DE10110462A1 - Cooling system, for dehydration of iso-butane to iso-butylene, has structured circuits for coolant/coolant mixture flows through heat exchanger - Google Patents

Abstract

To reduce flows to a low temperature, the complete condensation of the coolant/coolant mixture is initially in a heat exchanger with the circuits (100-107). The coolant/coolant mixture is in a closed or an open circuit. The coolant/coolant mixture is comprises methane, ethane, ethylene, propane, propylene, butane, nitrogen, or they are used in a mixture with two or three coolants as the components, which can contain hydrogen. The heat exchanger is a plate type.

Description

The invention relates to a process for the low-temperature decomposition of a stream consisting essentially of hydrogen, methane and C ₃ -, C ₄ - or C ₃ / C ₄ hydrocarbons, the hydrogen obtained in the decomposition by cooling and partial condensation of this stream at least partially to a the purpose of cooling supply performed by the low-temperature fractionation, C ₃ -, C ₄ - or C ₃ / C ₄ hydrocarbon-rich stream is mixed, while the not the C ₃ - _4-rich hydrocarbon or C ₃ / C -, C ₄ Hydrogen added to the stream and the hydrocarbon obtained from the decomposition of the stream consisting essentially of hydrogen, methane and C ₃ -, C ₄ - or C ₃ / C ₄ -hydrocarbons, C ₃ -, C ₄ - or C ₃ / C ₄ -hydrocarbons - Rich electricity is withdrawn from the decomposition after prior heating and evaporation and the cooling and partial condensation of the essentially hydrogen, methane and C ₃ -, C ₄ - or C ₃ / C ₄ hydrocarbons existing substances and the heating and evaporation of the C ₃ -, C ₄ - or C ₃ / C ₄ hydrocarbon-rich stream, to which at least part of the hydrogen is admixed, is carried out in a single heat exchanger.

Generic processes for the low-temperature decomposition of a stream consisting essentially of hydrogen, methane and C ₃ -, C ₄ - or C ₃ / C ₄ -hydrocarbons are found, for example, in the cryogenic decomposition of the from the dehydrogenation reactor downstream of the dehydrogenation of isobutane to isobutene originating product flow use. The dehydrogenation of isobutane to isobutene plays an important role especially in the production of MTBE (methyl tert-butyl ether), since isobutene and methanol are required for the production of MTBE. Due to the increasingly strict exhaust gas regulations for motor vehicles, the consumption of MTBE, which is used as an octane number improver for fuels, will increase in the following years. While methanol is available in sufficient quantities, there is a significant shortage of isobutene.

From DE-PS 196 44 106 a generic method for the low-temperature decomposition of a stream consisting essentially of hydrogen, methane and C ₃ -, C ₄ - or C ₃ / C ₄ hydrocarbons is known, which is shown on the basis of FIG. 1 Embodiment will be explained in more detail.

The line drawn in dashed lines in FIG. 1 encloses the area which is implemented in practice as a so-called cold box. Not shown in FIG. 1 are the dehydrogenation stage or stages as well as compression and optionally pretreatment steps.

The liquid hydrocarbon-rich feed stream supplied, for example, to a dehydrogenation is conducted via line 1 to the low-temperature decomposition or the heat exchanger E3. In this, it is subcooled against process flows to be heated. This stream is withdrawn from the heat exchanger E3 via line 2 and then divided into two partial streams 3 and 4 . Both partial streams 3 and 4 will be mixed in the following with a hydrogen-rich stream.

For this purpose, the first partial stream 3 is first expanded in the valve a and then mixed with the hydrogen-rich stream in line 6 upstream or in the heat exchanger E1. The second partial stream 4 is further subcooled in the heat exchanger E2, expanded in the valve b and then admixed via line 5 to the hydrogen-rich gas stream in line 16 . This hydrogen-rich gas stream in line 6 or 16 and its origin will be discussed in the following.

The mixture stream from the hydrogen and hydrocarbon-rich stream withdrawn via line 7 from the heat exchanger E1 is now fed, for example, to a single-stage or multi-stage dehydrogenation. The reaction product withdrawn from the dehydrogenation is then compressed in one or more stages, if appropriate a pretreatment such as. B. drying, HCl removal, etc., subjected and fed as an essentially consisting of hydrogen, methane and C ₃ hydrocarbons via line 8 again the low-temperature decomposition or the heat exchanger E1. This stream is cooled in the heat exchanger E1 in the heat exchange with process streams to be heated, partially condensed and then fed via line 9 to a first separator D1.

At the top of the separator D1, a hydrogen-rich gas fraction is drawn off via line 10 , cooled in the heat exchanger E2 and partially condensed and then fed via line 11 to a second separator D2. A C ₃ hydrocarbon-rich liquid fraction is drawn off from the bottom of the separator D1 via valve c and line 30 and fed to a third separator D3.

A C ₃ hydrocarbon-rich liquid fraction is likewise drawn off from the bottom of the separator D2 via line 12 and valve d and fed to the separator D3. At the head of the separator D2, a hydrogen-rich gas fraction is drawn off via line 13 and heated in the heat exchanger E2 against process streams to be cooled. The heated gas fraction is fed to the heat exchanger E3 via line 20 , further heated in the latter against process streams to be cooled, and then discharged via line 21 from the low-temperature decomposition.

A partial flow of the hydrogen-rich gas fraction supplied to the heat exchanger E2 via line 13 is first fed via line 14 to a first expansion turbine T1, via line 15 to a second expansion turbine T2 and then via line 16 to the heat exchanger E2, before or immediately during the supply to the Heat exchanger E2 is mixed with the hydrocarbon-rich liquid fraction in line 5 . The energy released in the expansion of the hydrogen-rich gas fraction in the expansion turbines T1 and T2, which relieves the cold and work, can be used, for example, to generate electricity.

At the top of the separator D3, a methane-rich gas stream is drawn off via line 23 , which under certain circumstances can be returned to the compression and pretreatment steps. A C ₃ hydrocarbon-rich product fraction is drawn off from the bottom of the separator D3, pumped to the desired discharge pressure by means of the pump P and then fed to the heat exchanger E3 via line 25 . In this, the product fraction is warmed and evaporated against process streams to be cooled and then led out of the low-temperature decomposition via line 26 .

A partial stream of the product fraction fed to the heat exchanger E3 in the line 25 can be fed to the heat exchanger E1 via line 27 and used in the latter for providing cooling. From the heat exchanger E1, this part of the product fraction is then admixed again to the product fraction in line 26 via control valve e and line 28 .

In the above procedure, however, bottlenecks sometimes occur Heat transfer on. The reason for this is an overlap in the Q / T Diagram. In order to fix this, external cooling has so far been required on the Temperature level used to increase this overlap in the heat transfer avoid. However, this requires the provision of additional cooling capacity, which then it would not be necessary, if it were possible, to shift the sufficient To achieve cold supply to the required temperature level.

The object of the present invention is to provide a generic method for the low-temperature decomposition of a feed stream consisting essentially of hydrogen, methane and C ₃ -, C ₄ - or C ₃ / C ₄ hydrocarbons, which avoids the disadvantages mentioned.

This is achieved according to the invention in that the heat exchanger at least a refrigerant or mixed refrigerant circuit is assigned.

Further developing the method according to the invention it is proposed that the complete condensation of the refrigerant or the refrigerant mixture of the Refrigerant or refrigerant mixture circuit only in the heat exchanger to which the Refrigerant or mixed refrigerant circuit is assigned.

The refrigerants or refrigerant mixtures used are preferably methane, ethane, Ethylene, propane, propylene, butane, nitrogen or two or more components Mixtures of the aforementioned components, which also contain hydrogen can used.

The refrigerant or refrigerant mixture circuit can be an open or closed circuit are operated.  

The additional refrigerant or The refrigerant mixture circuit now serves as a heat pump, by means of which the cooling capacity is available at a higher temperature level in excess on that Temperature level is shifted at which there is a lack of cold.

The method according to the invention will be explained in more detail with reference to FIG. 2; This shows the heat exchanger E1 already shown in FIG. 1, the process streams 3 , 6 to 9 , 27 and 28 leading through it - the composition of which is explained in detail in the description of the figures 1 - and the refrigerant or refrigerant mixture circuit to be provided according to the invention.

The refrigerant or mixture of refrigerants, which is fed via line 107 to a one-stage or multi-stage compression 101, is fed via line 100 to a heat exchanger 102 after compression and is cooled therein, for example against cooling water or air, and preferably not condensed. The refrigerant or refrigerant mixture is then fed via line 103 to the heat exchanger E1 and partially, but preferably completely, condensed therein. The condensation takes place in a temperature range in which a sufficient supply of cold can be used by other cold currents. In particular, there is a large temperature difference in the area of the dew point of the current 7 described above, the driving force of which can be used. In this way, a heat pump can be integrated that uses excess cooling in the warmer part of the heat exchanger E1 to compensate for a lack of cold in the colder part of the heat exchanger E1.

The refrigerant or mixture of refrigerants is then fed via line 104 to an expansion valve 105 , expanded there to a lower pressure, and then again fed via line 106 to the heat exchanger E1 and evaporated therein. The pressure of the re-evaporation is chosen so that a prevailing lack of cold is eliminated in the temperature range of the evaporation. The vaporized refrigerant or mixture of refrigerants is then, as already described, fed back to the single-stage or multi-stage compression 101 via line 107 and compressed to the original pressure therein and then cooled again to the original temperature.

The procedure described above can be used particularly advantageously if a lack of cold below approx. -40 ° C should be remedied. To solve this So far, a complex refrigeration system was required, which required high investment and Had operating costs.

The method according to the invention thus enables the known ones Solutions to reduce investment costs and energy consumption.

A further embodiment of the method according to the invention is characterized in that as a heat exchanger for the heat exchange between the stream consisting essentially of hydrogen, methane and C ₃ , C ₄ - or C ₃ / C ₄ hydrocarbons and the C ₃ -, C ₄ - or C ₃ / C ₄ hydrocarbon-rich dehydrogenation stream, a plate heat exchanger, preferably an aluminum plate heat exchanger, is used.

Claims (5)

1. A process for the low-temperature decomposition of a stream consisting essentially of hydrogen, methane and C ₃ -, C ₄ - or C ₃ / C ₄ -hydrocarbons, the hydrogen obtained in the decomposition by cooling and partial condensation of this stream at least partially for the purpose of cooling supply performed by the low-temperature fractionation, C ₃ -, C ₄ - or C ₃ / C ₄ hydrocarbon-rich stream is mixed, while the not the C ₃ -, C ₄ - or C ₃ / C ₄ hydrocarbon-rich stream admixed Hydrogen and the C ₃ -, C ₄ - or C ₃ / C ₄ -hydrocarbon-rich obtained from the decomposition of the stream consisting essentially of hydrogen, methane and C ₃ -, C ₄ - or C ₃ / C ₄ -hydrocarbons Electricity is withdrawn from the decomposition after prior heating and evaporation and the cooling and partial condensation of the stream consisting essentially of hydrogen, methane and C ₃ -, C ₄ - or C ₃ / C ₄ hydrocarbons mes ( 8 ) and the heating and evaporation of the C ₃ -, C ₄ - or C ₃ / C ₄ -hydrocarbon-rich stream, to which at least part of the hydrogen is admixed, takes place in a single heat exchanger, characterized in that the heat exchanger (E1) at least one refrigerant or mixed refrigerant circuit ( 100 , 101 , 102 , 103 , 104 , 105 , 106 , 107 ) is assigned. 2. The method according to claim 1, characterized in that the complete condensation of the refrigerant or the refrigerant mixture of the refrigerant or refrigerant mixture circuit ( 100 , 101 , 102 , 103 , 104 , 105 , 106 , 107 ) only in the heat exchanger (E1), to which the refrigerant or refrigerant mixture circuit ( 100 , 101 , 102 , 103 , 104 , 105 , 106 , 107 ) is assigned. 3. The method according to claim 1 or 2, characterized in that the refrigerant or mixed refrigerant circuit as an open or closed circuit is operated.   4. The method according to any one of the preceding claims 1 to 3, characterized characterized in that as refrigerant or refrigerant mixtures methane, ethane, Ethylene, propane, propylene, butane, nitrogen or two or more components Mixtures of the aforementioned components, which also contain hydrogen can be used. 5. The method according to any one of the preceding claims 1 to 4, characterized in that as a heat exchanger for the heat exchange between the essentially consisting of hydrogen, methane and C ₃ -, C ₄ - or C ₃ / C ₄ hydrocarbons and the current C ₃ , C ₄ - or C ₃ / C ₄ hydrocarbon-rich dehydrogenation stream a plate heat exchanger, preferably an aluminum plate heat exchanger, is used.