초록 ▼

A freeze-thaw valve is provided using a Peltier heat pump where the thermal short-circuit path between a cooled thermal mass and a heated thermal mass is reduced or absent and the valve state transition time is minimized. The freeze-thaw valve comprises a Peltier heat pump mounted to a heat exchange

A freeze-thaw valve is provided using a Peltier heat pump where the thermal short-circuit path between a cooled thermal mass and a heated thermal mass is reduced or absent and the valve state transition time is minimized. The freeze-thaw valve comprises a Peltier heat pump mounted to a heat exchange surface that comprises a cross-drilled copper water jacket or manifold. The Peltier heat pump is operated to maintain a cooled thermal mass at a substantially constant low temperature. A resistance heating element is used to produce a heated thermal mass. The freeze-thaw segment of a fluid conduit is commutated to contact either the heated or the cooled thermal mass to thaw and therefore open the valve or cool and thus close the valve. The operation of the Peltier heat pump at a constant temperature avoids problems inherent in the use of a Peltier heat pump to both heat and cool a freeze thaw segment.

대표청구항 ▼

What is claimed is: 1. A device for controlling the flow of fluid comprising: a Peltier heat pump having a cold face, a cradle having a channel, said channel being capable of receiving a fluidic conduit, said cradle being in thermal communication with said cold face of said Peltier heat pump, said

What is claimed is: 1. A device for controlling the flow of fluid comprising: a Peltier heat pump having a cold face, a cradle having a channel, said channel being capable of receiving a fluidic conduit, said cradle being in thermal communication with said cold face of said Peltier heat pump, said fluidic conduit capable of transporting one or more fluids, freezing the fluids contained therein at a low temperature to restrict flow and thawing fluids contained therein to allow flow; a heat element, proximal to said cradle, for applying heat to said fluidic conduit; wherein said Peltier heat pump is maintained at a substantially constant temperature, such that when said heat element applies no heat to said fluidic conduit, said fluidic conduit is held at a low temperature closed state, and when said heat element applies heat to said fluidic conduit, said fluidic conduit is held at a high temperature open state. 2. The device of claim 1 where said heat element is a resistive heat element. 3. The device of claim 2 where said heat element is a resistive heating wire. 4. The device of claim 3 where said heat element is arranged as a coil around said fluidic conduit. 5. A device for controlling the flow of fluid comprising: a Peltier heat pump having a cold face, a cradle having a channel, said channel being caiable of receiving a fluidic conduit, said cradle being in thermal communication with said cold face of said Peltier heat pump, said fluidic conduit capable of transporting one or more fluids, freezing the fluids contained therein at a low temperature to restrict flow and thawing fluids contained therein to allow flow; a heat element, proximal to said cradle where said heat element is a resistive heat element embedded into said cradle, for applying heat to said fluidic conduit; wherein said Peltier heat pump is maintained at a substantially constant temperature, such that when said heat element applies no heat to said fluidic conduit, said fluidic conduit is held at a low temperature closed state, and when said heat element applies heat to said fluidic conduit, said fluidic conduit is held at a high temperature open state. 6. The device of claim 5 where said heat element is an electrically heatable resistance film deposited on said fluidic conduit. 7. The device of claim 5 where said cradle is held in thermal communication with said cold face of said Peltier heat pump by means of a thermal bridge. 8. The device of claim 7 where said thermal bridge comprises one or more voids. 9. A device for controlling the flow of fluid comprising: a Peltier heat pump having a cold face, a cradle having a fluidic conduit, said cradle being in thermal communication with said cold face of said Peltier heat pump, said fluidic conduit capable of transporting one or more fluids, freezing the fluids contained therein at a low temperature to restrict flow and thawing fluids contained therein to allow flow; a heat element, proximal to said cradle, for applying heat to said fluidic conduit; wherein said Peltier heat pump is maintained at a substantially constant temperature, such that when said heat element applies no heat to said fluidic conduit, said fluidic conduit is held at a low temperature closed state, and when said heat element applies heat to said fluidic conduit, said fluidic conduit is held at a high temperature open state. 10. The device of claim 9 where said heat element is a resistive heat element. 11. The device of claim 10 where said heat element is a resistive heating wire. 12. The device of claim 11 where said heat element is arranged as a coil around said fluidic conduit. 13. A device for controlling the flow of fluid comprising: a Peltier heat pump having a cold face, a cradle having a fluidic conduit, said cradle being in thermal communication with said cold face of said Peltier heat pump, said fluidic conduit capable of transporting one or more fluids, freezing the fluids contained therein at a low temperature to restrict flow and thawing fluids contained therein to allow flow; a heat element, proximal to said cradle where said heat element is a resistive heat element embedded into said cradle, for applying heat to said fluidic conduit; wherein said Peltier heat pump is maintained at a substantially constant temperature, such that when said heat element applies no heat to said fluidic conduit, said fluidic conduit is held at a low temperature closed state, and when said heat element applies heat to said fluidic conduit, said fluidic conduit is held at a high temperature open state. 14. The device of claim 13 where said heat element is an electrically heatable resistance film deposited on said fluidic conduit. 15. The device of claim 13 where said cradle is held in thermal communication with said cold face of said Peltier heat pump by means of a thermal bridge. 16. The device of claim 15 where said thermal bridge comprises one or more voids. 17. A device for controlling the flow of fluid comprising: a cooled thermal mass, a cradle comprising a channel mounted on a thermal bridge, said thermal bridge being in thermal communication with said cooled thermal mass, and said channel being capable of receiving a fluidic conduit, said fluidic conduit capable of transporting one or more fluids, freezing the fluids contained therein at a low temperature to restrict flow; a heat element, proximal to said cradle, for applying heat to said fluidic conduit to thaw fluids therein to allow flow; wherein said thermal bridge has one or more voids, such that the cross-section available for heat flow between said heat element and said cooled thermal mass is reduced. 18. The device of claim 17 where said thermal bridge is composed of aluminium. 19. The device of claim 17 where said heat element is a resistive heat element. 20. The device of claim 19 where said heat element is a resistive heating wire. 21. The device of claim 20 where said heat element is arranged as a coil around said fluidic conduit. 22. The device of claim 20 where said heat element is embedded into said cradle. 23. The device of claim 17 where said heat element is an electrically heatable resistance film deposited on said fluidic conduit. 24. A device for controlling the flow of fluid comprising: a cooled thermal mass, a cradle comprising a fluidic conduit mounted on a thermal bridge, said thermal bridge being in thermal communication with said cooled thermal mass, and said fluidic conduit capable of transporting one or more fluids, freezing the fluids contained therein at a low temperature to restrict flow; a heat element, proximal to said cradle, for applying heat to said fluidic conduit to thaw fluids therein to allow flow; wherein said thermal bridge has one or more voids, such that the cross-section available for heat flow between said heat element and said cooled thermal mass is reduced. 25. The device of claim 24 where said thermal bridge is composed of aluminium. 26. The device of claim 24 where said heat element is a resistive heat element. 27. The device of claim 26 where said heat element is a resistive heating wire. 28. The device of claim 27 where said heat element is arranged as a coil around said fluidic conduit. 29. The device of claim 27 where said heat element is embedded into said cradle. 30. The device of claim 24 where said heat element is an electrically heatable resistance film deposited on said fluidic conduit. 31. A method of controlling the flow of a fluid comprising the steps of: providing a Peltier heat pump having a cold face, a cradle having a channel, said channel being capable of receiving a fluidic conduit, said cradle being in thermal communication with said cold face of said Peltier heat pump, said fluidic conduit capable of transporting one or more fluids, freezing the fluids contained therein at a low temperature to restrict flow and thawing fluids contained therein to allow flow, and a heat element proximal to said cradle for applying heat to said fluidic conduit; and, operating said heat element such that no heat is supplied to said fluidic conduit to restrict flow or operating said heat element such that heat is applied to said fluidic conduit to allow flow. 32. A method of controlling the flow of a fluid comprising the steps of: providing a Peltier heat pump having a cold face, and a cradle having a fluidic conduit, said cradle being in thermal communication with said cold face of said Peltier heat pump, said fluidic conduit capable of transporting one or more fluids, freezing the fluids contained therein at a low temperature to restrict flow and thawing fluids contained therein to allow flow, and a heat element proximal to said cradle for applying heat to said fluidic conduit; and, operating said heat element such that no heat is supplied to said fluidic conduit to restrict flow or operating said heat element such that heat is applied to said fluidic conduit to allow flow. 33. A method of controlling the flow of a fluid comprising the steps of: providing a cooled thermal mass, a cradle comprising a channel mounted on a thermal bridge, said thermal bridge being in thermal communication with said cooled thermal mass, and said channel being capable of receiving a fluidic conduit, said fluidic conduit capable of transporting one or more fluids, and a heat element proximal to said cradle for applying heat to said fluidic conduit, said thermal bridge has one or more voids, such that the cross-section available for heat flow between said heat element and said cooled thermal mass is reduced; and, operating said heat element such that no heat is supplied to said fluidic conduit to restrict flow or operating said heat element such that heat is applied to said fluidic conduit to allow flow. 34. A method of controlling the flow of a fluid comprising the steps of: providing a cooled thermal mass, a cradle comprising a fluidic conduit mounted on a thermal bridge, said thermal bridge being in thermal communication with said cooled thermal mass, said fluidic conduit capable of transporting one or more fluids, and a heat element proximal to said cradle for applying heat to said fluidic conduit, said thermal bridge has one or more voids, such that the cross-section available for heat flow between said heat element and said cooled thermal mass is reduced; and, operating said heat element such that no heat is supplied to said fluidic conduit to restrict flow or operating said heat element such that heat is applied to said fluidic conduit to allow flow.