METHOD FOR LIQUEFYING A HYDROCARBON-RICH FRACTION
A process for liquefying a hydrocarbon-rich fraction, in particular natural gas, where the hydrocarbon-rich fraction is precooled and subjected to water separation and a subsequent drying process before liquefaction and the hydrocarbon-rich fraction is liquefied against at least one mixed refrigerant circuit, where the refrigerant circulating in the mixed refrigerant circuit is compressed in at least two stages, subsequently at least partially condensed and the liquid fraction formed here is at least partly mixed into the refrigerant which has been compressed to an intermediate pressure is described. A substream of the liquid fraction serves for precooling the hydrocarbon-rich fraction to be liquefied before it is fed to the water separation, where heat exchange between the liquid fraction and the hydrocarbon-rich fraction to be liquefied is effected by means of at least one heat exchanger system.
The invention relates to a process for liquefying a hydrocarbon-rich fraction, in particular natural gas, where
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- the hydrocarbon-rich fraction is precooled and subjected to water separation and a subsequent drying process before liquefaction and
- the hydrocarbon-rich fraction is liquefied against at least one mixed refrigerant circuit,
- where the refrigerant circulating in the mixed refrigerant circuit is compressed in at least two stages, subsequently at least partially condensed and the liquid fraction formed here is at least partly mixed into the refrigerant which has been compressed to an intermediate pressure.
To liquefy hydrocarbon-rich gas fractions, in particular natural gas, use is made of, inter alia, processes employing a refrigerant mixture consisting of light hydrocarbons and nitrogen, with the refrigerant mixture being at least partially condensed at elevated pressure compared to the surroundings. In order to liquefy natural gas, the liquid refrigerant is subsequently vaporized under reduced pressure by indirect heat exchange with the natural gas. Since, in the case of a (non-azeotropic) mixture, the dew point at a given pressure is always above the boiling point, the refrigerant evaporation takes place, depending on the composition, gradually over a temperature range which extends, depending on the process, over at least 20° C., sometimes even over 200° C.
If the capital costs for a natural gas liquefaction plant are to be kept low, a mixture circuit of the above-described type is used exclusively for the entire temperature range from ambient temperature to LNG (Liquefied Natural Gas) product temperature (about −160° C.). The use of a separate precooling circuit for the temperature range from ambient temperature to about −50° C. is dispensed with here.
In a procedure of this type, which is usually referred to as SMR (Single Mixed Refrigerant) process, only one refrigerant, or substreams thereof, which displays gradual evaporation is thus available. Such a natural gas liquefaction process is known, for example, from DE 19722490.
Before liquefaction, the natural gas is generally freed of acidic gas components, such as CO2 and H2S, by means of a chemical scrub, for example an amine scrub. As a result, the natural gas is saturated with water (vapor). In order to achieve an economical design of the subsequent drying, which is generally based on adsorption on a zeolitic molecular sieve, the natural gas is cooled as far as possible and the water concentration is reduced by partial water condensation and subsequent water separation to such an extent that a limit is imposed on the threshold formation of hydrates or water ice. This limit is, depending on the gas composition, attained at a temperature of up to 20° C.
Under many climatic conditions, it is not possible to cool the natural gas to sufficiently close (not more than 10° C., preferably 5° C., above the hydrate temperature) to the abovementioned limit temperature against air and/or cooling water.
Mixed refrigerants are, owing to the gradual evaporation, not very suitable for very precisely attaining the optimum temperature of the moist natural gas before drying in an economical way without at the same time going below the hydrate temperature at least in parts of the heat exchanger used.
It is an object of the present invention to provide a process of the type in question for liquefying a hydrocarbon-rich fraction, which makes it possible for the hydrocarbon-rich fraction to be liquefied to be precooled before drying without use of a complete precooling circuit, i.e. without an additional compressor. In particular, the hydrocarbon-rich fraction should be precooled to a temperature of not more than 10° C. above, preferably not more than 5° C. above, the hydrate temperature without the moist hydrocarbon-rich fraction coming into thermal contact with temperatures below the hydrate point.
To achieve this object, a process of the type in question for liquefying a hydrocarbon-rich fraction, which is characterized in that a substream of the liquid fraction serves for precooling the hydrocarbon-rich fraction to be liquefied before the latter fraction is fed to the water separation, where heat exchange between the liquid fraction and the hydrocarbon-rich fraction to be liquefied is effected by means of at least one heat exchanger system, is proposed.
In a further embodiment of the process of the invention for liquefying a hydrocarbon-rich fraction, it is proposed that a substream of the liquid fraction of the refrigerant be depressurized to a pressure of at least 0.3 bar above, preferably at least 0.7 bar above, the suction pressure of the second or last compressor stage and only the liquid fraction formed here be used for precooling the hydrocarbon-rich fraction to be liquefied before the latter is fed to the water separation.
According to the invention, the precooling of the hydrocarbon-rich fraction to be liquefied before this fraction is fed to the water separation is effected against a substream of the liquid fraction formed in the partial condensation of the compressed refrigerant. Here, the heat exchange between this liquid fraction and the hydrocarbon-rich fraction to be liquefied is achieved by means of a heat exchanger system. The heat exchanger system serves to effect indirect heat transfer between the hydrocarbon-rich fraction to be liquefied and the gradually evaporating refrigerant.
For the purposes of the present invention, the term “heat exchanger system” refers to any system in which indirect heat transfer occurs between at least two media by means of a heat transfer fluid. Such a heat exchanger system is known, for example, from the U.S. Pat. No. 2,119,091.
Such heat exchanger systems preferably use a boiling pure material which is present in liquid form in the temperature range from 0 to 30° C., which can be, for example, ethane, ethylene, propane, propylene, butane, carbon dioxide or ammonia, as heat transfer fluid.
The heat exchanger system is preferably made up of two bundles of straight tubes, two helically coiled heat exchangers, two plate exchangers or any combination of these construction types, where the aforementioned heat exchanger components have preferably been installed in a pressure vessel which contains the boiling heat transfer fluid.
Suitable selection of the pure material heat transfer fluid and regulation of the operating pressure thereof and thus the boiling point thereof enable the hydrocarbon-rich fraction to be cooled to very close to the hydrate temperature without coming directly into thermal contact with an unacceptably cold refrigerant stream. The heat transfer fluid brings about the desired heat transfer comparatively efficiently by continual condensation on the refrigerant side and evaporation on the side of the hydrocarbon-rich fraction. In contrast to the gradually evaporating mixed refrigerant, the heat transfer fluid operates at constant boiling point and thus dew point. Even if the condensation of the heat transfer fluid occurs at least partially against a mixed refrigerant which vaporizes below the hydrate temperature of the hydrocarbon-rich fraction, the hydrocarbon-rich fraction and the mixed refrigerant are effectively separated thermally by the heat transfer fluid.
The procedure according to the invention makes it possible for the load on the drying process to be optimally reduced by cooling of the hydrocarbon-rich fraction to be liquefied or of the natural gas to be liquefied down to close to the hydrate point, and also enables water separation.
The process of the invention for liquefying a hydrocarbon-rich fraction and also further advantageous embodiments thereof are illustrated in more detail by the working examples depicted in
In the working examples depicted in
The liquefaction of the hydrocarbon-rich fraction occurs against a mixed refrigerant circuit in the working examples depicted in
Whereas the refrigerant liquid fraction 17′ taken off from the separator D3 is entirely recirculated via the depressurization valve V1 to a point upstream of the separator D2 in the methods of the prior art, a substream 17 of this liquid fraction is now employed for precooling the hydrocarbon-rich fraction 1/2 to be liquefied. For this purpose, the above-described substream 17 of the liquid fraction is depressurized in the valve V2, preferably to a pressure of at least 0.3 bar above, in particular at least 0.7 bar above, the suction pressure of the second compressor stage C2, and the resulting two-phase stream is fed to the separator D5. The gas fraction 19 present therein is recirculated via the regulating valve V3 to a point upstream of the separator D2, while the liquid fraction 18 obtained in the separator D5 is employed for precooling the hydrocarbon-rich fraction 1/2 to be liquefied and the liquid fraction 18 is subsequently likewise recirculated to a point upstream of the separator D2.
Heat exchange between the liquid fraction 17 or the liquid fraction 18 obtained after depressurization in the valve V2 and the hydrocarbon-rich fraction 1/2 to be liquefied is effected by means of the heat exchanger system E4.
In the working example depicted in
Claims
1. A process for liquefying a hydrocarbon-rich fraction where
- the hydrocarbon-rich fraction is precooled and subjected to water separation and a subsequent drying process before liquefaction and
- the hydrocarbon-rich fraction is liquefied against at least one mixed refrigerant circuit,
- where the refrigerant circulating in the mixed refrigerant circuit is compressed in at least two stages, subsequently at least partially condensed and the liquid fraction formed here is at least partly mixed into the refrigerant which has been compressed to an intermediate pressure,
- characterized in that a substream of the liquid fraction serves for precooling the hydrocarbon-rich fraction to be liquefied before it is fed to the water separation, where heat exchange between the liquid fraction and the hydrocarbon-rich fraction to be liquefied is effected by means of at least one heat exchanger system.
2. The process as claimed in claim 1,
- characterized in that the substream of the liquid fraction is depressurized to a pressure of at least 0.3 bar above, the suction pressure of the second or last compressor stage and only the liquid fraction formed here serves for precooling the hydrocarbon-rich fraction to be liquefied before it is fed to the water separation.
3. The process as claimed in claim 1, characterized in that a boiling pure material which is present in liquid form in the temperature range from 0 to 30° C., is used as heat transfer fluid of the heat exchanger system.
4. The process as claimed in claim 1, characterized in that the heat exchanger system is made up of two bundles of straight tubes, two helically coiled heat exchangers, two plate exchangers or any combination of these construction types, where the heat exchanger components have preferably been installed in a pressure vessel which contains the boiling heat transfer fluid.
5. The process as claimed in claim 1, characterized in that the refrigerant circulating in the mixed refrigerant circuit comprises nitrogen and at least one C1+-hydrocarbon.
6. The process as claimed in claim 1 wherein the hydrocarbon-rich fraction is natural gas.
7. The process as claimed in claim 2 wherein the substream of the liquid fraction is depressurized to a pressure of at least 0.7 bar above the suction pressure of the second or last compressor stage.
8. The process as claimed in claim 3 wherein the boiling pure material is selected from the group consisting of ethane, ethylene, propane, propylene, butane, carbon dioxide and ammonia.
Type: Application
Filed: Feb 11, 2016
Publication Date: Feb 15, 2018
Inventor: Heinz Bauer (Ebenhausen)
Application Number: 15/555,745