1. Field of the Invention
This invention generally relates to the field of optimization of control variables to maximize production of Natural Gas Liquids (“NGL”) in a gas plant while minimizing the refrigeration system power usage, including systems in multiple processing trains.
2. Description of the Related Art
Gas plants produce fuel gas, Natural Gas Liquids (“NGL”) and other solid components such as sulfur. Such plants typically include distillation columns, heat exchangers, and refrigeration systems. The NGL product must meet certain specifications in order to be a saleable product, but variation within these boundaries is acceptable. Early efforts to improve NGL quality have been directed toward maximizing the amount of refrigeration used to achieve better recovery of heavier components. As energy costs have increased, this approach is no longer economical.
Other efforts have focused on design of turbo-expanders that drive recompression with the objective of maximizing NGL production. Other methods teach of physically manipulating the temperature profile within the column to obtain desired separation results or pressure responsive fractionation control system. With the increasing cost of energy, these approaches may not provide the most cost-effective approach.
It would be advantageous to develop a new method and apparatus that provides improvement in the recovery of the valuable NGL products while minimizing energy requirements, including systems in multiple processing trains. It would be advantageous to allow for the optimization of the process variables within allowable quality variations and equipment constraints while minimizing the overall electricity or energy usage.
Disclosed herein is a method of optimizing a Natural Gas Liquids (“NGL”) facility, wherein the NGL facility comprises NGL trains each having an NGL process. The NGL trains may comprise two or more trains in parallel. The method comprises establishing a baseline NGL recovery for each NGL process and modeling a process scenario for each NGL process using input variables. The input variables comprise process data and wherein each NGL process comprises first and second refrigeration circuit with associated refrigeration compressors. The method further includes modeling a simulated selective deactivation of a refrigeration compressor, determining a modeled NGL recovery for each NGL process from the aforementioned simulation step, and classifying the process scenario as a compressor off scenario if the modeled NGL recovery is substantially at least the same as the baseline NGL recovery. Using the data from the simulation, the method further comprises operating a functioning NGL facility having a process scenario wherein the functioning NGL facility comprises a first and second refrigeration system with associated refrigeration compressors, deactivating a refrigeration system compressor of the functioning NGL facility if the process scenario is classified as a compressor off scenario, and optimizing a feed flow rate distribution to each NGL train. In one embodiment the first and second refrigeration systems comprise C3 refrigeration systems having C3 compressors. In another embodiment the first and second refrigeration systems comprise refrigeration systems where the working fluid is one of ethane, ethylene, propane, or mixtures thereof. In another embodiment, the NGL process comprises a third refrigeration process. The third refrigeration process working fluid may be one of ethane, ethylene, propane, propylene, or combinations thereof.
Also disclosed herein is an NGL facility having first and second propane refrigeration systems and an ethylene refrigeration system. The facility includes a controller for operating the facility, wherein the controller accesses statistical process data and is configured to selectively deactivate one or more compressors of the propane refrigeration systems if the baseline NGL product specifications are attainable without operation of the compressor. The aforementioned method is also applicable to other facilities, including gas processing plants, liquefied natural gas facilities, turbo-expander plants, food processing plants, and any processing facility using two or more parallel trains.
So that the manner in which the features, advantages and objects of the invention, as well as others which will become apparent, may be understood in more detail, more particular description of the invention briefly summarized above may be had by reference to the embodiment thereof which is illustrated in the appended drawings, which form a part of this specification. It is to be noted, however, that the drawings illustrate only a preferred embodiment of the invention and is therefore not to be considered limiting of the invention's scope as it may admit to other equally effective embodiments.
Disclosed herein is a method for optimizing the production of an NGL product stream from one or more NGL trains. The method for optimizing utilizes the available refrigeration capacity provided from refrigeration circuits associated with each train. The method honors process equipment and product quality constraints such as the NGL product specification, an upper limit of the percents of ethane, methane, and lighter components (mole percent) in the residue gases, a maximum pressure drop across the demethanizer column and a predetermined operating range for suction pressures of the associated refrigerant compressors.
An example of an NGL train for use with the present method is shown in the schematic of
Chilled rich gas stream 37 and chilled liquid stream 36 have different compositions as a result of separation of natural gas feed stream 9. Natural gas feed stream 9 contains sweet gas that has been submitted to a sweetening process to remove hydrogen sulfide and carbon dioxide. Natural gas stream 9 is dehydrated in molecular sieve beds to reduce moisture levels. Natural gas feed stream 9 is preferably in a pressure range of 200-1000 psig or is compressed to reach this range. Chilled gas stream 37 is fed to second chilling unit 18 to produce second chilled gas stream 92 and second chilled liquid stream 91. The second chilled gas stream 92 is fed to the third chilling unit 22 to produce third chilled liquid stream 116.
Bottom stream 202 can be split to provide NGL outlet stream 303. When alternate heat sources are available to the bottom of the demethanizer and/or a stream containing at least partial vapor is fed to the bottom of the demethanizer, then the entire bottom stream 202 can be removed as NGL product. The three liquid streams provide feed stream for the demethanizer column from which the NGL product is drawn from the bottom.
Shown in
Vapor from the top tray of the demethanizer column 200 exits the column 200 as an overhead stream 201. The overhead stream 201 is characterized by an overhead ethane and propane concentration. An overhead valve 32 on the overhead stream 201 may be used for controlling pressure in the column 200.
Overhead stream 201 is shown being compressed to become residue gas stream 42, which comprises a sales gas stream. In another embodiment (not shown), the overhead stream 201 can be split, with compression before or after the split, to produce the residue gas stream and a recycle stream that is recycled into the demethanizer or other unit. In an alternate embodiment, the overhead stream of the column is low pressure residue gas, which can be combined with the high pressure residue gas to produce a sales gas.
A first refrigeration system 34 provides cooling to first chiller 30, second chiller 70, and third chiller 80. The first chilling unit 12 includes first chiller 30 and first chill down separator 38. The second chilling unit 18 includes second chiller 70, third chiller 80, and separator 90. The third chilling unit 22 includes fourth chiller 105 and separator 115. The fourth chiller is refrigerated by third refrigeration system 64. In one embodiment, the second chill down separator 90 defines a second chill down separator temperature, and the subsequent second chiller 80 defines a subsequent second chiller output level. Level instruments may be installed in second chiller 70 and subsequent second chiller 80.
An embodiment of the first refrigeration system 34 is shown in a schematic view in
Shown in schematic view in
One embodiment of an third refrigeration system 64 is provided in schematic view in
The present method involves an optimization of an operation of an NGL facility by minimizing the refrigeration load. The optimization disclosed herein maintains the NGL product specification without venturing outside of a prescribed ethane and propane concentration range of the demethanizer overhead 201. The refrigeration load comprises energy requirements (such as the electricity required) to operate the associated refrigeration systems. In one embodiment of the present method, the associated refrigeration systems include the first refrigeration system 34, the second refrigeration system 54, and the third refrigeration system 64.
One optimization method disclosed is based on statistical modeling relating NGL facility or plant process variables with the refrigeration system's electricity usage. The method identifies process control variables in an NGL facility for optimization and is useful for NGL facilities having single or multiple NGL trains. Key optimal targets may be included with the present method for the process control settings. These key optimal targets can be fed to a multivariable controller algorithm (such as model-based predictive control (MPC)) that controls the NGL plants, or can be implemented directly by the NGL plant operators inputting the calculated optimal targets in the NGL plant's distributed control system (DCS). Mixed Integer optimizers provide a method for determining an optimal number of deactivated refrigeration compressors in the “compressor off” scenario or in the partial recycle modes. Examples of other optimization techniques applicable with the disclosed method include “AMS Optimizer” available from Emerson Process Management, Profit Max, available from Honeywell, Inc, and ROMEO, available from Invensys Inc. In one optional embodiment, an “equipment performance monitor” is included for monitoring and ensuring the proper functioning of the refrigeration compressors. An example of an “equipment performance monitor” is Matrikon Inc.'s “Equipment Condition Monitor”, another is Emerson Process Management's AMS Suite.
Model Predictive Control (“MPC”), is an advanced control method for process industries that improves on standard feedback control by predicting how a process, such as distillation, will react to inputs such as heat input. This means that reliance on feedback can be reduced since the effects of inputs will be derived from mathematical empirical models. Feedback can still used to correct for model inaccuracies. The MPC controller relies on an empirical model of a process obtained, for example, by plant testing to predict the future behavior of dependent variables of a dynamic system based on past moves of independent variables. MPC usually relies on linear models of the process. Commercial suppliers of MPC software useful in this invention include AspenTech (DMC+), Honeywell (RMPCT) and Shell Global Solutions (SMOC).
The current method is also applicable to an NGL plant with a single refrigeration system by using the same empirical optimization method based on statistical modeling relating NGL plant process variables with the refrigeration system's electricity usage. The method identifies the key process control variables in an NGL plant to be optimized. One example of a statistical optimization method can be found in Taha et al., Ser. No. 11/797,803, published on Oct. 25, 2007 with publication number 2007/0245770 and assigned to Saudi Arabian Oil Company, which is the assignee of the present application, the entirety of which is incorporated for reference herein.
An apparatus corresponding to an embodiment of the method disclosed herein is represented in
In one mode of operation, the present method comprises compiling data during operation of an NGL process facility. Data may also optionally be obtained from modeling operating of the facility. Using the acquired data (actual, modeled, or both) a statistical optimization analysis is performed and an optimized NGL recovery is calculated. The estimation is performed on different process scenarios with one or more differing input values. Input values such as total feed to the NGL facility, ambient temperatures, and feed composition may be varied during the statistical analysis. Values not varied during the analysis include the NGL product specifications, the ethane (C2) and propane (C3) mole percent upper limits in the residue gas, the maximum pressure drop across the top section of the associated demethanizer, and a predetermined operating range for refrigerant compressor suction pressure.
The present optimization method includes modeling a process scenario by simulating selective deactivation of one or more refrigeration compressor(s) and evaluating the corresponding modeled NGL product; where the product includes the NGL product stream 303, the gas stream 42, or a combination. If the modeled NGL product has specifications within a predetermined acceptable or baseline product range, the process scenario is a “compressor off” scenario. Similarly, process scenarios are classified as a “compressor on” scenario if simulated deactivation of a refrigeration compressor results in a modeled NGL product whose specifications fall outside of a predetermined acceptable product range. Accordingly, by performing the statistical analysis disclosed herein, operating process scenarios can be identified where at least one refrigeration compressor can be deactivated without reducing NGL recovery. Deactivating a refrigeration compressor reduces compressor load, which in turn reduces the overall cost of operating the NGL process facility without compromising NGL product quality. In operation, either an automated controller or manual operator identify an actual process scenario, determine if the actual process scenario is a compressor off scenario, and deactivate one or more of the refrigeration compressors. The optimization method herein described is also useful for NGL facilities having multiple trains. In multiple train facilities the optimization method redirects a portion of the flow from the train(s) with a deactivated compressor and distributes the redirected portion to other trains.
In one example, an NGL facility optimized having four natural gas trains with a total of 8 propane compressors. Each of the propane compressors has a power of 40,000 horse power each. In this scenario, each of the trains typically has a feed of no more than 420 MMSCD. Applying the aforementioned optimization and modeling methods it has been determined one of the C3 compressors may be shut down without a loss of recovery if the total feed to the NGL facility is less than 1,470 MMSCD (1,470 MMSCD=3×420 MMSCD+(½)×420 MMSCD). Thus, the NGL train having a deactivated compressor receives a proportionally reduced amount of feed. Similarly, if the total feed is less than 1,260 MMSCD (1,260 MMSCD=3×420 MMSCD), the facility can operate with maximum NGL recovery with only six compressors activated or otherwise operating.
While the invention has been shown or described in only some of its forms, it should be apparent to those skilled in the art that it is not so limited, but is susceptible to various changes without departing from the scope of the invention. For example, this invention may be used in process design but is also useful in conjunction with an existing process plant. This invention is useful as a steady state tool and also for real time optimization. For example, splitters can be added to redirect amounts of flow or to allow for control of amounts of flow. Recycle streams can be used to enhance recovery or as a heat since for heat exchangers. Other variation can also be made.