TH19394B - Methods and instruments for controlled production and temperature control in the liquid natural gas production of mixed refrigerants. - Google Patents

Abstract

DC60 (06/10/41) Control system for the process of natural gas liquefied (LNG) production using a heat exchanger. And the closed cycle cooling cycle uses Control both for both production And direct temperature, independently by adjusting the cooling accordingly. With the set production The control system will set The LNG is produced at the desired production value, and the LNG temperature is independently controlled by adjusting the cooling supplied to the natural gas stream. One example method uses the compressor speed, for example, a variable that Optimized the key-type (MV) to achieve constant and rapid control of the LNG ginger temperature. Rather, the velocity may be key-type MVs, which depends on the type of MR compressor used, and possibly the human turbine blades in the compressor. Centrifugal force Or the angle of the stator rotor In the axial compressor, the second sampling method uses the ratio of the coolant flow. It is a totally new spin on LNG flow, a key-type optimization variable to effectively control the temperature of LNG. Control system for the process of LNG production from natural gas using a heat exchanger. And the closed cycle cooling cycle uses Control both for both production And direct temperature, independently by adjusting the cooling accordingly. With the set production The control system will set The LNG is produced at the desired production value, and the LNG temperature is independently controlled by adjusting the cooling supplied to the natural gas stream. One example method uses the compressor speed, for example, a variable that Optimized the key-type (MV) to achieve constant and rapid control of the LNG ginger temperature. Rather, the velocity may be key-type MVs, which depends on the type of MR compressor used, and possibly the human turbine blades in the compressor. Centrifugal force Or the angle of the stator rotor In the axial compressor, the second sampling method uses the ratio of the coolant flow. It is a totally new spin on LNG flow, a key-type optimization variable to effectively control the temperature of LNG.

Claims (8)

1. Methods for controlling the production of liquefied natural gas (LNG) outlet flows (222) by natural gas cooling. Which flows through the liquefaction process, which consists of the steps of: (a) temperature measurement and flow rating of the LNG exit current (222); And (b) the cooling transformation of natural gas. To adjust the temperature of the LNG outlet current (222) and the independent adjustment of the LNG outlet flow rating, while maintaining the LNG outlet current rating (222) at the set flow value. And the temperature at the specified temperature value 2. Procedure for claim 1, where step b) will continue with the procedure for Cooling management in the cycle of closed loop cooling (226) where the compressor (238) will adjust the coolant flow and pressure and vary, at least, the value of the compressor. Selected from a group consisting of Speed, angle of turbine blades And compressor stator rotor position To adjust the practice The operation of the closed loop cooling cycle, whereby the temperature of the LNG outlet stream is adjusted. 3. Claim Method 2, which follows the procedure of: (c) Defining corresponding target values based on finite values. Set range Operation of the compressor For at the very least the value of the compressor; And (d) the minimum adjustment of the compressor value. To the corresponding target value, and (e) the variation, which is based on at least the adjustment of the compressor, at least the value associated with the coolant re-rotation, where Will hold the value The flow and temperature of the outlet current of the LNG (200). 4. The method of claim 3, where step d) varies at least the value of the refrigerant based on the feedback signal that is based on at least the compressor value and the value. Consistent goals 5. Method of Claim No. 1, including following the procedure for Refrigerant flow rating measurement And the LNG outlet flow rating (222), the ratio of the refrigerant flow rating to the LNG flow rating (222), and scaling to adjust the performance of the cooling cycle. Cool the twisted loop, where it will Adjust the temperature of the exposure of the LNG (222). 6. Method of claim 5, where the refrigerant is partially condensed to exist. In the form of a liquid of a coolant And the vapor of the coolant And the procedure for measuring the flow rating This will include measurements of refrigerant vapor flow ratings. And the fluid flow rating Of the coolant And the ratio adjustment process will include adjusting the refrigerant's vapor flow, setting the refrigerant flow rating. And adjusting the liquid flow of the coolant to adjust the ratio until the desired flow ratio is obtained. 7. Method of claim 5, where the refrigerant is partially condensed to exist. In the form of a liquid coolant And the vapor of the coolant And the flow rating measurement process will include the coolant flow rating measurement. And the rated flow of Liquid coolant And the ratio adjustment process will include adjusting the flow of the coolant liquid to set the refrigerant flow rating. And adjusting the vapor flow of substances Cool to adjust the ratio until the desired flow ratio is achieved. 8. Method of claim No. 1, where the liquefaction process of natural gas is performed in the plant. Where it will consist of a heat exchanger (210) with a heated end And the cool end And the entrance to the natural gas feed stream (216) is at its heated end, the pipe (218,220) located in the heat exchanger (210) for the cooling and liquefaction of the natural gas. By indirect heat exchange with current Of refrigerant contained in separate cooling cycles And the liquefied natural gas path (222) for the transmission of the LNG exit stream to the cold end of the heat exchanger (210). The path is equipped with an LNG flow control device (224). The cooler is composed of a compressor (236) for compression. Condensers (242) for condensing the compressed coolant, expansion devices (260) for condensing coolant expansion and a route for introducing the extended coolant into the vaporization zone in the heat exchanger. Where the extended coolant is indirectly exchanging heat with and conducting cooling with the natural gas stream. Where the natural gas is liquefied, and the route for returning the extended coolant, evaporated from the preheated end to the compressor (238), and where the cooling control is in control. Process variable feedback Fitting It is selected from a group consisting of: compressor operation (238) and amplification equipment operation (260) 9. Method of claim No. 8, where the condenser function (242) to condense the cooled refrigerant. Compressed to produce a vapor coolant. And a liquid coolant and there is a separate expansion device (260,268) for each vapor coolant. And a liquid coolant and a separate expansion device (860,260) of either or one of them will be supplied. Separately suitable 1 0. Method of claim 8, where the compressor of the refrigerant (238) is selected from a group consisting of centrifugal compressors. Which has pilot turbine blades and axial compressors Which has a stator rotor And the LNG outlet flow rating (222) is under feedback control, with the improvement of the LNG flow control device (224), and the LNG outlet current temperature (222) is under control. Control feedback by Adjust the compressor parameters selected from the group which includes: (a) the compressor speed of the coolant, (b) the angle of the turbine blade, and (c) the stator blade angle. 1 1. Method of claim that 10 where the compressor parameters are the compressor speed of the coolant (238) and (a) if the temperature of the outlet flow of the LNG (222) is higher than the set temperature. Then, the compressor speed of the coolant (238) will increase; Or (b) if the temperature of the LNG outlet current (222) is lower than the specified temperature. Then, the compressor speed of the coolant (238) will decrease by 1. 2. Method of claim No. 10, where the compressor (238) is a strong compressor. Centrifugal (238) and the compressor variable is the angle of the pilot turbine blade and: (a) if the outlet temperature of the LNG (222) is higher than the predetermined temperature, the angle of the pilot turbine blade decreases (b). If the outlet temperature of the LNG (222) is lower than the set temperature, Then, the guide turbine blade angle will decrease by 1. 3. Method of claim No. 10, where the compressor (238) is the axial compressor. And the compressor parameters are the stator rotor angle and: (a) if the outlet temperature of LNG (222) is higher than the predetermined temperature, the stator rotor angle will increase; Or (b) if the outlet temperature of the LNG (222) is lower than the predetermined temperature, the stator rotor angle decreases by 1. 4. Method of claim No. 10, where the rated flow And the outlet temperature of the LNG (222) is controlled in unison by feedback through combined and unison modulation to the multi-variable regulator of the LNG flow control device (224), and at the very least. Of compressor variant 1 5. Method of claim No. 8, where the pipes for the cooling of natural gas in the apparatus Heat exchanger Will go through at least the warm zone (212) near the warm end of the machine Heat exchanger (210) and the cold zone (214) near the cold end of the heat exchanger (210) the evaporation zone in the cooling cycle (226) is divided into at least the warm zone (212). And the corresponding cold zone (214), respectively, with the warm zone (212) and the cold zone (214) to where the pipe passes, with a separate expansion device (260,268) for condensing the refrigerant into but Each zone of the warm zone (212) and the cold zone (214), and where the preheating zone (268) regulates the flow of at least the portion of the coolant. Condensation to the warm zone (212) and the cold zone expander (260) controls the flow of at least part Of the refrigerant condensed to the cold zone (214) and this includes the following steps: (a) the desired target setting for the compressor variable; (b) the current configuration of the variable of the compressor; (c) comparison of the desired target value with the current value; And (d) adjustment of the heated zone amplification device. By means of a reverse control method that is based on different values and on the same difference between the demand target value and the current value of the compressor variable. To achieve the temperature change of the outlet current of the LNG (222) in the same direction as achieved by adjusting the Compressor, and (e) resetting the compressor variables to the desired target value 1 6. Method of claim No. 15, where the coolant is a multi-component coolant. This is partially condensed to organize the coolant liquid. And the cough of cooling that contains the Liquid coolant Which flows through the warm zone (212) and the vapor of the coolant Which flows through the cold zone (214) and the warm zone (212) and is further included with the procedure of: (a) predetermination of the desired ratio of the coolant flow As a liquid to the flow of a vapor refrigerant (b) current flow rating detection of a liquid coolant; (c) measuring the current flow rating of the vapor coolant; (d) Determination of the current ratio of the flow of the liquid coolant to the flow. Of the vapor coolant and (e) cooling zone expansion / flow control device (260) to adjust the flow ratio The ratio of the liquid coolant to the flow of the vapor coolant is defined as a predetermined ratio. 1 7. Procedures of Clause 16, which will be extended further with the limited control of temperature Of the refrigerant at a path for reversing the extended coolant, evaporated from the heated tip Of the heat exchanger (210) to the compressor (238), which consists of the procedure of: (a) pre-determined of the low temperature limit for coolant inversion. At the warm tip (b) temperature measurement of the refrigerant returning at the warm tip; (c) comparison of the measured temperature with the limit temperature; (d) If the measured temperature is less than the limit temperature, the flow rating ratio is reduced. Liquid cooling per the vapor coolant flow rating Until temperature That measured over the limit temperature 1 8. Method of claim 16, which shall include further with determination of compressor vent pressure and compressor power consumption. And will include further with control A limited number of process parameters are selected from a group. It consists of: (a) compressor vent pressure (b) compressor intensification (c) cooling / flow control expansion device and (d) preheating / flow control expansion device; By selecting the desired target value for the compressor variable selected at The group includes (a) compressor speed, (b) guide turbine blade angle, and (c) stator blade angle 1 9. Method of claim 18 where the desired target setting will take effect. By way The best way to calculate In a steady state using a selection of factors from a group consisting of: (a) predetermined LNG outlet flow rating (b) natural gas feed condition (c) amount of excipient Cool in the cooling cycle; (d) composition of mixed refrigerant (e) operating pressure (f) obtainable power (g) design of equipment (h) compressor characteristics. And (i) environment 2 0. Method of claim 17, where the desired ratio of flow rating Of the refrigerant's liquid to the vapor flow rating of the refrigerant. Will produce fruit by means of Optimal calculation in steady state Using the factors selected from the group It includes: (a) LNG outlet current rating as defined (b) natural gas feed condition (c) amount of refrigerant. In the cooling cycle (d) composition of the mixed refrigerant (e) operating pressure (f) obtainable power (g) design of equipment (h) compressor characteristics and ( i) ENVIRONMENT 2. 1. Method of Clause 16, where: (a) LNG outlet flow rating (222), which is to be achieved by the control Control the feedback of the LNG flow control device (224) (b) adjusting the refrigerant liquid flow rating to the predetermined value. This is achieved by controlling the feedback of the preheating / flow control device (268) (c) adjusting the refrigerant's vapor flow rating to the predetermined value. Feedback control of cold zone expansion device / flow control (260) (d) predetermined value for the ratio of the liquid flow rating of the reagent. To cool according to the refrigerant vapor flow rating Will be maintained by adjusting the resulting value Predetermined the refrigerant liquid flow rating; (e) a predetermined value The ratio of the total refrigerant flow (liquid and vapor) to the LNG outlet flow rating (222) is obtained by adjusting the predetermined value of the refrigerant's vapor flow rating. ; And (f) the temperature control of the LNG outlet current (222) is effected by adjusting the values according to The ratio of the refrigerant flow rating was determined. All per coordinate The outlet flow of LNG 2 2. Method of claim 21 where the compressor speed of the refrigerant (238) is adjusted as a function of the mass flow rating (238) to the compressor so that Acquire Maximum compressor picture 2 3. The method of claim 21, where the angle of the compressor turbine blade of the refrigerant is adjusted as a function of the mass flow rating to the compressor (238) to obtain Come to Maximum compressor efficiency 2 4. Method of claim 21, where the angle of the compressor stator suspension of the The cooling capacity is adjusted as a function of the mass flow rating to the compressor. (238) to obtain 2. 5. Method of claim No. 21 which will be further included with limited control of temperature. Of the refrigerant recovered at the path for recovery of the extended refrigerant, which is evaporated from The preheating component of the heat exchanger (210) to the compressor (238) consists of a procedure of (a) pre-set low temperature limitation for the recovered coolant. At the tip warm; (b) temperature measurement of the refrigerant brought back at the warm tip; (c) Comparison of the measured temperature with the limit temperature (d) If the measured temperature is less than the limit temperature, the ratio of the flow rating of the Liquid coolant per the vapor coolant flow rating until the measured temperature is greater than the limit temperature 2 6. Method of claim 22, where the predetermined value for the rated temperature Flow of substances The liquid cooling capacity of the vapor coolant is determined by the method of Optimally calculated in a steady state using a selection of factors from a group consisting of: (a) predetermined LNG outlet current flow ratings, (b) natural gas feeder conditions; (c) the amount of the coolant in the cooling cycle; (d) composition of the mixed coolant; (e) operating pressure; (f) Feasible power, (g) design of equipment, (h) compressor characteristics, and (i) environmental conditions 2 7. equipment for controlling the production of liquefied natural gas (LNG) exit currents (222) by Natural gas cooling Which flows through the process of liquefaction, which includes a measuring path (276,278) for temperature measurement. And the LNG exit current flow rating (222) and the control path for a) the natural gas cooling transformation. To adjust the temperature of the LNG outlet current is characterized by a control path (274) b) independent adjustment of the LNG flow through the process, while maintaining rated flow. The outlet current of the LNG (222) is maintained at the predetermined flow value and the temperature at the predetermined temperature value. 2. 8. Equipment of claim 27, where the control path will continue to be assembled. By means of the variation in relation to the compressor (238) that manages the cooling, where to adjust the The temperature of the outlet current of the LNG (222) 2 9. The device of claim 28, where the compressor (238) adjusts the refrigerant flow and pressure, and the relative value of the compressor (238) is at least. The most value of Compressors selected from a group consisting of velocity, guide turbine blade angle and propeller position for Compressor stator (238) to adjust the operation of the closed loop cooling cycle, by adjusting the LNG outlet current temperature (222) 3 0. Device of claim No. 29, which consists of: A path for the corresponding target configuration with a base. Is on the set range Limited operating range of the compressor For at the very least, the compressor value and the path for at least the adjustment of the compressor to the corresponding target value, and the variable path will include the path for the replacement, based on the adjustment. The minimum value of the compressor, at the very least, is related to the refrigerant re-rotation, where the flow and outlet temperature of the LNG (222) will be maintained. 27, which continues with the method for changing values Of the mixed coolant (MR) of the coolant Which manages to cool, by which to adjust the temperature of LNG exit currents (222) 3 2. Device of claim 31, where: the measurement path will consist of: a) route (268,278) for measurement. Flow rating MR and rated flow The LNG outlet currents and b) a path for determining the ratio of the MR flow rating to the LNG flow rating and the control path. This includes: a method for scaling to adjust the performance of the torsional cooling cycle, by adjusting the temperature of the LNG outlet current (222) 3 3. The device of Claim 32, which follows: The Second Way (294, 296) for measurements. Mix coolant vapor flow rating (MRV) and mixed coolant liquid rating (MRL), and path for: a) MRL flow adjustment set MR flow rating, and b). Subsequent MRV flow adjustment to adjust the ratio until the limit value is reached; And the way for changing the value of the compressor After that, the cooling arrangement, where to adjust the temperature of the LNG outlet stream (222)