RU2796269C2 - Device and method for crude oil desulphurization - Google Patents

Abstract

FIELD: desulfurization of crude oil.

SUBSTANCE: invention relates to a device (100) for desulfurization of crude oil, containing a system for desulfurization (102) of sulphur-containing crude oil (101), in which, in addition to sulphur-free crude oil (103), hydrogen sulphide-containing acid gas (104) is formed; a system (106) for recovering from the acid gas (104) generated in the desulfurization system (102) of elemental sulphur (107) and hydrogen sulphide-containing tail gas (108) as off-gas; unit (1) for production of electricity (24) and gypsum (21) from residual gas (108), or acid gas (104), or from a mixture of acid gas (104) and residual gas (108) and a gas pipeline system (105) for supply of acid gas (104) from the desulfurization system (102) to the system (106) for extraction of elemental sulphur (107) and to the unit (1) for production of electricity (24) and gypsum (21), as well as for supplying residual gas (108) from the elemental sulphur recovery system (106) (107) to the unit (1) for the production of electricity (24) and gypsum (21). The gas pipeline system (105) has a gas distribution device (109), which in the first position supplies acid gas exclusively to the system (106) for extraction of elemental sulphur (107), in the second position supplies acid gas exclusively to the unit (1) for production of electricity (24) and gypsum (21), and in the distribution position it supplies the first part of the acid gas (104) to the system (106) for extraction of elemental sulphur (107), and the second part of the acid gas (104) to the unit (1) for production of electricity (24) and gypsum (21). The invention further relates to a process for the desulfurization of crude oil using such a device.

EFFECT: reducing the amount of sulphur formed during desulfurization of crude oil and obtaining additional products in addition to elemental sulphur or as an alternative to it.

15 cl, 4 dwg

Description

The invention relates to a device and method for the desulfurization of crude oil.

Once crude oil has been extracted, it must first be processed, with sulfur removal being an important step. The central step in crude oil refining is desulfurization by hydrogenation in a hydrotreater. Sulfur-containing crude oil is first mixed with hydrogen and heated. In the reactor, the hot mixture reacts with a catalyst, causing the sulfur compounds in the crude oil to react with hydrogen and convert to hydrogen sulfide. The sweetened crude oil is then separated from the hydrogen sulfide, for example using an amine treatment. While the sweetened crude oil is fed to further processing, the hydrogen sulfide-containing off-gas stream, referred to as acid gas, is fed to a sulfur recovery device, for example, according to the Claus process.

Among other things, crude oil is used to produce marine fuel oil, which is currently allowed to contain up to 3.5% sulfur. However, in the next few years, the sulfur content in marine fuel oil should be reduced to 0.5%. For this, the above known methods can be used. However, this will mean that more elemental sulfur will be available as feedstock than before. However, worldwide there is no corresponding need for sulfur, and therefore it is difficult to find the use of elemental sulfur obtained by desulfurization.

The present invention aims to provide a device and method for reducing the amount of sulfur formed during the desulfurization of crude oil and obtaining additional products in addition to elemental sulfur or as an alternative to it.

This goal is achieved thanks to the creation of a device characterized by the features of paragraph 1 of the claims, and a method characterized by the features of paragraph 8 of the claims. Each of the dependent claims presents preferred embodiments and designs.

The invention provides a device for the desulfurization of crude oil, containing

a) a system for the desulfurization of sulphurous crude oil, in which, in addition to the sweetened crude oil, hydrogen sulfide-containing acid gas is formed,

b) a system for extracting elemental sulfur and residual hydrogen sulfide-containing gas from acid gas formed in the desulfurization system as off-gas,

c) plant for the production of electricity and gypsum from residual gas or acid gas or from a mixture of acid gas and residual gas,

d) a gas pipeline system for supplying acid gas from the desulfurization system to the elemental sulfur recovery system and to the power and gypsum plant, and to supply tail gas from the elemental sulfur recovery system to the power and gypsum plant, wherein

d1) the gas pipeline system has a gas distribution device which in the first position supplies the acid gas exclusively to the elemental sulfur recovery system, in the second position supplies the acid gas exclusively to the power generation and gypsum plant, and in the distribution position supplies the first part of the acid gas to the elemental sulfur recovery system sulfur, and the second part of the acid gas in the installation for the production of electricity and gypsum.

According to the invention, the installation for the production of electricity and gypsum contains:

c1) a device for generating electricity, comprising a combustion device for burning tail gas or acid gas or a mixture of tail gas and acid gas, while the energy released during combustion is at least partially used to generate electricity, and

(c2) an exhaust gas desulfurization system for desulfurizing the sulfur oxide-containing off-gases of combustion released during combustion by forming gypsum.

The desulfurization in step b) can, for example, as described at the beginning, take place by hydrogenation, in particular in a hydrotreater, and subsequent amine purification. Elemental sulfur can be recovered in step c), for example using the Claus process.

The desulfurization system desulfurizes the crude oil, for example as described above, by hydrogenation, in particular in a hydrotreater, and subsequent amine treatment. The system for recovering elemental sulfur from the acid gas of a desulfurization system, for example, operates using the Claus process.

The gas distribution device may be designed such that, in the distribution position, it provides the ability to control the amount of acid gas that is supplied as the first part of the acid gas to the elemental sulfur recovery system, and the amount of acid gas that is supplied as the second part of the acid gas to the plant. for the production of electricity and gypsum. In other words, the ratio between the first part and the second part of the acid gas can be adjusted using the gas distribution device in the distribution position.

The advantages of the invention lie in particular in that the content of sulfur oxide in the purified off-gas after desulfurization of the off-gas is further reduced by the previous combination of the elemental sulfur recovery process and the power generation process by gas combustion and is thus lower than in the tail gas . In addition, when implementing these two auxiliary methods of sulfur recovery and combustion for power generation, to optimize the conditions of each, the mixture ratio between the tail gas and the second part of the acid gas can be controlled, in particular, with a preferred content of hydrogen sulfide. An additional advantage is the termination of the release of unused hydrogen sulfide gases, because. their energy is used to generate electricity.

Another important advantage is that the amount of elemental sulfur produced is reduced because sulfur is now also stored in the form of gypsum. Compared to elemental sulfur, there is a high demand for gypsum for a wide variety of gypsum products.

The combustion temperature in the combustion device is preferably at least 1000°C. This has the advantage that at such high combustion temperatures, even harmful by-products, such as carbon monoxide, benzene and other sulfur compounds, are completely burned to form carbon dioxide, sulfur oxide and water and are thus either not present at all in the waste effluent. gases or are present in a significantly reduced amount.

According to another embodiment of the invention, the combustion device of the power generation device comprises a steam generator or is a steam generator that is part of the thermodynamic circuit of the steam power process, which in turn contains a steam turbine installed after the steam generator and a condenser installed after the steam turbine. A generator driven by a steam turbine is used to generate electricity. In this case, the energy released during combustion in the combustion device is at least partially used to generate electricity, in the sense that the energy released is initially at least partially used in the steam generator to produce steam, and then the generated steam is at least partially transferred to the steam room. a turbine that drives a generator to generate electricity. The steam may also be at least partially withdrawn and supplied for use as a heat source, for example for heating or heating.

Alternatively or additionally, the power generation device may also comprise a gas turbine and/or a gas engine. In this case, a generator driven by a gas turbine and/or a gas engine serves to generate electricity.

According to another embodiment of the invention, there are:

- a measuring device for determining the composition and/or calorific value of the gas before combustion in the combustion device (tail gas or acid gas or a mixture of tail gas and acid gas),

- an analyzing apparatus for comparing said detected composition with a given composition or a given composition range and/or for comparing said detected calorific value with a given calorific value or given calorific value range, and

- a control device and a supply device for supplying natural gas, while when the analyzing device detects a deviation from the specified composition and / or the specified composition range or the specified calorific value and / or the specified calorific value range, the control device sets an additional proportion of natural gas necessary for correction , and before burning it adds it to the gas through the supply device.

This ensures that the composition of the combusted gases is the most optimal for the intended combustion. Alternatively or additionally, the ratio between tail gas and the second part of the acid gas can be adjusted, in particular in order to adapt the hydrogen sulfide content of the gas fed to the combustion device, for example using a gas distribution device.

For example, a given composition or a given composition range may include the following mole percentages:

Hydrogen sulfide: 3% to 70%, in particular 40% to 60%, preferably about 50%, and/or

Carbon dioxide: 10% to 90%, in particular 40% to 60%, preferably about 50%.

Alternatively or additionally, the target calorific value or the target calorific value range may be from 9 to 30 MJ/m3 (at standard conditions), in particular from 15 to 25 MJ/m3 (at standard conditions), preferably about 20 MJ/m3 (at standard conditions). conditions).

In view of the fact that flue gaseous products have a very high content of sulfur oxide (especially sulfur dioxide and sulfur trioxide) compared to conventional flue gaseous products, it may be advantageous to provide a multi-stage exhaust gas desulfurization system, preferably comprising a fixed bed reactor for sulfur trioxide separation and an ash catcher (wet ash catcher) for separating sulfur dioxide.

For example, in a multi-stage exhaust gas desulfurization system, sulfur trioxide can be separated in one process step, preferably the first process step, in a fixed bed reactor. In another process step, sulfur dioxide may be separated from the wet ash collector. The fixed bed reactor may use limestone, for example having a grain size of 4/6 mm. For example, limestone powder having a grain size of 90% below 0.063 mm can be used for wet washing.

A significant advantage of this multi-stage exhaust gas desulfurization system is the separation of sulfur trioxide. Through the wet ash collector alone, sulfur trioxide will pass almost unchanged, i.e. without a fixed bed reactor, in one of the process steps, sulfur trioxide would reach the chimney and form an aerosol at the outlet of the chimney. Particularly in the case of combustion of hydrogen sulfide-containing exhaust gases from the desulfurization of sulfur-containing crude oil according to the invention, the proportion of sulfur trioxide is relatively high, and therefore a multi-stage exhaust gas desulfurization system comprising a fixed bed reactor for separating sulfur trioxide is of particular importance.

Using the device according to the invention, more than 99.9% of sulfur oxides can be separated from acid gas, or the remaining proportion of sulfur oxides is less than 100 mg/m3 (under standard conditions).

According to another embodiment of the invention, the installation for the production of electricity and gypsum contains a gypsum plant, in which gypsum obtained in the process of exhaust gas desulfurization is used to produce gypsum products, in particular gypsum boards and/or ready-made gypsum plaster mixtures.

The above gypsum plant can be organized in such a way that it fully or partially satisfies its needs for electricity from the device for generating electricity. The gypsum plant can also be organized in such a way that it fully or partially satisfies its heat demand from the combustion gases generated during the combustion of gases in the combustion device and/or during the power generation process, in particular in the thermodynamic circuit of the steam power process. If it is intended to satisfy all or part of the heat demand using a steam power process, this can be done by supplying steam directly to the gypsum plant for heating or heating purposes by means of a vent. For example, steam can be used to supply heat to a dryer and/or calciner in a gypsum plant. The significant advantage here is that carbon dioxide emissions to the environment can be avoided in this way.

The process for desulfurizing crude oil according to the invention uses the device according to the invention and includes the following steps:

a) ensuring the availability of sulphurous crude oil;

b) desulfurization of the sour crude oil using a desulfurization system in which, in addition to the sweetened crude oil, hydrogen sulfide acid gas is produced;

c) setting the gas distribution device of the gas pipeline system to the first position or to the second position or to the distribution position, while in the first position the acid gas is supplied exclusively to the elemental sulfur recovery system, in the second position the acid gas is supplied exclusively to the plant for the production of electricity and gypsum, and in the distribution position, the first part of the acid gas is supplied to the elemental sulfur recovery system, and the second part of the acid gas is supplied to the plant for the production of electricity and gypsum;

d) production of electricity and gypsum from tail gas or acid gas or from a mixture of acid gas and tail gas using a plant for the production of electricity and gypsum, and

d1) tail gas or acid gas or a mixture of tail gas and acid gas is fed into the combustion device of the power generation device and burned there, the energy released during combustion is at least partially used for power generation,

d2) sulfur oxide-containing off-gases from combustion are fed to exhaust gas desulfurization using an exhaust gas desulfurization system, and

d3) gypsum is formed during the desulfurization of exhaust gases.

The advantages of the method according to the invention result from the advantages of the device according to the invention described above.

The combustion in step d1) preferably takes place at a combustion temperature of at least 1000°C.

An additional variant of the method is based on an apparatus in which the combustion device of the power generation device comprises a steam generator or is a steam generator that is part of the thermodynamic circuit of a steam power process, which in turn contains a steam turbine installed downstream of the steam generator and a condenser installed downstream of the steam generator. turbine. In this method, the energy released during combustion is at least partially used to generate electricity. More specifically, the extracted energy is initially at least partially used in a steam generator to produce steam, and then the generated steam is at least partially fed to a steam turbine which drives a generator to generate electricity. The steam may also be at least partially withdrawn and supplied for use as a heat source, for example for heating or heating.

If the power generation device of the plant comprises a gas turbine and/or a gas engine, a generator driven by the gas turbine and/or gas engine serves to generate electricity in accordance with the method.

According to another embodiment of the method, the composition or calorific value of the gas (tail gas or acid gas or mixture of tail gas and acid gas) supplied to the power generation device in step d1) is determined before combustion in the combustion device. The detected composition is compared to a target composition or a target composition range and/or the detected calorific value is compared to a target calorific value or a target calorific value range. If there is a deviation from the specified composition and/or the specified composition range or the specified calorific value and/or the specified calorific value range, an additional proportion of natural gas necessary for correction is set and added to the gas before combustion.

For example, a given composition or a given composition range may include the following mole percentages:

Hydrogen sulfide: 3% to 70%, in particular 40% to 60%, preferably about 50%, and/or

Carbon dioxide: 10% to 90%, in particular 40% to 60%, preferably about 50%.

Alternatively or additionally, the target calorific value or the target calorific value range may be from 9 to 30 MJ/m3 (at standard conditions), in particular from 15 to 25 MJ/m3 (at standard conditions), preferably about 20 MJ/m3 (at standard conditions). conditions).

In view of the fact that flue gaseous products have a very high content of sulfur oxide (especially sulfur dioxide and sulfur trioxide) compared to conventional flue gaseous products, it may be advantageous to provide a multi-stage exhaust gas desulfurization system, preferably comprising a fixed bed reactor for sulfur trioxide separation and an ash catcher (wet ash catcher) for separating sulfur dioxide. The examples and explanations regarding the exhaust gas desulfurization system as a device apply equally to the method.

According to another embodiment of the method, the gypsum produced in the process of exhaust gas desulfurization is fed into the gypsum plant in order to obtain gypsum products, in particular gypsum boards and/or ready-made gypsum plaster mixtures.

The above gypsum plant can be fully or partially supplied with electricity from the electricity generated in step d1). The gypsum plant can also fully or partially meet its heat requirements from the combustion gases generated during combustion in step dl) and/or from power generation, in particular in the thermodynamic circuit of the steam power process.

If it is intended to meet all or part of the heat demand from the steam-powered process, the steam can be removed and supplied to the gypsum plant for heating or heating. For example, steam can be used to supply heat to a dryer and/or calciner in a gypsum plant. The significant advantage here is that carbon dioxide emissions to the environment can be avoided in this way.

The invention, its features and advantages, are explained in more detail below based on the description of embodiments with reference to the accompanying drawings, in which:

In FIG. 1 shows a variant of the apparatus according to the invention for the desulfurization of crude oil.

In FIG. 2 shows a first version of a plant for the production of electricity and gypsum.

In FIG. 3 shows a second version of the installation for the production of electricity and gypsum.

In FIG. 4 shows a third embodiment of a plant for the production of electricity and gypsum.

Corresponding parts and components are designated in the drawings by the same reference numbers.

In FIG. 1 shows an embodiment of an apparatus 100 according to the invention for the desulfurization of a sulphurous crude oil. The drawing also illustrates a crude oil desulfurization process according to the invention.

The apparatus 100 includes a desulfurization system 102 to which sulphurous crude oil 101 is fed. The desulfurization system 102 includes a hydrogenation system 102a, preferably a hydrotreater, and an amine treatment system 102b. During the desulfurization of the sour crude oil 101 in the desulfurization system 102, due to the hydrogenation in the hydrogenation system 102a and the amine treatment in the system 102b, sweet crude oil 103 and hydrogen sulfide acid gas 104 are formed. The sweetened crude oil 103 can be delivered to consumers, if necessary after additional processing steps.

The apparatus 100 further comprises a system 106 for recovering elemental sulfur 107, such as a Claus system for carrying out the Claus process. Sour gas 104 may be supplied from the desulfurization system 102 to the system 106 through the gas pipeline system 105, as described in more detail below. During the recovery of elemental sulfur 107 in system 106, in addition to elemental sulfur 107, a hydrogen sulfide-containing residual gas 108 is formed as off-gas.

Plant 1 for generating electricity 24 and gypsum 21 should be considered as an additional part of the device 100. Tail gas 108 or acid gas 104, or a mixture of acid gas 104 and tail gas 108 can enter the plant 1 through a gas pipeline system 105. Plant 1 includes a device 4 for power generation, comprising a combustion device 6 for combustion of the supplied gas, while the energy released during combustion, at least partially used to generate electricity. In addition, the plant 1 includes an exhaust gas desulfurization system for desulfurizing the sulfur oxide-containing exhaust gases 18 of combustion emitted during combustion by forming gypsum 21.

The aforementioned gas pipeline system 105 is used to supply acid gas 104 from the desulfurization system 102 to the system 106 to recover elemental sulfur 107 and to the plant 1 for the production of electricity 24 and gypsum 21, as well as to supply tail gas 108 from the system 106 to recover elemental sulfur 107 in installation 1 for the production of electricity 24 and gypsum 21. The gas pipeline system 105 has a gas distribution device 109, in the first position supplying acid gas exclusively to the system 106 for the extraction of elemental sulfur 107, in the second position supplying acid gas exclusively to the installation 1 for the production of electricity 24 and gypsum 21, and in the distributing position, feeding the first part of acid gas 104 to the system 106 for recovering elemental sulfur 107, and the second part of acid gas 104 to the plant 1 for generating electricity 24 and gypsum 21. The ratio between the first and second parts of acid gas 104 can be adjusted in the distribution position using the gas distribution device 109.

In FIG. 2-4 show three different installations 1 for the production of electricity and gypsum. Thus, these drawings also illustrate the method of producing electricity and gypsum.

In all three embodiments, tail gas supply 108 and/or acid gas 104 is shown on the left. As indicated above, each gas can enter plant 1 individually or as a mixture of residual gas 108 and acid gas 104 and thus be used in the process for producing electricity and gypsum.

More specifically, the gas is fed into the device 4 for generating electricity and burned there, preferably with the supply of air 5, while the energy released during combustion is at least partially used for generating electricity.

In all considered embodiments, it is shown that before being fed into the device 4 for generating electricity, the gas is passed through a gas mixer 17 designed to obtain a gas 3 whose composition corresponds to a given composition and/or a given composition range and/or whose calorific value corresponds to a given calorific value and /or a given calorific value range. Examples of such a target composition or target range of composition and such target calorific value or target range of calorific value are given above in the general description. The gas mixer 17 is not absolutely necessary for the implementation of the invention.

The gas mixer 17 includes a measuring device 12, which detects the composition and/or calorific value of the incoming hydrogen sulfide-containing gases 3 (tail gas 108 or acid gas 104 or a mixture of tail gas 108 and acid gas 104). The gas mixer 17 further comprises an analysis apparatus 13 which compares the detected composition with a given composition or a given composition range, or a detected calorific value with a given calorific value or a given calorific value range.

In addition, the gas mixer 17 includes a control device 14 and a supply device 15 for supplying natural gas. When the analyzer 13 detects a deviation from the target composition and/or the target composition range or the target calorific value and/or the target calorific value range, the control device 14 sets the additional proportion of natural gas required for correction and cooperates with the supply device 15 so that the set the part of the natural gas required for correction is added to the gas 3 through the supply device 15 as make-up gas 16 before combustion. , using a gas distribution device 109.

Then, hydrogen sulfide-containing gases 3, whose composition may have been adjusted, are fed into the device 4 for generating electricity. The power generation device 4 in the embodiment of FIG. 2 contains the thermodynamic circuit 11 of the steam power process. To this end, the power generation device 4 comprises, as a combustion device 6, a steam generator into which the gas 3 is fed. The hydrogen sulfide-containing gases 3 are burned in the air-fed steam generator 5, preferably at a combustion temperature of at least 1000°C. The released energy is at least partially used in the steam generator to generate steam.

The device 4 for generating electricity further comprises a steam turbine 7. The steam 10 generated by the steam generator enters the steam turbine 7. The steam turbine 7, in turn, is connected to the generator 8, which is driven by the steam turbine 7, to generate electricity 24. electricity 24 may be fed into the public grid 25 and/or provided to consumers of electricity.

The power generation device 4 further comprises a condenser 9 located downstream of the steam turbine 7, ie, after flowing through the steam turbine 7, the steam 10 enters the condenser 9. The condenser 9 is preferably air-cooled.

After condensation in the condenser 9, the condensed liquid and/or steam, if still present, flows back into the combustion device 6 (in this case the steam generator) and thus the thermodynamic circuit 11 of the steam power process is closed.

It is also possible that the thermodynamic circuit 11 is interrupted and the thermal energy still contained in the steam after passing through the steam turbine 7 is used for other purposes, such as heating using local or district heating systems, in accordance with conventional heat transfer technology. In this case, water for compensation must be supplied to the thermodynamic circuit 11 of the steam-power process of the device 4 for generating electricity before the steam generator, i.e. there is this process no longer goes along the contour in the truest sense of the word. This option is not shown in the drawings.

When the hydrogen sulfide-containing gases 3 are burned in the combustion device 6 (in this case, the steam generator), combustion gases 18 are generated. They are fed into the exhaust gas desulfurization system 19, cleaned there and then released as purified exhaust gas 20, for example directly into the environment, but additional exhaust gas purification steps are also possible before or after the system 19 .

Due to the high content of hydrogen sulfide in the feed gases, the combustion gases 18 have a very high proportion of sulfur dioxide and sulfur trioxide compared to the exhaust combustion gases of known systems. Accordingly, a suitable exhaust gas desulfurization system 19 should be provided, such as a multi-stage exhaust gas desulfurization system, preferably comprising a fixed bed reactor for separating sulfur trioxide and an ash collector for separating sulfur dioxide. The water required for exhaust gas desulfurization can be obtained from the sea using sea water pumps if the unit is located near the sea. After passing through the exhaust gas desulfurization system 19, the purified exhaust gas 20 can be released into the environment.

During exhaust gas desulfurization using the exhaust gas desulfurization system 19, gypsum 21 is produced, which enters the gypsum shop 22 for the production of gypsum products 23. For example, in this gypsum shop 22, gypsum boards or ready-made gypsum plaster mixtures are produced using gypsum 21 .

The gypsum plant 22 is organized in such a way that it fully or partially satisfies its electricity needs from the electricity generated by the electricity generation device 4, i.e. the gypsum plant 22 is one of the aforementioned power consumers, to which the power generation device 4 supplies the power 24 generated by the combustion of the exhaust air containing hydrogen sulfide.

In addition, the gypsum plant 22 fully or partially satisfies its heat demand by extracting steam 26 from the above-described thermodynamic circuit 11 of the steam-powered process of the device 4 for generating electricity and extracting thermal energy from this diverted steam 26 for heating. For example, the exhausted steam 26 can be used in this way to fire the gypsum 21 and/or to dry the gypsum board in the gypsum shop 22.

After the described use as a heat source, the removed steam 26 can be released or used in some other way. In this case, in order to compensate for the discharged steam, it is necessary to supply water to the thermodynamic circuit 11 of the steam power process of the device 4 for generating electricity. Also, the removed steam 26, after being used as a heat source, can be fed back into the thermodynamic circuit 11 of the steam-powered process of the power generation device 4, so that this circuit still remains substantially closed to steam. The direction of the withdrawn steam 26 after being used as a heat source further and, if necessary, the supply of water to the thermodynamic circuit 11 are not illustrated in FIG. 2.

The second embodiment according to FIG. 3 and the third embodiment according to FIG. 4 correspond to the first embodiment with respect to the gas supply and the gas mixer 17, and thus the above explanations regarding FIG. 2.

However, the second and third embodiments described differ from the first embodiment in the power generation device 4 used. In the second version, the device 4 for generating electricity instead of a steam-power process contains a gas turbine 27, and in the third version, a gas engine 28, and a compressor 31 is installed in front of each of them to supply gas 3. Hydrogen sulfide-containing gases 3, the composition of which may have been adjusted, are supplied into this gas turbine 27 or into this gas engine 28 and burned in the gas turbine 27 or gas engine 28 with air supply 5, preferably at a combustion temperature of at least 1000°C. The gas turbine 27 or gas engine 28 is coupled or coupled to a generator 8 which is driven by the gas turbine 27 or gas engine 28 to generate electricity 24. As in the first embodiment of FIG. 1, the generated electricity 24, in turn, can be fed into the general network 25 and/or be provided to consumers of electricity.

When hydrogen sulfide-containing gases 3 are burned in a gas turbine 27 or a gas engine 28, combustion gases 18 are generated. Before they are sent further to the exhaust gas desulfurization system 19, they are passed through a heat exchanger 29 for further use of their energy. In the heat exchanger 29, heat energy is obtained from the combustion gases 18 and supplied to the gypsum plant 22 using a suitable hydraulic circuit 30, so that the heat demand of the gypsum plant 22 can be fully or partially satisfied. Thus, for example, the heat extracted from the combustion gases 18 can be used for firing gypsum 21 and/or for drying gypsum boards in the gypsum plant 22.

All features of the further direction of the combustion gases 18, the exhaust gas desulfurization system 19 and the gypsum plant 22 correspond to the solution already discussed in connection with the first embodiment in accordance with FIG. 2, and thus the above explanations should be referred to in this regard.

List of license plates

1 Plant for the production of electricity and gypsum

3 Gas

4 Electric generator

5 Air

6 Incinerator

7 Steam turbine

8 Generator

9 Capacitor

10 pairs

11 Thermodynamic cycle of the steam power process

12 Measuring device

13 Analyzing apparatus

14 Control unit

15 feeder

16 Make-up natural gas

17 Gas mixer

18 Combustion gases

19 Exhaust gas desulfurization system

20 Purified exhaust gas

21 Gypsum

22 Gypsum shop

23 Plaster products

24 Electricity

25 Public network

26 Steam used for heat for the gypsum shop

27 Gas turbine

28 Gas engine

29 Heat exchanger

30 Hydraulic circuit

31 Compressor

100 Crude oil desulfurizer

101 Sulfur crude oil

102 Sour crude oil desulfurization system

102а Hydrogenation system

102b Amine cleaning system

103 Sweet oil

104 Sour gas

105 Gas pipeline system

106 Elemental sulfur recovery system

107 from acid gas 104

107 Elemental sulfur

108 Residual gas

109 Gas distributor

Claims (55)

1. Device (100) for desulfurization of crude oil, containing a) a desulfurization system (102) for sour crude oil (101), in which, in addition to the sweetened crude oil (103), hydrogen sulfide acid gas (104) is formed, b) a system (106) for recovering from the acid gas (104) formed in the desulfurization system (102), elemental sulfur (107) and hydrogen sulfide tail gas (108) as off-gas, and c) plant (1) for the production of electricity (24) and gypsum (21) from residual gas (108), or acid gas (104), or from a mixture of acid gas (104) and residual gas (108), while the device is additionally contains c1) a device for generating electricity (4), containing a combustion device (6) for burning tail gas (108), or acid gas (104), or a mixture of tail gas (108) and acid gas (104), while the energy released when incinerated, at least partly used to generate electricity, c2) an exhaust gas desulfurization system (19) for desulfurizing the sulfur oxide-containing exhaust gaseous combustion products (18) released during combustion by forming gypsum (21), d) a gas pipeline system (105) for supplying acid gas (104) from the desulfurization system (102) to the system (106) for the extraction of elemental sulfur (107) and to the plant (1) for the production of electricity (24) and gypsum (21), and also for supplying the residual gas (108) from the system (106) for extracting elemental sulfur (107) to the installation (1) for the production of electricity (24) and gypsum (21), and d1) the gas pipeline system (105) has a gas distribution device (109), which in the first position supplies acid gas exclusively to the system (106) for the extraction of elemental sulfur (107), in the second position supplies acid gas exclusively to the installation (1) for the production of electricity (24) and gypsum (21), and in the distributing position feeds the first part of the acid gas (104) to the system (106) for the extraction of elemental sulfur (107), and the second part of the acid gas (104) to the installation (1) for the production of electricity (24) and gypsum (21). 2. Device (100) according to claim 1, wherein the combustion device (6) of the device (4) for generating electricity contains a steam generator or is a steam generator, which is part of the thermodynamic circuit (11) of the steam power process, which, in turn, contains a steam turbine (7) installed behind the steam generator, and a condenser ( 9) installed behind the steam turbine (7), while a generator (8) driven by a steam turbine (7) serves to generate electricity. 3. Device (100) according to claim 1 or 2, wherein the device (4) for generating electricity contains a gas turbine (27) and/or a gas engine (28), and a generator (8) driven by a gas turbine (27) and/or a gas engine (28) serves to generate electricity. 4. The device (100) according to any one of paragraphs. 1-3, further comprising a measuring device (12) for determining the composition and/or calorific value of the gas before combustion in the combustion device (6), an analyzing apparatus (13) for comparing said detected composition with a given composition or a given composition range and/or for comparing said detected calorific value with a given calorific value or given calorific value range, and a control device (14) and a supply device (15) for supplying natural gas (16), while when the analyzing apparatus (13) detects a deviation from the specified composition, and/or the specified composition range or the specified calorific value, and/or the specified range calorific value, the control device (14) determines the additional proportion of natural gas required for correction and adds it to the gas (3) using a supply device (15) before combustion. 5. Device (100) according to claim 4, wherein the specified composition or specified composition range includes the following mole percentages: hydrogen sulfide: 3% to 70%, in particular 40% to 60%, preferably about 50%, and/or carbon dioxide: 10% to 90%, in particular 40% to 60%, preferably about 50%, and/or the target calorific value or target calorific value range is 9 to 30 MJ/m ³ (under standard conditions), in particular 15 to 25 MJ/m ³ (under standard conditions), preferably about 20 MJ/m ³ (under standard conditions). ). 6. The device (100) according to any one of paragraphs. 1-5, in which the installation (1) for the production of electricity (24) and gypsum (21) contains a gypsum plant (22), in which gypsum (21) obtained from the exhaust gas desulfurization process (19) is used to produce gypsum products (23), in particular gypsum boards and/or pre-mixed gypsum plasters. 7. Device (100) according to claim 6, wherein the gypsum plant (22) fully or partially satisfies its electricity needs using electricity from the device (4) for generating electricity, and/or the gypsum plant (22) fully or partially satisfies its heat demand using gaseous combustion products (18) generated by the combustion of gases in the combustion device (6) and/or during power generation, in particular in the thermodynamic circuit (11) of the steam power process . 8. A method for desulfurizing crude oil using a device according to any one of the preceding claims, comprising the following steps: (a) Ensuring the availability of sulphurous crude oil (101); b) desulfurization of the sulphurous crude oil (101) using a desulfurization system (102) in which, in addition to the sweetened crude oil (103), hydrogen sulfide acid gas (104) is formed; c) installing the gas distribution device (109) of the gas pipeline system (105) in the first position, or in the second position, or in the distribution position, while in the first position, acid gas is supplied exclusively to the system (106) for the extraction of elemental sulfur (107), during in the second position, the acid gas is supplied exclusively to the installation (1) for the production of electricity (24) and gypsum (21), and in the distribution position, the first part of the acid gas (104) is fed to the system (106) for the extraction of elemental sulfur (107), and the second part of the acid gas (104) is fed into the installation (1) for the production of electricity (24) and gypsum (21); d) production of electricity (24) and gypsum (21) from residual gas (108) or acid gas (104) or from a mixture of acid gas (104) and residual gas (108) using an installation (1) for the production of electricity ( 24) and gypsum (21), and d1) tail gas (108), or acid gas (104), or a mixture of tail gas (108) and acid gas (104) is fed into the combustion device (6) of the device (4) for generating electricity and burns there, the energy released during incineration, at least partially used to generate electricity, d2) containing sulfur oxide, the exhaust gaseous products (18) of combustion obtained during combustion are fed to exhaust gas desulfurization using an exhaust gas desulfurization system (19), and d3) gypsum (21) is formed during desulfurization of the exhaust gases. 9. The method according to claim 8, wherein the combustion in step d1) takes place at a combustion temperature of at least 1000°C. 10. The method according to claim 8 or 9, in which the combustion device (6) of the device (4) for generating electricity contains a steam generator or is a steam generator, which is part of the thermodynamic circuit (11) of the steam power process, which, in turn, contains a steam turbine (7) installed behind the steam generator, and a condenser ( 9) installed after the steam turbine (7), while the energy released during combustion is at least partially used to generate electricity, namely, the released energy is initially at least partially used in the steam generator to produce steam, and the generated steam is at least partially supplied to the steam turbine (7), which drives in operation generator (8) to generate electricity. 11. The method according to any one of paragraphs. 8-10, in which the device (4) for generating electricity contains a gas turbine (27) and/or a gas engine (28), and a generator (8) driven by a gas turbine (27) and/or a gas engine (28) serves to generate electricity. 12. The method according to any one of paragraphs. 8-11, in which before combustion in the combustion device, the composition and/or calorific value of the gas supplied to the device (4) for generating electricity in step d1), the detected composition is compared to a given composition or a given composition range and/or the detected calorific value is compared to a given calorific value or to a given calorific value range, and if there is a deviation from the specified composition or the specified composition range and/or the specified calorific value or the specified calorific value range, an additional proportion of natural gas necessary for correction is determined and added to the gas before combustion. 13. The method according to claim 12, in which the specified composition or specified composition range includes the following mole percentages: hydrogen sulfide: 3% to 70%, in particular 40% to 60%, preferably about 50%, and/or carbon dioxide: 10% to 90%, in particular 40% to 60%, preferably about 50%. and/or the target calorific value or target range of calorific value is from 9 to 30 MJ/m ³ (under standard conditions), in particular from 15 to 25 MJ/m ³ (under standard conditions), preferably about 20 MJ/m ³ ( under standard conditions). 14. The method according to any one of paragraphs. 8-13, in which the gypsum (21) produced by desulfurization (19) of exhaust gases enters the gypsum plant (22) to produce gypsum products (23), in particular gypsum boards and/or ready-made gypsum plaster mixtures. 15. The method according to claim 14, in which the gypsum plant (22) fully or partially satisfies its electricity needs using the electricity produced in step d1), and/or the gypsum plant (22) fully or partially satisfies its heat demand using the gaseous combustion products (18) resulting from the combustion of gases in step d1) and/or during power generation, in particular in the thermodynamic circuit (11) of the steam power process.

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