flow passage extending therebetween, the purge gas flow passage configured to increase the fluid velocity of the purge gas flowing therethrough, the purge gas outlet port in fluid communication with the optical passageway and disposed relative thereto such that the increased fluid velocity purge gas exits therefrom substantially transverse to the optical axis, andan exhaust section including an inlet port, the purge gas exhaust port, and an exhaust flow passage extending therebetween, the inlet port in fluid communication with the optical passageway and disposed relative thereto such that at least a portion of the increased fluid velocity purge gas flows through the inlet port and into the exhaust flow passage, the inlet port and at least a portion of the exhaust flow passage forming a venturi throat, whereby the differential pressure is created upon increased fluid velocity purge gas flowing therethrough.
- View Dependent Claims (13, 14, 15, 16)
- - 13. The densitometer of claim 12, further comprising:
    - an environmental chamber disposed between the emitter chamber and the receiver chamber and at least partially enclosing the optical purge devices, the environmental chamber including an inner surface that defines a volume in which a measurement gas is disposed, the environmental chamber further including first and second purge gas inlet ports, each purge gas inlet port in fluid communication with one of the optical path purge device purge gas inlet ports and adapted to receive the flow of purge gas.
  - 14. The densitometer of claim 13, wherein the environmental chamber further includes first and second purge gas outlet ports, each purge gas outlet port in fluid communication with one of the optical path purge device purge gas exhaust ports.
  - 15. The densitometer of claim 13, further comprising:
    - an emitter chamber at least partially enclosing the optical emitter and including at least a relief gas inlet port and a relief gas outlet port, the emitter chamber relief gas inlet port adapted to receive a flow of relief gas, the emitter chamber relief gas outlet port in fluid communication with the optical path purge device first optical port; and
      
      a receiver chamber at least partially enclosing the optical receiver and including at least a relief gas inlet port and a relief gas outlet port, the receiver chamber relief gas inlet port adapted to receive a flow of relief gas, the receiver chamber relief gas outlet port in fluid communication with the second optical path purge device first optical port.
  - 16. The densitometer of claim 15, wherein the differential pressure draws:
    - (i) the flow of relief gas into the emitter and receiver chambers, and into the optical purge device first optical ports; and
      
      (ii) a portion of the measurement gas into each of the optical purge device second optical ports.

17. An optical densitometer, comprising:
- an optical emitter configured to emit a light beam along an optical axis, the light beam having an optical intensity;
  
  an optical receiver spaced-apart from the optical emitter and configured to receive at least a portion of the emitted light beam, the optical receiver operable, upon receipt of the emitted light beam, to supply a signal representative of the optical intensity of the received light beam;
  
  an emitter chamber at least partially enclosing the optical emitter and including at least a relief gas inlet port and a relief gas outlet port, the emitter chamber relief gas inlet port adapted to receive a flow of relief gas;
  
  a receiver chamber at least partially enclosing the optical receiver and including at least a relief gas inlet port and a relief gas outlet port, the receiver chamber relief gas inlet port adapted to receive a flow of relief gas;
  
  first and second optical path purge devices positioned between the emitter and receiver chambers, each optical path purge device including;
  
  a first optical port, a second optical port, and an optical passageway extending therebetween, the first and second optical ports and the optical passageway all disposed at least partially along the optical axis to thereby allow light beam transmission therethrough,a purge gas inlet section including a purge gas inlet port, a purge gas outlet port, and a purge gas flow passage extending therebetween, the purge gas inlet port adapted to receive a flow of purge gas at a fluid velocity, the purge gas flow passage configured to increase the fluid velocity of the purge gas flowing therethrough, the purge gas outlet port in fluid communication with the optical passageway and disposed relative thereto such that the increased fluid velocity purge gas exits therefrom at least substantially transverse to the optical axis, andan exhaust section including an inlet port, an exhaust port, and an exhaust flow passage extending therebetween, the inlet port in fluid communication with the optical passageway and disposed relative thereto such that at least a portion of the increased fluid velocity purge gas flows through the inlet port and into the exhaust flow passage, the inlet port and at least a portion of the exhaust flow passage forming a venturi throat, whereby, upon the increased fluid velocity purge gas flowing therethrough, a differential pressure is created between the purge gas flow passage and the first and second optical ports.
- View Dependent Claims (18)
- - 18. The densitometer of claim 17, further comprising:
    - an environmental chamber disposed between the emitter chamber and the receiver chamber and at least partially enclosing the optical purge devices, the environmental chamber including;
      
      an inner surface that defines a volume in which a measurement gas is disposed,first and second purge gas inlet ports, each purge gas inlet port in fluid communication with one of the optical path purge device purge gas inlet ports and adapted to receive the flow of purge gas at the first flow velocity, andfirst and second purge gas outlet ports, each purge gas outlet port in fluid communication with one of the optical path purge device exhaust section exhaust ports,wherein the differential pressure draws;
      
      (i) the flow of relief gas into the emitter and receiver chambers, and into the optical purge device first optical ports; and
      
      (ii) a portion of the measurement gas into each of the optical purge device second optical ports.

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Current Assignee
Honeywell International Inc.
Original Assignee
Honeywell International Inc.
Inventors
Friedrichs, Hans P.
Primary Examiner(s)
Nguyen; Sang H.

Application Number

US11/092,471
Publication Number

US 20060215163A1
Time in Patent Office

1,023 Days
Field of Search

356432-439, 356/443, 356/446, 356/326, 250/343, 250351-353, 250/228, 250/564, 250/573
US Class Current

356/438
CPC Class Codes

G01N 2021/151   Gas blown

G01N 21/15   Preventing contamination of...

G01N 21/534   by measuring transmission a...

Air purged optical densitometer

First Claim

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Abstract

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18 Claims

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Air purged optical densitometer

First Claim

1 Assignment

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Abstract

31 Citations

18 Claims

Specification

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