Multiple-channel uv spectrometer assembly

Title: Multiple-channel uv spectrometer assembly

Brief Patent Description - Full Patent Description - Patent Claims

The Patent Description & Claims data below is from USPTO Patent Application 20060082769, Multiple-channel uv spectrometer assembly.

1. A multiple-channel spectrometer assembly for analyzing a plurality of sample flows, comprising: a plurality of spectrometer channels each being fluidly connectable to a respective one of the plurality of sample flows, each channel having: a sample inlet and a sample outlet connectable to a respective one of the sample flows; a chassis; a light source having a light outlet portion; a spectrometer module mounted to the chassis and optically aligned with the light source, the spectrometer module having an optical inlet axially aligned with the light outlet portion of the light source; and a flow cell assembly adjacent to the chassis intermediate the light source and the spectrometer module, the flow cell having a flow passageway in fluid communication with the sample inlet and sample outlet and configured to receive one of the plurality of sample flows therethrough, the flow passageway being positioned between the light source and the spectrometer, the flow all assembly being configured to direct light from the light source toward the spectrometer module as the sample flow moves through the flow passageway; and a signal processor coupled to each of the spectrometer modules and configured to receive data from each spectrometer module.

2. The spectrometer assembly of claim 1 further comprising a housing, and the plurality of the spectrometer channels are contained in the housing.

3. The spectrometer assembly of claim 1 further comprising a single power module coupled to each of the plurality of spectrometer channels and to the signal processor.

4. The spectrometer assembly of claim 1 wherein the signal processor includes an analog-to-digital converter.

5. The spectrometer assembly of claim 1 wherein the plurality of spectrometer channels includes a master spectrometer channel with the signal processor connected thereto, and a plurality of subsidiary channels separate from the master channel and the signal processor.

6. The spectrometer assembly of claim 1, further comprising a first housing that contains the signal processor and a first set of the plurality of the spectrometer channels, and a second housing that contains a second set of the plurality spectrometer channels, the second housing being independent of the first housing and each spectrometer channel in the second set is operatively coupled to the signal processor in the first housing.

7. The spectrometer assembly of claim 1 wherein the flow cell assembly is a high-pressure flow cell configured to receive a high-pressure fluid sample flow therethrough.

8. The spectrometer assembly of claim 1 wherein each flow cell assembly includes a flow cell body having a sample passageway extending therethrough and in fluid communication with the sample inlet and sample outlet, the flow cell assembly emulating a fiber optic connection between the light source and the spectrometer module of the respective spectrometer channel.

9. The spectrometer assembly of claim 1 wherein each of the flow cell assemblies includes: a flow cell body mounted to the respective chassis, the flow cell body having a sample flow inlet, a sample flow outlet, and a sample passageway extending therebetween, the sample flow inlet being in fluid communication with the sample inlet, and the sample flow outlet being in fluid communication with the sample flow outlet; and first and second light couplers removably connected to the flow cell body, first light coupler being positioned in axial alignment with the light outlet portion of the light source and the second light coupler positioned in axial alignment with the optical inlet of the spectrometer module.

10. The spectrometer assembly of claim 9 where the first light coupler has: a first connector releasably connected to the light outlet portion of the light source and connected to the flow cell body, a first flow cell window connected to the first connector, the first flow cell window having a light receiving end and a light outlet end, the light receiving end being positioned adjacent to the light outlet portion of the light source to receive light from the light source and the light outlet end being positioned within the flow cell body adjacent to the sample passageway to direct light across the sample flow passageway, and the second light coupler has: a second connector releasably connected to the respective spectrometer module and connected to the flow cell body; a second flow cell window connected to the second connector, the second flow cell window having a light receiving end and a light outlet end, the light receiving end being positioned in the flow cell body and spaced apart from the light outlet end of the first flow cell window on an opposite side of the sample passageway, the second flow cell window being in axial alignment with the first flow cell window and with the optical inlet of the spectrometer module.

11. The spectrometer assembly of claim 1 wherein each flow cell assembly includes optical connectors interconnecting the flow cell assembly to the light source and to the spectrometer module on the respective chassis.

12. The spectrometer assembly of claim 1 wherein light source is an ultra violet light source.

13. The spectrometer assembly of claim 1 wherein the light source contains a Deuterium lamp and a tungsten lamp.

14. The spectrometer assembly of claim 1 wherein the plurality of the spectrometer channels includes a primary spectrometer channel and a plurality of secondary spectrometer channels, the primary spectrometer channel having a first chassis, and the signal processor is connected to the first chassis, and further comprising a power module connected to the first chassis and coupled to the signal processor and spectrometer module.

15. The spectrometer assembly of claim 1, wherein the signal processor includes an analog-to-digital converter coupled to each of the spectrometer channels.

16. A multiple-channel UV spectrometer assembly for analyzing a plurality of liquid sample flows, comprising: a plurality of spectrometer channels each being fluidly connectable to a respective one of the plurality of liquid sample flows, each channel having: a sample inlet and a sample outlet connectable to a respective one of the liquid sample flows; a chassis; a light source having a light outlet portion; a spectrometer module mounted to the chassis and having an optical inlet optically coupled to the light outlet portion to receive light from the light source; and a high-pressure flow cell assembly coupled between the light source and the spectrometer module for transferring light therebetween, the flow cell assembly having a sample flow passageway in fluid communication with the sample inlet and sample outlet and configured to receive one of the plurality of sample flows therethrough, the sample flow passageway positioned between the light source and the spectrometer and configured to receive light generated from the light source before the light is received by the spectrometer module; and a signal processor coupled to each of the spectrometer modules and configured to receive data from each spectrometer module.

17. The spectrometer assembly of claim 16 wherein each spectrometer channel includes connectors interconnecting the high-pressure flow cell assembly to the respective light source and to the respective spectrometer module.

18. A multiple-channel spectrometer assembly for analyzing a plurality of simultaneous sample flows, comprising: a first housing; a primary spectrometer channel positioned in the first housing and being connectable to one of the sample flows, the primary spectrometer channel having a sample inlet and a sample outlet; a first chassis; a first light source having a first light outlet portion; a first spectrometer module mounted to the first chassis and optically aligned with the first light source, the first spectrometer module having an optical inlet axially aligned with the first light outlet portion to receive light from the first light source; and a first flow cell assembly adjacent to the first chassis intermediate the first light source and the first spectrometer module, the first flow cell assembly having a first flow passageway in fluid communication with the sample inlet and sample outlet and configured to receive one of the plurality of sample flows therethrough, the first flow passageway being positioned between the first light source and the first spectrometer module and configured to receive light generated from the first light source and directed toward the first spectrometer module as the sample flow moves through the first flow passageway; and a signal processor coupled to the first spectrometer module and configured to receive data from the first spectrometer module; a first set of secondary spectrometer channels positioned in the first housing; a second housing; a second set of secondary spectrometer channels positioned in the second housing; each of the secondary spectrometer channels in the first and second housings having: a second chassis; a second light source having a second light outlet portion; a second spectrometer module mounted to the second chassis and coupled to the signal processor in the first housing, each second spectrometer module being optically aligned with the second light source, the second spectrometer module having an optical inlet coupled to the second light outlet portion to receive light from the second light source; and a second flow cell assembly adjacent to the second chassis intermediate the second light source and the second spectrometer module, the second flow cell assembly having a second flow passageway in fluid communication with the sample inlet and sample outlet and configured to receive one of the plurality of sample flows therethrough, the second flow passageway being positioned between the second light source and the second spectrometer module and configured to receive light generated from the second light source and directed toward the second spectrometer module as the sample flow moves through the second flow passageway.

19. The spectrometer assembly of claim 18 wherein each of the primary and secondary spectrometer channels includes a power module coupled to the first or second light source.

20. The spectrometer assembly of claim 18 wherein the signal processor includes an analog-to-digital converter.

21. The spectrometer assembly of claim 18 wherein each of the first and second flow cell assemblies is a high-pressure flow cell assembly configured to receive a high-pressure fluid sample flow therethrough.

22. The spectrometer assembly of claim 18 wherein the first flow cell assembly includes a flow cell body mounted to the first chassis, the flow cell body having the first flow passageway therethrough and in fluid communication with the sample inlet and sample outlet, the first flow cell assembly having a close-coupled light path intersecting the first flow passageway and extending between the first light source and the first spectrometer module.

23. The spectrometer assembly of claim 18 wherein the first flow cell assembly includes: a flow cell body mounted to the first chassis, the flow cell body having a sample flow inlet, a sample flow outlet, and the first flow passageway extending therebetween, the sample flow inlet being in fluid communication with the sample inlet, and the sample flow outlet being in fluid communication with the sample outlet; first and second light couplers removably connected to the flow cell body, first light coupler being positioned in axial alignment with the light outlet portion of the light source and the second light coupler positioned in axial alignment with the optical inlet of the first spectrometer module.

24. The spectrometer assembly of claim 23 where the first light coupler has: a first connector releasably connected to the light outlet portion of the light source and connected to the flow cell body; a first flow cell window connected to the first connector, the first flow cell window having a light receiving end and a light outlet end, the light receiving end being positioned adjacent to the light outlet portion of the light source to receive light from the light source and the light outlet end being positioned within the flow cell body adjacent to the sample passageway to direct light across the first flow passageway; and the second light coupler has: a second connector releasably connected to the respective spectrometer module and connected to the flow cell body; a second flow cell window connected to the second connector, the second flow cell window having a light receiving end and a light outlet end, the light receiving end being positioned in the flow cell body and spaced apart from the light outlet end of the first flow cell window on an opposite side of the sample passageway, the second flow cell window being in axial alignment with the first flow cell window and with the optical inlet of the spectrometer module.

25. A flow cell assembly configured to receive a high-pressure sample flow for use with a spectrometer module and a light source, comprising: a flow cell body having a sample flow inlet, a sample flow outlet, and a sample passageway extending between the sample flow inlet and sample flow outlet, the sample flow inlet being fluidly coupled to the high-pressure sample flow; first and second light couplers removeably connected to the flow cell body, first light coupler optically connectable to the light source and the second light coupler spaced apart from the first light coupler and positioned with the sample passageway therebetween and optically coupled to the spectrometer module.

26. The flow cell assembly of claim 25, wherein the first light coupler has: a first connector connectable to the light source and releasably connected to the flow cell body; a first flow cell window connected to the first connector, the first flow cell window having a light receiving end and a light outlet end, the light receiving end being positioned adjacent to the light outlet portion of the light source to receive light from the light source, and the light outlet end being positioned within the flow cell body adjacent to the sample passageway to direct light across the sample flow passageway; and the second light coupler has: a second connector connectable to the respective spectrometer module and releasably connected to the flow cell body; a second flow cell window connected to the second connector, the second flow cell window having a light receiving end and a light outlet end, the light receiving end being positioned in the flow cell body and spaced apart from the light outlet end of the first flow cell window on an opposite side of the sample passageway, the second flow cell window being in axial alignment with the first flow cell window.

27. A flow cell assembly configured to receive a high-pressure sample flow for use with a spectrometer module and a light source, comprising: a flow cell assembly between the light source and the spectrometer module, the flow cell having a flow passageway in fluid communication with the sample inlet and sample outlet and configured to receive one of the plurality of sample flows therethrough, the flow passageway being positioned between the light source and the spectrometer and configured to emulate a fiber optic cable therebetween to direct light from the light source toward the spectrometer module as the sample flow moves through the flow passageway.

28. A multiple-channel spectrometer assembly for analyzing a plurality of sample flows, comprising: a plurality of spectrometer channels each being fluidly connectable to a respective one of the plurality of sample flows, each channel having: a sample inlet and a sample outlet connectable to a respective one of the sample flows; a chassis; a light source having a light outlet portion; a spectrometer module mounted to the chassis and optically aligned with the light source, the spectrometer module having an optical inlet axially aligned with the light outlet portion of the light source; and a flow cell assembly intermediate the light source and the spectrometer module, the flow cell having a flow passageway in fluid communication with the sample inlet and sample outlet and configured to receive one of the plurality of sample flows therethrough, the flow passageway being positioned between the light source and the spectrometer and configured to emulate a fiber optic cable therebetween to direct light from the light source toward the spectrometer module as the sample flow moves through the flow passageway.

29. A spectrometer assembly for analyzing a high-pressure sample flow, comprising: a light source having a light outlet portion; a spectrometer module having an optical inlet configured to receive light from the light source; and a high-pressure flow cell assembly optically coupled between the light source and the spectrometer module, the flow cell assembly having a flow cell body with a flow inlet configured to receive the sample flow, and a flow outlet in fluid communication with the flow inlet, the flow cell assembly having first and second optical couplers connected to the flow cell body, the first optical coupler being coupled to the light source and the second optical coupler being connected to the spectrometer module, the first and second optical couplers having axially aligned portions in the flow cell body with flow-facing ends spaced apart from each other by a selected distance to define a fluid passageway therebetween in fluid communication with the flow inlet and flow outlet, the fluid passageway being free of upswept dead space while the sample flow moves therethrough, the first optical coupler is configured to direct light across the flow passageway when the high-pressure sample flow passes through the flow passageway, and the second optical coupler is configured to receive light from the flow passageway and directed toward the spectrometer module.

30. The spectrometer assembly of claim 29 wherein the flow inlet includes a small-bore first channel having a first diameter, and the flow outlet includes a small-bore second channel having a second diameter and in fluid communication with the first channel, and the flow-facing ends of the first and second optical coupler being spaced apart from each other by a distance less than the first and second diameters.

31. The spectrometer assembly of claim 29 wherein the first and second couplers are axially aligned with each other.

32. The spectrometer assembly of claim 29 wherein the flow inlet and flow outlets in the flow cell body are axially aligned.

33. The spectrometer assembly of claim 29 wherein the first and second couplers are axially moveable relative to the flow cell body and to each other.

34. The spectrometer assembly of claim 29 wherein the first and second couplers are each threadably connected to the flow cell body and axially adjustable to adjust the size of the flow passageway.

35. The spectrometer assembly of claim 29 wherein the first optical coupler is directly connected to the light source.

36. The spectrometer assembly of claim 29 wherein the second optical coupler is directly connected to the spectrometer module.

37. The spectrometer assembly of claim 29 wherein the flow cell includes a replaceable spacer between the flow cell body and at least one of the first and second optical couplers.

Brief Patent Description - Full Patent Description - Patent Claims

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