A microfluidic interconnect system and method for assembly thereof is described. The microfluidic interconnect has a port and a seal, with the port having a reverse taper. The port has a first port end, a second port end, and an inner port surface with a tapered portion. Each port end has an opening
A microfluidic interconnect system and method for assembly thereof is described. The microfluidic interconnect has a port and a seal, with the port having a reverse taper. The port has a first port end, a second port end, and an inner port surface with a tapered portion. Each port end has an opening with a diameter, and in certain embodiments, the diameter of the first port end is smaller than the diameter of the second port end. The seal has a first end and a second end, and each seal end has a rim and an opening with an inner diameter and an outer diameter. The seal also has an inner surface and an outer surface, where in certain embodiments, each surface has a tapered portion. In certain embodiments, the inner diameter of the first seal end is equal to or larger than the inner diameter of the second seal end, the outer diameter of the first seal end is equal to or smaller than the outer diameter of the second seal end, and the outer diameter of the second seal end is larger than the outer diameter of each port end. In certain embodiments, a tube is slidably coupled to the inner surface of the seal, and the tube has an outer diameter that is equal to or larger than the inner diameter of the second seal end.
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1. A microfluidic interconnect for use with an analytical instrument system, comprising: a) a port in a chip for receiving a fluid, wherein said port has a first port end, a second port end, and an inner port surface with a tapered portion, wherein each port end has an opening with a diameter, and f
1. A microfluidic interconnect for use with an analytical instrument system, comprising: a) a port in a chip for receiving a fluid, wherein said port has a first port end, a second port end, and an inner port surface with a tapered portion, wherein each port end has an opening with a diameter, and further wherein the diameter of the first port end is smaller than the diameter of the second port end;b) a seal having a passageway therethrough and an outer seal surface slidably coupled to the inner port surface, a first seal end, a second seal end, and an inner seal surface, i) wherein each seal surface has a tapered portion,ii) wherein each seal end has a rim and an opening with an inner diameter and an outer diameter,iii) and further wherein the inner diameter of the first seal end is larger than the inner diameter of the second seal end, the outer diameter of the first seal end is smaller than the outer diameter of the second seal end, and the outer diameter of the second seal end in an uncompressed state is larger than the outer diameter of each port end, and wherein the second seal end sealingly engages with the second port end without an additional clamping device when an end portion of an outer surface of a tube which has an outer diameter that is equal to or larger than the inner diameter of the second seal end is coupled to a portion of the inner seal surface and is located within the passageway of said seal within said port. 2. The microfluidic interconnect according to claim 1, wherein said tube comprises polyetheretherketone (PEEK™), polyetheretherketone-covered fused silica (PEEKsil™), stainless steel, or fused silica. 3. The microfluidic interconnect according to claim 1, further comprising a thermosetting polymer for coupling the seal to the tube. 4. The microfluidic interconnect according to claim 1, further comprising a thermosetting polymer for coupling the seal to the port. 5. The microfluidic interconnect according to claim 1, wherein a frictional force between said seal and tube exceeds an extrusion force required to extrude the tube from said seal. 6. The microfluidic interconnect according to claim 1, wherein the tube and seal are chemically compatible with respect to each of water, methyl ethyl ketone, aliphatic hydrocarbons, and aromatic hydrocarbons. 7. The microfluidic interconnect according to claim 1, wherein insertion of the tube into the seal causes an elongation of the second seal end inner diameter within a range of approximately 4% and approximately 35%. 8. The microfluidic interconnect according to claim 1, wherein the diameter of each port opening is less than 1 inch. 9. The microfluidic interconnect of claim 1, wherein said seal comprises a fluoro-elastomer. 10. The microfluidic interconnect of claim 1, wherein said seal and said port are each generally frusto-conical in shape. 11. The microfluidic interconnect according to claim 1, wherein the tapered portion of the inner seal surface is at an angle within a range of approximately 91 degrees and approximately 100 degrees with respect to the second seal end. 12. The microfluidic interconnect according to claim 1, wherein the tapered portion of the inner surface of the port is at an angle within a range of approximately 80 degrees and approximately 89 degrees with respect to the second port end. 13. The microfluidic interconnect according to claim 1, wherein the tapered portion of the outer seal surface is at an angle within a range of approximately 95 degrees and approximately 110 degrees with respect to the second seal end. 14. The microfluidic interconnect according to claim 1, wherein insertion of the seal into the port causes a compression of the outer diameter of the second seal end within a range of approximately 1% and approximately 10%. 15. An analytical instrument system comprising at least one microfluidic connection, wherein said microfluidic connection comprises: a) a port in a chip, wherein said port has a first port end, a second port end, and an inner port surface with a tapered portion, wherein each port end has an opening with a diameter, wherein the diameter of the first port end is smaller than the diameter of the second port end, wherein the second port end is in fluid communication with a fluid channel in the chip, and wherein said port defines a frusto-conical shape;b) a seal having a passageway therethrough, an outer seal surface slidably and removably coupled to the inner port surface, a first seal end, a second seal end, and an inner seal surface, wherein each seal surface has a tapered portion, and wherein an inner diameter of the first seal end is larger than an inner diameter of the second seal end, an outer diameter of the first seal end is smaller than an outer diameter of the second seal end, and the outer diameter of the second seal end in an uncompressed state is larger than the outer diameter of each port end, wherein said seal defines a frusto-conical shape, and wherein the second seal end and the second port end are sealingly engaged; andc) a tube having a passageway therethrough and having a first tube end and a second tube end, wherein a portion of said tube is located within the passageway of said seal and within said port, and wherein the second tube end is sealingly engaged with the second port end, and wherein at least a portion of said tube proximal the second tube end has an outer diameter that is equal to or larger than the inner diameter of the second seal end. 16. The analytical instrument system according to claim 15, wherein a frictional force between said seal and tube exceeds an extrusion force required to extrude the tube from said seal. 17. The analytical instrument system according to claim 15, wherein the tube and seal are chemically compatible with respect to each of water, methyl ethyl ketone, aliphatic hydrocarbons, and aromatic hydrocarbons. 18. The analytical instrument system according to claim 15, wherein insertion of the tube into the seal causes an elongation of the second seal end inner diameter within a range of approximately 4% and approximately 35%. 19. The analytical instrument system of claim 15, wherein said seal comprises a fluoro-elastomer. 20. The analytical instrument system according to claim 15, wherein the tapered portion of the inner surface of the port is at an angle within a range of between approximately 80 degrees and approximately 89 degrees with respect to the second port end. 21. The analytical instrument system according to claim 15, wherein the tapered portion of the inner seal surface has an angle within a range of approximately 91 degrees and approximately 100 degrees with respect to the second seal end. 22. The analytical instrument system according to claim 15, wherein the tapered portion of the outer seal surface has an angle within a range of approximately 95 degrees and approximately 110 degrees with respect to the second seal end. 23. The analytical instrument system according to claim 15, wherein the outer diameter of the second seal end is compressed within a range of approximately 1% and approximately 10% when said seal is inserted into the port. 24. A microfluidic fitting assembly comprising: a) a port in a chip body, wherein said port has a first port end, a second port end, and an inner port surface with a tapered portion, wherein each port end has an opening with a diameter, and further wherein the diameter of the first port end is smaller than the diameter of the second port end, wherein the second port end is in fluid communication with a fluid channel in the chip body, and wherein said port defines a frusto-conical shape;b) a seal having a passageway therethrough, an outer seal surface slidably and removably coupled to the inner port surface, a first seal end, a second seal end, and an inner seal surface, wherein each seal surface has a tapered portion, and wherein an inner diameter of the first seal end is larger than an inner diameter of the second seal end, an outer diameter of the first seal end is smaller than an outer diameter of the second seal end, and the outer diameter of the second seal end in an uncompressed state is larger than the outer diameter of each port end, wherein said seal defines a frusto-conical shape, and wherein the second seal end and the second port end are sealingly engaged; andc) a tube having a passageway therethrough and having a first tube end and a second tube end, wherein a portion of said tube is located within the passageway of said seal and within said port, and wherein the second tube end is sealingly engaged with the second port end, and wherein at least a portion of said tube proximal the second tube end has an outer diameter that is equal to or larger than the inner diameter of the second seal end and elongates the inner diameter of the second seal end within a range of 4% to 35%. 25. The microfluidic fitting assembly according to claim 24, wherein said seal comprises a fluoro-elastomer. 26. The microfluidic fitting assembly according to claim 24, wherein the tapered portion of the inner seal surface has an angle within a range of approximately 91 degrees and approximately 100 degrees with respect to the second seal end. 27. The microfluidic fitting assembly according to claim 24, wherein the tapered portion of the outer seal surface has an angle within a range of approximately 95 degrees and approximately 110 degrees with respect to the second seal end. 28. The microfluidic fitting assembly according to claim 24, wherein the outer diameter of the second seal end is compressed within a range of approximately 1% and approximately 10% when said seal is inserted into the port. 29. The microfluidic fitting assembly according to claim 24, wherein a frictional force between said seal and tube exceeds an extrusion force required to extrude the tube from said seal. 30. The microfluidic fitting assembly according to claim 24, wherein the tube and seal are chemically compatible with respect to each of water, methyl ethyl ketone, aliphatic hydrocarbons, and aromatic hydrocarbons. 31. The microfluidic fitting assembly according to claim 24, wherein insertion of the tube into the seal causes an elongation of the second seal end inner diameter within a range of approximately 4% and approximately 35%. 32. The microfluidic fitting assembly according to claim 24, wherein the tapered portion of the inner surface of the port is at an angle within a range of between approximately 80 degrees and approximately 89 degrees with respect to the second port end.
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