This disclosure relates generally to closed loop systems with a pressurized working fluid, and, more particularly, to a method and apparatus for preventing the migration of contaminant gases into the system during shut down.
Closed loop systems often contain a working fluid with properties specific to the successful or efficient operation of the equipment. The working fluid properties may be degraded by the addition of foreign, particles. Closed, loop systems generally operate at elevated pressures relative to ambient pressure. This ensures that leaks propagate out of the system during operation. During system shutdown, this scenario may be reversed with the closed loop system pressure at or below ambient pressure. As a result, molecules such as oxygen and nitrogen may migrate into the system. These pollute the working fluid and negatively, impact the subsequent operation and efficiency of the system. Currently, related systems require a purge device that extracts the system pollutants from the working fluid.
One such closed loop system is that of an organic rankine cycle system which includes in serial flow relationship, an evaporator or boiler, a turbine, a condenser and a pump. Such a system is shown and described in U.S. Pat. No. 7,174,716, assigned to the predecessor of the assignee of the present invention.
In accordance with one aspect of the disclosure, a heat source is operatively connected to the evaporator and has a control which is responsive to a condition sensor for maintaining the pressure in the system above a predetermined threshold.
In accordance with another aspect of the disclosure, a process of preventing migration of impurities into a closed loop system during shut down includes the steps of sensing the pressure in the system and responsively operating a heat source so as to maintain the pressure in the system above a predetermined threshold.
In the drawings as hereinafter described, a preferred embodiment is depicted; however, various other modifications and alternate constructions can be made thereto without departing from the spirit and scope of the disclosure.
Shown in
The energy which is provided to drive the system is from of a primary heat source 16 by way of a closed loop which connects to the evaporator 11 by way of lines 17 and 18. A valve 20 is provided to turn this flow on or off and may be located either upstream or downstream from the heat exchanger 16. The primary heat source 16 may be of various types such as, for example a geothermal source, wherein naturally occurring hot fluids are available below the surface of the earth. The temperatures of such geothermal sources are generally greater than 150-F, sufficient to operate most working fluids well above atmospheric pressure.
After the working fluid is heated in the evaporator 11, it passes as a high temperature, high pressure vapor to the turbine 12 where the energy is converted to motive power. The turbine 12 is drivingly attached to a generator 19 for generating electrical power that then passes to the grid 21 for further distribution.
After passing to the turbine 12, the working fluid, which is now a vapor which is at a reduced temperature and pressure vapor, passes to the condenser 13, which is fluidly connected to a cooling water source 22 by lines 23 and 24. The condenser 13 functions to condense the working fluid vapor into a liquid, which then flows along line 26 to the pump 14, which then pumps the liquid working fluid back to the evaporator 11 by way of line 27.
During normal operation of the above described organic rankine cycle system, because of the energy added by the primary heat source 16, the working fluid always remains at a pressure substantially greater than ambient pressure. However, during selected periods of time, such as during oil warm up or when the system is shut down, such as, for example, during periods of maintenance and/or repair, then the working fluid therein slowly cools and eventually may reach ambient temperature. At this point, because of the thermodynamic, properties of the working fluid that relates temperature and pressure of a saturated system, the pressure within the system will tend to further decrease to a level below ambient pressure. This low pressure condition will then allow the migration of contaminating gases, such as oxygen and/or nitrogen, to migrate into the system from the atmosphere. The present disclosure is intended to prevent such a migration from occurring.
In one form of the disclosure, a sensor 27 is provided to sense a condition indicative of pressure in the system, such as the temperature or pressure within the evaporator 11, and to send a responsive signal along line 28 to a control 29. Control 29 is connected by a line 31 to a valve 20 with the valve 20 then being operated by the control 29 in response to the sensed temperature/pressure in such a manner as to maintain the temperature/pressure in the evaporator 11 at a level which will remain above the ambient pressure/temperature in the evaporator 11 at a level which will remain above the ambient pressure/temperature and therefore prevent the migration of unwanted gases into the system during periods of shut down.
Referring now to
As will be seen, at time t1 the system is operating normally such that the pressure is at P1. Further, at time t2, the system is shut down and the pressure begins to decline, and at time t3, reaches a threshold level of P3, which is lightly above the anticipated ambient pressure P4 for the environment of the warming system. When this threshold pressure is reached, the sensor 27 signals the control 29 which then opens the valve 32 to provide heat to the evaporator 11 to thereby cause the pressure in the system to be gradually increased.
At time t4, a second threshold of pressure equals P2 and the control 20 then responsively moves, the valve 32 to a fully closed or at least a partially closed position. The pressure of the system is then gradually reduced such that at time t5 it again reaches the lower threshold of P3 wherein the control 29 again opens the valve 32 to add heat to the system. At time t6, the control again moves the valve 32 to a more-closed position. This cycle is repeated so as to maintain the system at a pressure above that of ambient so that migration of gases into the system is prevented during shut down. When normal operation resumes, the control 29 remains in an inactive condition until called on to be activated by the sensor 27 when, for example, the system is again shutdown.
An alternative embodiment is shown in
Another alternative is to use a supplementary heat source 36 rather than the primary heat source 16 during periods of shut down. Such a supplementary heat source might be steam or hot water from a source other than the primary heat source 16, or it may be by way of an electrical resistance heater. Similar to the
As another alternative, to ensure that the two tanks i.e. the evaporator 11 and the condenser 13, are maintained at substantially the same pressure during pressure shut down, the two may be selectively fluidly interconnected by way of a line 37 and valve 38, with the valve 38 being controlled by way of the control 34.
While the present invention has been particularly shown and described with reference to preferred and modified embodiments as illustrated in the drawings, it will be understood by one skilled in the art that various changes in detail may be made thereto without departing from the spirit and scope of the disclosure as defined by the claims.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US2007/089041 | 12/28/2007 | WO | 00 | 9/14/2010 |
Publishing Document | Publishing Date | Country | Kind |
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WO2009/085048 | 7/9/2009 | WO | A |
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Entry |
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International Search Report and Written Opinion mailed Sep. 23, 2008 (9 pgs.). |
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Number | Date | Country | |
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20110000552 A1 | Jan 2011 | US |