KR820001970B1 - Combination coal liquefaction-gasification process - Google Patents

Abstract

Bituminous coal was gasified and liquefied in a combined process that gave increased thermal efficiency and included the steps of hydroliquefaction, oxidative gasification to make systhesis gas, and use of the shift reaction to produce addnl. H from the synthesis gas. Thus, dry pulverized bituminous coal was mixed with a recycle solvent-contg. slurry from the process and then hydrogenated at 820-870≰C. The product was sepd. by vacuum distn., and the residue from vacuum distn. was gasified with O to give synthesis gas(H/CO <= 1). The synthesis gas was passed through a shift reactor to produce addnl. H, and the gas after purifn. was recycled to the liquefaction step.

Description

Integrated Coal Liquefaction and Vaporization Methods

1 is the thermal efficiency curve of the coal coal liquefaction-gasification process.

2 is a process diagram for carrying out the present invention.

The present invention relates to a mixed coal liquefaction and vaporization process in which a coal liquefaction apparatus and an oxidizer are cooperatively merged together to enhance thermal efficiency. The feed coal of this apparatus contains bituminous coal, sub-bituminous coal or lignite.

The liquefaction zone of the device of the present invention provides for carrying out the preheating step of endotherm and the dissolving step of exotherm. The temperature of the melter is higher than the maximum preheating temperature due to the hydrogenation and hydrocracking reactions occurring in the melter. In processes containing liquid and usually solid dissolved coal and suspended mineral residues, residual sludge produced in the dissolver or elsewhere is recycled through the preheater and dissolver stages. Gaseous hydrocarbons and liquid hydrocarbon distillates are recovered from the product separation unit of the liquefied stage. Part of the rare substance-containing residual slurry that does not recycle from the melter is passed to the atmospheric tower and the vacuum distillation column. Normally all liquid and gaseous material is removed from the top of the tower so that these materials are also substantially matte, while concentrated mineral-containing residual slurry is also recovered from the bottom of the vacuum tower (VTB).

The concentrated slurry contains all inorganic minerals and undissolved organic substances (UOM), which together are referred to herein as "mineral residues".

Liquid coal is usually described herein as "classification liquid" and "liquid coal" and refers to dissolved coal containing a process solvent that is liquid at room temperature.

The amount is always less than 10 or 15% by weight of the coal supply. The concentrated slurry also contains 454 ° C. + dissolved coal, which is solid at room temperature and is referred to herein as “usually solid dissolved coal”. The slurry is passed through a partially oxidized gaseous phase suitable to receive the supplied slurry for conversion into syngas, without the filtration step or other solid-liquid separation step and without the coke step or other step that destroys the slurry. This synthesis gas is a mixture of carbon monoxide and hydrogen.

This slurry is the only carbonaceous feed provided in the vaporization stage. An oxygen system is provided to remove nitrogen from the oxygen provided to the vaporizer and the resulting syngas is essentially nitrogen free.

Some syngas undergoes a shift reaction to convert it to hydrogen and carbon dioxide. Together with hydrogen sulfide, carbon dioxide is removed in an acid gas removal unit. All hydrogen gas-rich air streams thus produced are essentially used in the liquefaction process.

It is an important feature of the present invention that more syngas is produced than converted to a hydrogen rich air stream. At least 60, 70 or 80 mole% of the excess syngas is burned as fuel such that at least 60, 70, 80 and 100% of the heat content is recovered by in-process combustion. Syngas used as fuel in the process is not subjected to methanation or other hydrogen combustion reactions such as methanol production before combustion in the process. Excess syngas not used as fuel in the process is always less than 40, 30 or 20 mole percent of the gas and methane addition is usually applied to increase the calorific value of syngas by converting carbon monoxide to methane.

According to the present invention, the amount of hydrocarbonaceous material entering the vaporizer above VTB is not only at an appropriate level for generating the hydrogen demand of the preceding process required for the liquefaction zone by the partial oxidation reaction and the shift conversion reaction, but also a sufficient amount to generate the synthesis gas. The total combustion calorific value of this syngas is adequate to supply 5-100 percent of the baseline calorific value of the total energy required by the process, and this energy can be generated by or generated from the equipment. It is required in the form of fuel in the preheater and in the form of steam in the pump.

In the context of the present invention, the energy consumed in the pressure of the inherent vaporization stage is not considered an energy consumption process.

All carbonaceous material supplied to the vaporizer is considered a vaporizer feed rather than a fuel. Although the vaporizer feed is exposed to partial oxidation, this oxidizer is the reaction product of the vaporizer and is not a fuel gas. Of course, the energy required to produce vapor in the vaporizer is considered an energy consuming process because this energy is consumed outside the pressure of the vaporizer. The present invention is advantageous because the vapor demand of the vaporizer is relatively low for the following reasons.

Process energy not derived from syngas produced in the vaporizer is from selected non-premium gas and liquid hydrocarbonaceous feeds generated in the liquefaction zone, or from energy sources from the process, such as electrical energy. Or directly from both sources.

The vaporization zone is fully integrated into the liquefaction apparatus because the entire hydrocarbonaceous material supplied to the vaporization zone is condensed in the liquefaction zone, since almost all gaseous products produced in the vaporization zone are consumed as reactants or fuel by the liquefaction zone.

Hydrogenation and hydrocracking reactions occurring in the liquefaction stage of the liquefaction zone are variously separated in accordance with the present invention, which optimizes the merging process on the basis of thermal efficiency as compared to the mass balance apparatus of the prior art. Separation of the dissolver stage is set by temperature, hydrogen pressure, residence time and recycle rate of mineral residues.

The operation of this merging process on the basis of material balance is entirely different from the concept of operation. When the amount of hydrocarbonaceous material in the feed to the vaporizer is determined so that the total syngas product of the vaporizer can be shifted to produce a hydrogen-rich air stream containing the exact process hydrogen demand of the coalescing process, It works based on.

Optimizing this process on the basis of thermal efficiency requires process fluidity, in order to ensure that the evaporator emissions not only provide the total process hydrogen demand, but also provide much or all of the energy requirements of the combined process.

In addition to providing the total process hydrogen demand through the shift reaction, the vaporizer produces a sufficient amount of syngas and, when burned directly, at least about 5, 10, 20 or 50 to 100 based on the total energy requirements of the process. It supplies up to a percent, which contains electrical or purchased energy, except for the heat produced by the vaporizer. At least 60, 70, 80, or 90 mole percent of the total capacity of H ₂ and CO in this excess syngas, and up to 100 percent based on the aliquots or non-fractions of H ₂ and CO are methane in this process. It is combusted with fuel without addition reaction and hydrogenation reaction. If this gas and the process are not required as fuel, less than 40 percent of this gas can be added to methane and used as pipelin gas. Although the present liquefaction process is generally more efficient than the vaporization process, in the following examples it was expected that by moving some of the components from the liquefaction zone to the vaporization zone to produce methane, the process efficiency would be reduced, more Surprisingly, it can be seen that the thermal efficiency of the merging process is increased by accident by moving a portion of the process from the liquefaction zone to produce the synthesis gas for combustion in the process.

The prior art has already shown the merging of coal liquefaction and vaporization on the basis of hydrogen material resin. The title is "SRC-III Process, which is listed at the 3rd Annual International Conference on Coal Gasification and Liquefaction at the University of Pittsburgh", on August 3-5, 1976. K. Smid and d. M. It is stressed that the amount of organic material passed by the liquefied bed from the liquefied bed in the coal-liquefied-vaporizer, combined, should be sufficient to produce the hydrogen required for the process.

The energy passed here is not presented as a fuel between the liquefaction and vaporization zones and therefore never knew the feasibility of efficiency as described in FIG. 1 and discussed below.

From the description of FIG. 1, it can be seen that the optimum efficiency requires the energy to be passed between the two fuels and cannot be obtained through the hydrogen resin without passing the energy.

Since VTA contains all mineral residues as anomalies with all the usual solid dissolved coals produced in this process, and because all amounts of VTB pass directly to the vaporizer, the separation of mineral residues from the dissolved coals No steps, ie filtration, deposition, solvent-dependent deposition, solvent extraction of hydrogen-rich compounds containing mineral residues, centrifugation, or similar steps are required in this process. Also, mineral residue drying, generally solid dissolved coal cooling and treatment steps, or delayed coke stages or latex coke stages are not required for the apparatus of the coalescing process. Eliminating or avoiding each of these steps significantly enhances the thermal rate of the process.

A portion of the mineral residue-containing slurry is recycled through the liquefaction zone to increase the concentration of mineral residue at the dissolving stage. Since inorganic minerals in the mineral residues are catalysts for the hydrogenation and hydrocracking reactions taking place in the dissolvers stage, and because sulfur is a catalyst for the conversion of hydrogen sulfide soils and oxygen to water, the dissolvers size and residence time are By reducing the efficiency of the process.

Recycling these mineral residues can advantageously reduce the yield of solid dissolved coal, typically about one half, thereby increasing the yield of more useful liquid and hydrocarbon gas products and reducing the feed rate to the vaporizer stage.

Because of the mineral recycling, this process is called an autocatalyst and does not require an external catalyst and, moreover, tends to increase process efficiency.

It is a feature of the present invention that the recycle solvent does not require hydrogenation in the presence of an external subcatalyst in order to revive its hydrogen-donating ability.

Higher process efficiencies raise the melter temperature to at least about 20, 50, 100, or 200F (11.1, 27.8, 55.8 or 111.1C), or above the maximum preheater temperature, since the reactions occurring in the melter are exothermic. Requires.

Cooling the dissolver to counter this temperature difference requires the formation of quench hydrogen, which is added in the shift reaction, and the input of heat added to the preheating step to eliminate the temperature lag between the two poles.

Both of these consume more coal in the process and therefore tend to reduce the thermal efficiency of the process.

All impure coals supplied to the merger process are supplied to the liquefaction zone and not directly to the vaporization zone. The mineral residue-containing VTB slurry contains all hydrocarbonaceous material fed to the vaporizer. The liquefaction process can be operated with higher thermal efficiency than the vaporization process, which raises the solid dissolved coal product in normal yield. Part of the reason for the lower efficiency of the gasification process is that the partial oxidation gasification process produces syngas (CO and H ₂ ), and if hydrogen is the last gas product, a series of shift reactions that convert water to carbon monoxide and convert it to hydrogen. This is because it requires a step, or if the pipelin gas is the last gas product, it requires a series of shift reaction steps and methane addition steps.

A shift reaction step is required before the methane addition step to increase the H ₂ to CO ratio from about 0.6 to 3 to produce a gas for methane addition. Total impure coal feed passes through the liquefaction zone, converting some coal constituents into a higher efficiency premium product of the liquefaction zone, which is before the non-premium, usually solid, dissolved coal passes through the vaporization stage.

The exact amount of process hydrogen required is passed through all of the syngas shift reactors produced in the prior art merged coal liquefaction-vaporization plant cited above. Thus, the prior art process is exposed to firm mass resin pressure. However, this process represents a process for controlling the correct mass balance by supplying more than the amount of hydrocarbons required to produce process hydrogen to the vaporizer. Syngas produced in excess of the amount required to produce hydrogen is removed between vaporization systems such as partial oxidation zones and transition reaction zones. At least 60 percent of the removed portion, based on the calorific value of the combustion heat after treatment to remove the acid gas, can be used as fuel for the unit without the methane or hydrogenation step. Less than 40 percent of the amount always removed is passed through the shift reactor to produce commercial process hydrogen, methane can be used as pipelin gas, or converted to methanol or other fuels.

Therefore, almost all vaporizer products are consumed as reactants or energy sources in the apparatus. The remaining fuel requirement of the apparatus is supplied by the fuel produced in the liquefaction apparatus and the energy provided from external sources of the process.

The use of syngas or carbon monoxide-rich airflow as fuel in the process is an important feature of the present invention and thus contributes to the high efficiency of the process.

Syngas or carbon monoxide-rich air streams are not marketable as commercial fuels because they contain carbon monoxide, which are toxic and have lower calorific values than methane. However, this objection to the commercial use of syngas or carbon monoxide as fuel does not apply to the device of the present invention.

First, the process is already installed as a device to prevent the toxicity of carbon monoxide because it contains a syngas device. Such preventive devices would not be useful for devices that do not produce syngas.

Secondly, since syngas is applied as fuel at the site of the device, it does not require transportation to a remote location.

The cost of pumping pipelin gas is based on gas capacity and not on heat capacity. Therefore, the cost of transporting syngas or carbon monoxide based on the calorific value is higher than the cost of transporting methane.

However, the cost of transport is not critical since either syngas or carbon monoxide is used as fuel in the apparatus section according to the invention. The device can be installed at a site using syngas or carbon monoxide as a fuel without a methane addition step or a hydrogenation step, thereby improving thermal efficiency. It is illustrated next that if excess syngas is added to the methane and used as the pipelin gas, the benefits of the increased thermal efficiency achieved are reduced or lost. It is also illustrated next that if syngas is produced by the vaporizer in the excess amount required for process hydrogen and both of the excess syngas are methane-added, a reduction in thermal efficiency is achieved by combining the liquefaction and vaporization processes.

The thermal efficiency of the device is increased because 5-100 percent of the total energy requirement of the device, which contains fuel and electrical energy, can be obtained by direct combustion of the syngas produced in the vaporization zone.

It is surprising that the thermal efficiency of the liquefaction process can be increased by vaporizing the coal obtained from the liquefaction zone, rather than converting the solid dissolved coal, usually in the liquefaction zone, where coal vaporization is less efficient than coal liquefaction. This is because it is known as a conversion method. Therefore, since additives are required to generate process energy in addition to process hydrogen, it can be expected that the efficiency of the merging process is reduced by adding these additives to the vaporization zone. Moreover, it can be expected that the supply of coal already exposed to hydrogenation to the vaporizer is particularly inefficient compared to impure coal, since the vaporizer stage is an oxidation reaction.

Nevertheless, the vaporizer did not expect to increase the thermal efficiency of the combined process when producing not only process hydrogen but also all or a significant amount of device fuel.

As suggested by the present invention, in the coal liquefaction-gasification coalescing process, it is not expected to provide a more efficient coalescing process by moving a part of the process to the already described method and degree as the low efficiency vaporization zone in the high efficiency liquefaction zone.

In order to realize the benefits of increased thermal efficiency found in the present invention, a coal liquefaction-gasification coalescing apparatus is provided for transporting a part of syngas generated in a partial oxidation zone to one or more combustors provided with a combustion apparatus of syngas in the process. Conduit arrangements should be provided. First, the syngas is required to remove the hydrogen sulfide generated through the acid gas removal device, while the heat generation of the syngas is increased by the removal of carbon dioxide, and fine temperature control is performed in the burner using the syngas as a fuel. Make it possible.

In order to improve the proposed thermal and thermal efficiency, the syngas must pass through the combustor without the methane addition or hydrogenation steps of the intermediate syngas.

It is a feature of the present invention that a high temperature vaporization device is applied in the range of 1,204 ° C-1,982 ° C.

Due to this high temperature, process efficiency is enhanced by promoting the vaporization of all essential carbonaceous feeds to the vaporizer.

The high temperature of the vaporizer can be achieved by appropriately adjusting and controlling the rate of introduction of water vapor and oxygen into the vaporizer. The steam input rate affects the endothermic reaction of water vapor and carbon to produce CO and H ₂ , while the oxygen input rate affects the exothermic reaction of carbon and hydrogen to produce VTB.

Because of the high temperatures indicated above, the syngas produced according to the invention has a molar ratio of H ₂ to CO of 1 or less and even 0.9, 0.8 or 0.7 or less. However, the heat of combustion to CO ratio of H ₂ in the synthesis gas generation due to the same heat of combustion of CO and H ₂ is not lower than the combustion heat of the high synthesis gas. Therefore, the high temperature of the vaporizer of the present invention is advantageous for contributing to high thermal efficiency by possibly oxidizing almost all carbonaceous materials in the vaporizer.

However, these high temperatures do not present any significant disadvantages in terms of H ₂ and CO ratios because they use large amounts of syngas as fuel.

The low ratio of CO to H ₂ presents a significant disadvantage in the process where all syngas proceeds to hydrogenation.

Syngas may be split within this process based on aliquots or non-fractional distributions of the CO content of H ₂ .

If the syngas is split based on non-fractions, some syngas can be passed through a freeze separator or adsorber to separate carbon monoxide from hydrogen. The hydrogen-rich air stream is recovered and contained in an already produced sorghum stream going to the liquefaction stand. A carbon monoxide-rich air stream is recovered and mixed with all syngas fuels containing aliquots of H ₂ and CO or applied as plant fuel independently.

Applying a refrigerator, adsorber or other device to separate hydrogen from carbon monoxide contributes to process efficiency because hydrogen and carbon monoxide show the same heat of combustion, but hydrogen is more useful as a reactant than as a fuel.

Removing hydrogen from carbon monoxide is particularly advantageous in processes where the appropriate carbon monoxide is useful to meet most process fuel requirements. It can be seen that the removal of hydrogen from the syngas fuel can substantially increase the calorific value of the remaining carbon monoxide-rich air stream. Indicates the amount of heat generated 300BTU / SCF (2,670Cal · kg / M 3) having a synthesis gas stream has an increased amount of heat generated sikimeuro remove the hydrogen content 321BUT / SCF thereof ^{(2,857Cal · kg / M 3)} . This process, which can be used interchangeably with all syngas or carbon monoxide-rich air streams as process fuel, advantageously recovers more useful hydrogen substances in syngas without introducing a pennally to decompose residual carbon monoxide-rich air streams. can do.

Therefore, residual carbon monoxide-rich air streams can be used directly as process fuel without further refinement. A method of achieving the unexpected advantages of thermal efficiency of the present invention in an integrated coal-liquefied vaporizer is described in detail below in connection with the drawing illustration of FIG.

1 shows that the thermal efficiency of the combined coal liquefaction-gasification process, which produces only liquid gaseous fuel, is higher than the thermal efficiency of the liquefaction process itself. This excellence is maximal when the liquefaction zone usually produces solid dissolved coal in medium yield, all of which are consumed in the vaporization zone.

Medium yields of solid dissolved coal can be obtained very easily by applying slurry recycling as the catalytic effect of the minerals in the slurry being recycled and the continuously reacting recycled dissolved coal.

Therefore, the thermal efficiency of the coalescing process is very low if the liquefaction separation is too low and the amount of solid coal passing through the vaporizer is so high that it produces more hydrogen and syngas than the unit can consume. It will be lower than thermal efficiency, because it is similar to vaporizing coal directly.

In another extreme aspect, if the separation of the liquefaction process is too high and the amount of solid coal passing through the vaporizer is too small to produce even the hydrogen demand of the process (hydrogen production is the first priority of vaporization), Other sources will have to compensate for the lack of hydrogen.

The only practical source of hydrogen for this device would be steam that reforms light gases such as methane or light liquids from the liquefaction zone.

However, this will result in a reduction in total efficiency, and the above method is impossible, and difficult and impractical to achieve, because of the significant conversion of methane to hydrogen and back to methane.

Thermal efficiency due to the merging device of the present invention is calculated from the input and output energy of the device. The output energy corresponds to the high calorific value (kilo calories) of all fuels that are products recovered from the device. The input energy is the sum of the high calorific value of the coal supply and the calorific value of all fuels supplied to the device from an external source and the heat required to make the purchased power.

Assuming 34 percent efficiency in power generation, the heat required to generate power purchased is equal to the power purchased divided by 0.34. The high calorific value of the coal feed and the fuel which is the product of this process are used in the calculation. In view of the high calorific value, the fuel is dried, and the heat capacity of water generated by the reaction of hydrogen and oxygen is estimated to be recovered through the condensation reaction.

Thermal efficiency can be calculated as follows.

All impure coal fed to the apparatus is crushed, dried and mixed with a hot solvent-containing recycled slurry.

The recycled slurry is significantly dilute than the slurry that passes through the vaporizer since it contains a substantial amount of distillate at 193-454 ° C. that first conducts solvent action without vacuum distillation. On the basis of weight, 4 parts 1 part of the slurry to be recycled is preferably applied to 1 part 2.5 parts 1.5 parts impure coal. The recycled slurry hydrogen and raw coal pass through the tubular preheater of the flame and then through the reactor or the melter. The ratio of hydrogen to raw coal is (20,000-80,000, preferably 30,000-60,000SCF per tonne (0.62-2.48 and preferably 0.93-1.86M ³ per kg).

The temperature of the reactants in the preheater is gradually increased so that the preheater discharge temperature ranges from 360-438 ° C, with a preferred temperature of about 071-404 ° C.

Coal is partially dissolved at this temperature and the exothermic hydrogenation and hydrocracking reactions begin. The heat produced by these exothermic reactions in a stirred and maintained at a constant temperature gradually increases the temperature of the reactants to 427-482 ° C., preferably 449-466 ° C.

The residence time in the melter zone is longer than in the preheat zone.

The temperature of the melter is at least 11.1, 27.8, 55.5 or 111.1 ° C above the output temperature of the preheater.

The hydrogen pressure in the preheating and dissolution steps ranges from 1,000-4,000 psi, preferably 1,500-2,500 psi (70-280, preferably 105-175 kg / cm 2).

Hydrogen is added to the slurry at one or more time points. At least a portion of the hydrogen is added to the slurry before the inlet of the preheater. Hydrogen may be added between the preheater and the dissolver or may be added as quench hydrogen within the dissolver itself.

The quench hydrogen is injected at various points in the present dissolver to maintain the reaction temperature to the extent that avoiding significant coke reactions. Since the vaporizer is preferably compressed and suitable for receiving and processing the slurry feed, the vacuum column bottoms constitute the ideal vaporizer feed, and hydrocarbon conversion or other process steps that prevent the slurry before going to the vaporizer. Do not expose to By way of example, the VTB should not be passed through the coke unit which is delayed or flowable before going to the vaporizer to produce coke distillate from the coke unit, as the resulting coke feeds it to the vaporizer. This is because it requires kneading in water to return to acceptable conditions.

Vaporizers suitable for receiving solid feeds require a lock-hopper feed mechanism and are therefore more complex than vaporizers suitable for receiving slurry feeds. The amount of water needed to make the coke slurry accepted and sent is greater than the amount of water that must be supplied to the vaporizer of the present invention. Although the controlled amount of water or water vapor is required for the present vaporizer, which requires its own slurry feed to produce CO and H ₂ by the endothermic reaction, the slurry supplied to the vaporizer of the present invention is essentially free of water. .

This reaction consumes heat while heat is produced by reacting oxygen with the carbonaceous feed to produce CO. It would be advantageous to introduce a large amount of water in the vaporization process, which is a preferred vaporizer product rather than H ₂ -CO and shifts, methane addition or methane conversion continues.

However, in the process of the present invention where a significant amount of syngas is used as process fuel, hydrogen production is reduced compared to CO production because H ₂ and CO have approximately the same heat of combustion.

The vaporizer of the present invention can therefore be operated at elevated temperatures as indicated below, which, although at high temperatures, has a molar ratio of less than 1 of CO to H ₂ , preferably less than 0.8 or 0.9, more preferably Is to promote almost complete oxidation of the carbonaceous feed, even if it leads to syngas product at a molar ratio of less than 0.6 or 0.7.

Vaporizers are generally liquid hydrocarbons rather than solid carbonaceous materials such as coke, because vaporizers cannot oxidize all hydrocarbonaceous fuels supplied to them and some fuels are inevitably lost to coke. There is a tendency to work with higher quality materials. Because coke is a solid, decomposed hydrocarbon, it cannot vaporize at nearly 100 percent efficiency, such as a liquid hydrocarbonaceous feed, and loses more in the dissolved slag formed in the vaporizer than in the case of a liquid vaporizer. This results in the loss of unnecessary carbonaceous material from the device.

Whatever material is supplied to the vaporizer, its enhanced oxidation is affected by increasing vaporizer, temperature. Therefore, in order to increase the high process heat efficiency of the present invention, a high temperature of the vaporization apparatus is required.

The maximum temperature range of the vaporizer of the present invention is generally 1,204-1,982 占 폚, preferably 1,260-1,760 占 폚, most preferably 1,316 or 1,371-l, 760 占 폚.

At these temperatures, mineral residues are converted to dissolved slack that is removed from the bottom of the vaporizer.

By applying a coke plant between the melt and vapor stages, the efficiency of the coalescing process is reduced. Coke plants usually convert solid dissolved coal into distillate fuel and hydrocarbon gas in substantial yield of coke. Melting zones also usually convert solid dissolved coal to distillate and hydrocarbon gas, but at lower temperatures have minimal coke yield. The coke stage is not required between the liquefaction and vaporization stages because the melter stage alone can produce the yield of normally solid dissolved coal that is required to achieve adequate thermal efficiency in the coalescing process of the present invention.

Performing the required reaction in a single process step with minimal coke yield is more efficient than using a two step process.

According to the present invention, the coke total yield occurs in the form of only a small amount of precipitate in the dissolver, which is sufficiently less than one percent increase and usually less than one tenth of one percent increase based on the amount of coal.

The liquefaction process produces a significant amount of liquid fuel and hydrocarbon gas for sale. Total process thermal efficiency is enhanced by applying process conditions that are suitable for producing a significant amount of hydrocarbon gas and liquid fuel, as compared to process conditions that are exclusively suitable for enhancing the production of hydrocarbon gases or liquids. For example, the liquefaction zone should produce at least 8 or 10 weight percent of C ₁ -C ₄ gaseous fuel and at least 15-20 weight percent of distillate liquid fuel based on the amount of coal supply. A mixture of methane and ethane is recovered and sold as LPG. These two products are premium fuels.

The oil fuel recovered in this process and boiled to 193-454 ° C. is a premium boiler fuel.

It is essentially matte and contains less than about 0.4 or 0.5 weight percent sulfur. With naphtha stream at 193 ° C, C ₅ can be pretreated and regenerated to improve premium gasoline fuel. Hydrogen sulfide is recovered from the elution process in the acid gas removal apparatus and converted to elemental sulfur.

Figure 1 illustrates the advantages of the present invention by showing the thermal efficiency curves of the combined coal liquefaction-gasification process carried out with centrifugal bituminous coal using a melter temperature of 427-460 ° C. and a melter hydrogen pressure of 1700 psi (119 kg / cm 2). Can be explained.

The dissolver temperature is higher than the preheater maximum temperature. The liquefaction zone provides impure coal at a fixed rate and mineral residues are fixed in the slurry with distillate liquid solvent and ordinary solid dissolved coal at a rate to maintain a fixed 48% by weight total solids content of the slurry supplied. Recycled, the total solids content is close to the limited solids level for the feed, which is about 50-55 weight percent.

Figure 1 correlates the thermal efficiency of the coalescing process with the yield of dissolved coal at 454 ° C +, where the dissolved coal is solid at room temperature, contains mineral residues, contains undissolved organic matter and is obtained from a liquefied bed. It contains. This material is the only carbon material supplied to the vaporizer and passes directly to the vaporizer without the intermediate treatment step.

The amount of solid dissolved coal in the vacuum column bottoms can be varied by varying the temperature, hydrogen pressure, or residence time in the melt zone, or can vary with the rate of coal feed to the mineral residue being recycled. When the amount of dissolved coal at 454 ° C. + in the vacuum column bottoms material is changed, the composition of the recycled slurry is automatically changed.

Curve A is the thermal efficiency curve of the merged liquefaction-vaporization process, curve B is the thermal efficiency of a typical vaporization process only, point C represents the general range of the maximum thermal efficiency of the merge process, and represents about 72.4 percent in the illustrated embodiment.

The vaporizer of curve B is used for the oxidation zone to generate syngas, the connected shift reactor for converting a portion of the syngas into a hydrogen-rich air stream, an acid gas remover, and other parts of the syngas for purification. It contains a separate acid gas removal unit and a connected shift reactor and a methanator for converting the remaining synthesis gas into pipelin gas.

The thermal efficiency of vaporizers containing shift reactors and methanators in conjunction with oxidation zones is generally in the range of 50-60 percent, which is lower than the thermal efficiency of a liquefaction process with moderately solid dissolved coal. The oxidizer in the vaporization apparatus produces the first stage synthesis gas.

As described above, because syngas contains carbon monoxide, syngas is not a marketable fuel and requires a hydrogenation conversion or a methanol conversion, such as a methane addition step to improve to a marketable fuel. Since carbon monoxide has a low calorific value as well as toxicity, the transport cost of syngas based on the calorific value cannot be tolerated.

This process contributes to the increased thermal efficiency of the merging process, as it can use both or at least 60 percent of the combined capacity of H ₂ and CO of syngas produced as fuel in the apparatus without hydrogenation conversion.

In order to use the syngas as fuel in the apparatus according to the invention, a conduit device must be provided to transport the CO capacity of the syngas or non-fractionated syngas to the liquefied bed, which results in the removal of the acid gas, which is synthesized A combustion apparatus suitable for burning syngas or carbon monoxide, abundant portions of syngas as fuel, without going through a gas hydrogenation apparatus must be installed.

If the amount of syngas is not sufficient to provide the total fuel requirements of the process, the conduit can burn fuel produced in the dissolution zone, ie naphtha, or gaseous fuels such as methane, ethane, in-process combustion suitable for burning these fuels. It should also be provided for transportation to the device.

As Figure 1 suggests, the thermal efficiency of the coalescing process is low at about 45 percent of the molten coal yield of 454 ° C +, which is related to the vaporization zone itself in proceeding the coalescing process in this or the yield of ordinary solid molten coal. There is no advantage of efficiency.

As indicated in Figure 1, there is no mineral residue that is recycled to promote the liquefaction in the liquefaction process, so the yield is raised to 60 percent based on molten coal at 454 ° C. +.

As shown in Figure 1, the recycle of mineral residues reduces the yield of dissolved coal at 454 ° C + to the 20-25 percent range, which corresponds to the maximum thermal efficiency range of this consolidation process. Recirculation of mineral residues maintains the solids in the supplied slurry at a constant level while dissolving coal at 454 ° C. + to optimize thermal efficiency by varying the temperature, hydrogen pressure, residence time and / or ratio of coal to recycle slurry. Yield can be finely adjusted.

Point D ₁ on curve A represents the chemical hydrogen balance point of the merging process.

At 15 percent yield (point D ₁ ) of dissolved coal at 454 ° C., the vaporizer produces the exact chemical hydrogen demand of the liquefaction process. Point D ₁ is the thermal efficiency in the dissolved coal yield of 454 ℃ + is the same as the efficiency at the point D ₂ of 454 ℃ + More of the dissolved coal yield. When performing this process in the region of lower yield point D ₁ , the size of the dissolution zone will be relatively large to achieve the required degree of bath hydrolysis, and the vaporization zone is relatively small due to the relatively small amount of carbonaceous material supplied to it. Will be less.

When performing this process in the point D ₂ region, the size of the melting stage will be relatively small due to the reduction in the degree of hydrocracking required at point D ₂ , but the vaporization stage will be relatively large.

In the regions of points D ₁ and D ₂ , the melting and vaporizing zones will be relatively balanced so that the thermal efficiency will be near maximum.

Point E ₁ on curve A represents the process hydrogen number point, which contains hydrogen losses in the process. Point E ₁ represents the amount of dissolved coal at 454 ° C. + which is produced to produce sufficient gaseous hydrogen to meet the sum of the chemical hydrogen demand of this process plus the loss of gaseous hydrogen in the product liquid and gas streams. Pass through the vaporizer. A relatively large amount of dissolved coal at 454 ° C. + produced at point E ₂ will achieve the same thermal efficiency as achieved at point E ₁ .

At point E ₁ conditions, the dissolver size is relatively large and will achieve the greater degree of hydrocracking required at this point and therefore the vaporizer size will be relatively small. Conversely, at point E ₂ conditions, the dissolver size will be relatively small due to the lower degree of hydrocracking, while the vaporizer size will be relatively large. The dissolver and vaporizer stages will be relatively balanced in size in the middle of the points E ₁ and E ₂ phases (for example about 17.5 of the coal yield of 454 ° C. + and in the middle of the weight percent phase), and thermal efficiency is the best in this zone.

The dissolved coal yield of 454 ° C. + at point X on line E ₁ E ₂ would be very suitable to supply all process hydrogen demands and all process fuel demands.

At the dissolved coal yield of 454 ° C. between points E ₁ and X, the synthesis gas which is not required for process hydrogen is used as fuel in the process, thus the thermal efficiency is high without the need for hydrogenation conversion of the synthesis gas. However, at 454 ° C. + dissolved coal yield in the region between points X and E ₂ , the excess of 454 ° C. dissolved coal produced at point X cannot be consumed within the process and therefore for sale as pipelin gas. Further conversion will be required, such as the addition of methane.

As shown in Figure 1, the thermal efficiency of the coalescing process, which increases the amount of syngas useful as fuel, increases and reaches the highest point of the region of point Y, where the syngas provides the pre-process fuel demand. This efficiency decreases at point Y because more syngas is produced in the process than can be used as equipment fuel, requiring a methane addition unit to convert excess syngas to pipelin gas at point Y. To start.

As shown in Figure 1, the amount of dissolved coal produced at 454 ° C + is appropriate, and the thermal efficiency of the present invention can be achieved when generating process fuel demands in any amount, such as from about 5, 10 or 20 to 90 or 100 percent. Can be increased. However, as shown in Fig. 1, the advantage of the thermal efficiency increase of the present invention is that when the generated syngas is used to supply process fuel demand without methane addition, a limited excess of syngas is produced to add methane to make it marketable. Although needed, it is still widely used despite its reduced degree.

The efficiency advantage of the present invention is lost, as indicated by point Z, when the resulting syngas that requires methane addition is excessive.

An efficiency increase of 1 percent in a commercial sized device of the present invention can affect the savings of about $ 10 million annually. This liquefaction process should be carried out separately, so that the weight percent of moderately solid dissolved coal at 454 ° C + on a dry coal basis is broadly 15-45 percent, narrower 15-30 percent, and even narrower. Any value between 17 and 27 percent, which provides the benefit of the thermal efficiency of the present invention.

As described above, the percentage based on the calorific value of the total energy requirements of this process, derived from the syngas generated from these vaporizer feed quantities, is at least 5, 10, 20 or 30 percent, or even 100 percent based on the calorific value. The remaining process energy is derived from energy supplied directly from the liquefaction zone and from sources supplied from outside sources of the process, such as electrical energy.

The device fuel, not syngas, is advantageously obtained in the liquefaction process rather than impure coal, since the pretreatment of coal in the liquefaction process allows the fractions useful here to be extracted with the increased efficiency of the present coalescing process.

As mentioned above, high thermal efficiencies are associated with moderate yields of normally solid dissolved coal and hence with appropriate liquefaction conditions. Under appropriate conditions, significant yields of hydrocarbon gas and liquid fuel are produced in the liquefaction zone and very high and very low yields of moderately solid dissolved coal are reduced.

As indicated, the appropriate conditions result in a relatively balanced mixture of hydrocarbon gas, liquid, and solid coal liquefaction zone products, which is reasonably balanced in size between the dissolution and vaporization stages, resulting in a medium size between the two. It needs a device to have.

When the dissolved and vapor stages are reasonably balanced, the vaporizer will produce more syngas than required for process hydrogen demand. Therefore, a balanced process requires the following devices, which are provided to pass the syngas through the liquefaction zone at one or more of the device sections or elsewhere after the removal of the acid gases in the process, and these A device is provided to the burner device for combustion of the syngas or carbon monoxide-rich portion produced as plant fuel.

In general, a burner of a type different from that required for combustion of hydrocarbon gas will be required for combustion of the synthesis gas. Only in such a device can this optimum thermal efficiency be obtained.

Therefore, the features of such a device are important if the device can find the proper thermal efficiency of the invention.

By obtaining a reaction equilibrium that can be easily achieved with a dissolver without adding a limited reaction or half of excess, it is very easy to obtain the appropriate and relatively balanced operation described above. For example, hydrocracking reactions should not proceed excessively, with little or no solid dissolved coal being produced.

The hydrocracking reaction, on the other hand, should not be overly limited, because it produces very high yields of normally solid dissolved coal with excessively reduced efficiency.

Because hydrocracking reactions are exothermic, the temperature in the melter must be raised above the preheater temperature.

As mentioned above, the suppression of such temperature increases requires the introduction of quench hydrogen significantly more than the amount required for such an increase in temperature. This reduces the thermal efficiency by requiring the production of more hydrogen than is required in the case different from the above, and also requires the energy consumption added to compress the excess hydrogen.

The temperature difference that develops between the preheater and the melter can be avoided, but the use of excess fuel in the preheater is required. Therefore, a convenient way of maintaining normal preheater and dissolver temperatures works against the natural tendency of the liquefaction reaction and reduces the thermal efficiency of the process.

The mineral residues produced in this process are hydrogenated, hydrocracked catalyst and recycled in this process to increase their concentration, resulting in an increase in the naturally occurring reaction rate and thus the required residence time in the dissolver. And / or reduce the required size of the dissolution zone.

The present mineral residues are suspended in the form of very small particles 1-20 microns above the product and will increase their catalysis with small particle sizes. Recirculation of the catalyst material greatly reduces the amount of solvent required. Therefore, there is a tendency to increase the thermal efficiency of the process by recycling the process mineral residues in an appropriate amount to provide adequate equilibrium catalysis in the slurry with distillate liquid solvent.

Catalysts and other effects due to the recycling of process residue mineral residues will not only increase sulfur and oxygen removal, but will also reduce the yield of normally solid dissolved coal in the liquefaction zone to about or above through hydrocracking. . As shown in FIG. 1, a 20-25 percent 454 ° C. + coal yield essentially provides maximum thermal efficiency in the combined liquefaction-vaporization process. As a result of the excess coke, it is not possible to satisfactorily achieve the hydrocracking of this level by increasing the melter temperature without limiting it through exothermic reactions occurring in the melter.

The use of external catalysts in this liquefaction process results in mineral residues, as compared with the use of indigenous or in vitro catalysts, the introduction of external catalysts increases the process content and makes the process more complex, thus reducing process efficiency. It does not have the same value as recycling.

As already mentioned above, the thermal efficiency curve of FIG. 1 relates to the appropriate thermal efficiency and especially the yield of dissolved coal, which is usually solid, and that all usually solid molten coal obtained must be passed through the vaporizer without liquid coal or hydrocarbon gas. Requires.

Therefore, in the apparatus for implementing the above-described efficient curve, it is important to apply a vacuum distillation column, preferably associated with an atmospheric column, in order to completely separate the solid dissolved coal from the liquid coal and the hydrocarbon gas.

Atmospheric towers alone do not completely remove the distillate liquid from the solid dissolved coal. In practice, the atmospheric tower can be omitted in the process if necessary. If the liquid coal passes through the vaporizer, the efficiency will be reduced as a result, since liquid coal is a premium fuel, unlike solid dissolved coal.

Liquid coal usually consumes more hydrogen than solid dissolved coal consumes.

The increased hydrogen contained in the liquid coal is consumed in the oxidizing zone, which reduces the process efficiency. A flowchart for carrying out the merging process of the present invention is described in FIG.

The dried and pulverized raw coal is the total raw coal supplied in this process and passes through line 10 to slurry mixing tank 12 where the coal is mixed with the slurry recycled from the process flowing to line 14 containing hot solvent. .

In line 16 the solvent-containing recycle slurry mixture (mixed in the range of 1.5-2.5 parts per slurry weight per 1 part of coal) is pumped by a reciprocating pump 18 and mixed with recycle hydrogen entering through line 20, It is mixed with the already produced hydrogen entering through line 92 prior to being passed to dissolver 26 through tubular preheater 22. The feed-to-hydrogen ratio is about 40,000 SCF / ton (1.24 M ³ / kg).

The reactant temperature at the preheater outlet is about 371-404 ° C. At this temperature, the coal is partially dissolved in the recycle solvent and the exothermic hydrogenation and hydrocracking reactions begin soon. As the temperature gradually increases along the length of the preheater, the dissolver is generally thoroughly homogeneous and the heat generated by hydrocracking in the dissolver increases the temperature of the reactants in the range of 449-466 ° C. The quench hydrogen passing through line 28 is injected into the dissolver at several points to control the reaction temperature and to mitigate the impact of the exothermic reaction.

The eluate of the dissolver goes to the vapor-liquid separator 32 via line 29. The upper hot steam stream from these separators is cooled in a series of heat exchangers and by addition of a medium-liquid separation step and removed via line 32.

Liquid distillate from these separators goes to line fractionator 36 via line 34. Ratio in the lines 32-a yongchuk gas is passed to a non-reaction of hydrogen, methane and other light hydrocarbons, plus contains an H ₂ S and CO _2, acid gas removal for the removal of H ₂ S and CO ₂ device . The recovered hydrogen sulfide is converted to elemental sulfur removed in the present process through line (0).

A portion of the purified gas is chiller 44 for removing propane and butane with LPG passing through line 48 to remove large amounts of methane and ethanol through pipeline 46. It is passed to 42 for further processing within.

Purified hydrogen (90 percent purity) in line 50 is mixed with the gas remaining from the acid gas treatment step of line 52 and contains recycled hydrogen of the process.

Liquid slurry from distillation liquid separator 30 passes through line 56 and is separated into two main streams, 58 and 60. Air stream 58 includes a recycle slurry, which contains a solvent, usually dissolved coal, and catalytic mineral residues.

The slurry that is not recycled goes to line fraction 36 through line 60 for separation of the main product of the process. In fractionator 36, the slurry is distilled at atmospheric pressure to remove the upper naphtha stream through line 62, the middle distillate stream through line 64, and the bottom stream through line 66. The lower airflow of line 66 passes through vacuum distillation tower 68.

The temperature of the feed to the fractionator is generally maintained at a sufficiently high level that does not require preheater addition rather than for start-up operation. Mixing the fuel oil from the atmospheric tower of line 64 with the intermediate distillate recovered from the vacuum tower via line 70 makes the main fuel oil product of the process and is recovered via line 72.

The stream of line 72 contains a fuel oil product of 193-454 ° C. which is a distillate, a portion of which is passed through the sine 73 to adjust the solid concentration and coal-solvent ratio of the slurry supplied. Can be recycled to feed 12). The recycle stream 73 gives fluidity to the process by varying the solvent ratio for the slurry to be recycled, and therefore does not fix this ratio of the process to the general proportion within line 58.

This can also improve the feeding of the slurry.

The vacuum column bottoms material contains all normally solid dissolved coal, undissolved organics and minerals, and goes through the line 74 to the partial oxidizing vapor stage 76 without distillate or hydrocarbon gas. Since the vaporizer 76 is suitable for receiving and running a hydrocarbonaceous slurry feed stream, there is no need for a hydrocarbon conversion step, such as a coke unit, between the vacuum tower 68 and the vaporizer 76, which destroys the slurry. It will require recycling of the slurry in water. The amount of water required to coke the slurry is generally greater than the amount of water required by the vaporizer, so the efficiency of the vaporizer will be reduced to the amount of heat consumed to evaporate excess water.

It is made in nitrogenfree oxygen oxygen device 78 of vaporizer 76 and goes through vaporizer 80 to vaporizer. Water vapor is supplied to the vaporization apparatus via line 82. The total mineral content of the coal supplied through line 10 is removed from the process through line 84 as inert slag, which is released from the bottom of vaporizer 76.

Syngas is produced in the vaporizer 76, a portion of which goes to the shift reactor stage 88 via line 86 to be converted by a shift reaction in which water vapor and CO are converted to H ₂ and CO ₂ . _It is followed by an acid gas removal zone (89) for ₂ S and CO ₂ removal. The resulting purified hydrogen (90-100% percent purity) is compressed to treat pressure with a compressor 90, and the lines 92 are provided to provide pre-generated hydrogen 22 and dissolved hydrogen 26 to the dissolver 26. Supplied through.

As explained above, the heat generated in the vaporization stage 76 is not considered energy consumption in the present process but only the reaction heat required to produce the syngas reaction product.

The amount of syngas produced in the vaporizer 76 is not only sufficient to supply all the hydrogen molecules required by the process, but also sufficient to supply the total heat and energy requirements of the process between 5-100 percent without a methane addition step. It is an important feature of the present invention. For this reason, the part of the synthesis gas which does not flow to the moving reactor passes through the line 94 to the acid gas removal device from which the CO ₂ + H ₂ S is removed. The removal of H ₂ S allows the synthesis gas to meet the external standards required for fuel, while the CO ₂ removal increases the syngas heat capacity and achieves finer thermal control when used as fuel.

The stopped syngas stream is directed to boiler 100 via line 98. The boiler 100 is provided with an apparatus for burning syngas as fuel.

Water goes to the boiler 100 via line 102 where water is converted into water vapor and water vapor flows through line 104 to supply process energy, which is like passing through a reciprocating pump 18. The separated stream of syngas from the degassing apparatus 96 passes through line 106 to the preheater 22 where it is used as fuel. The syngas can be used similarly to the above at all other points in the process requiring fuel.

If the syngas does not provide all the fuel required for the process, the fuel and the rest of the energy required in the process can be supplied from a non-premium fuel stream generated directly in the liquefaction zone. If this is more economical, some or all of the process energy not derived from the synthesis gas may originate from sources and silver sources not yet exemplified.

The syngas added is directed to shift reactor 114 via line 112 and increases the hydrogen to carbon monoxide ratio from 0.6 to 3.

This enriched hydrogen mixture goes through the line 116 to the methane adder 118 to convert to the pipelin gas, passes through the line 120 and mixes with the pipeline gas in the line 46.

The amount of pipelin gas based on the calorific value passing through line 120 will be less than the amount of syngas passing through lines 98 and 106 and used as process fuel, thus ensuring the thermal efficiency advantages of the present invention. .

A portion of the purified syngas stream is directed to the cooling separator 124 via line 122 where hydrogen and carbon monoxide are separated respectively. An adsorption device may be used instead of the cooling device.

The hydrogen-rich air stream is recovered via line 126 and mixed with the hydrogen air stream already produced in line 92, each passing through a liquefied bed or sold as a product of the process. The carbon monoxide-rich air stream may be recovered via line 128 and mixed with syngas adapted to process fuel within line 98 or line 106, or may be sold or used as process fuel or chemical feedstock, respectively. have.

As Figure 2 shows, the vaporizer section of this process is highly integrated into the liquefier section. The total feed to the vaporizer section (VTB) comes from the liquefaction section and almost or all of the gaseous products of the vaporizer section are consumed as reactants or fuel in the process.

Example 1

The raw Kentucky bituminous coal is ground and mixed with hot solvent-containing slurry which is recycled from this process. A mixture of coal-recycle slurry (in the range of 1.5-2.5 parts per slurry weight for 1 part of coal) is condensed with hydrogen and passed to the melting stage through the flame preheating zone. The coal-hydrogen ratio is about 40,000 SCF / ton (1.24 M ³ / kg).

The temperature of the reactants at the preheater outlet is about 371-399 ° C. At this point, the coal is partially dissolved in the recycle slurry and the pyrogenic and hydrocracking reactions begin soon. The heat generated by these reactions in the dissolver further increases the temperature of the reactants in the range of 820-870 ° C. The quench hydrogen is injected at several points in the melter and reduces the impact of this exothermic reaction. Eluate from the dissolver stage is passed through a product separator, which contains an atmospheric tower and a vacuum tower. The residue at 454 ° C. from the vacuum tower is passed to an oxygen-blowing vaporizer containing all undissolved mineral residues and all normally solid dissolved coal without coal liquid and hydrocarbon gas.

The synthesis gas produced in the vaporizer has a ratio of CO to H ₂ of about 0.6 and is passed to the shift reactor where steam and carbon monoxide are converted to hydrogen and carbon dioxide and to the acid gas removal step to remove carbon dioxide and hydrogen sulfide. Grieg's hydrogen (94 percent purity) is compressed and is produced hydrogen that is supplied to the preheater-melt stage.

In this embodiment, the amount of hydrocarbonaceous material supplied to the vaporization zone is sufficient so that the resultant synthesis gas can meet the process hydrogen demand, which includes process losses and when the process burns directly in the process, the layer energy requirements of the process Contains 5 percent of

The remaining energy requirements of the process can be met by burning light hydrocarbon gas or naphtha produced in the liquefaction zone and by the power purchased.

The following is a list of products of the liquefaction zone. Viewed here, the liquefaction zone produces a liquid or gaseous product and also a re-containing residue at 454 ° C.

The main product of this process is 0.3% by weight sulfur-containing, ash-free fuel oil useful for power plants and industrial equipment.

The yield below shows the residual product for sale after obtaining future fuel demand as described above.

The following data shows the input energy, output energy and thermal efficiency of this merge process.

Based on power plant thermal efficiency of 34 percent

(1) 1,317 BTU / SCF (11,590 cal.kg/M ³ ) This example shows that the combined liquefaction-gasification process is operated so that the amount of carbohydrate material that passes from the liquefaction zone to the vaporization unit causes the vaporizer to have sufficient The thermal efficiency of the combined process is 71.9 percent when it meets the process hydrogen demand and the total process energy requirement of only about 5 percent, which is adequate to supply.

Example 2

The merged liquefaction-vaporization process is carried out in a similar process as in Example 1, using the same Kentucky bituminous coal, except as follows. That is, the amount of hydrocarbon material passing from the liquefaction zone to the vaporization zone is adequate so that the vaporization zone is adequate to supply the total process hydrogen demand containing process losses and about 70 percent of the total energy requirements of the process when burned directly in the process. It is possible to produce an amount of syngas.

The following is a list of liquefaction zone products.

Yield: weight percent of dry coal

The yield below shows the residual product for sale after obtaining the fuel requirement of the device as described above.

Product yield of the device

Coal Supply Rate (Based on Dry): T / D (kg / D)

30,000 (27.2 × 10 ⁶ )

Pipeline gas: MMSCF / D (MMM ³ / D) 77 (2.16)

LPG: B / D (M ³ / D) 16,883 (2,026)

Naphtha: B / D (M ³ / D) 20,440 (2,453)

Distillate Fuel Oil: B / D (M ³ / D) 49,343 (5,921)

The data below shows the input energy, output energy and thermal efficiency of this process.

Device thermal efficiency

Thermal efficiency: percent

1,317 BTU / SCF (11,590 cal kg / M ³ )

The thermal efficiency in addition to the 72.4 percent of this example is greater than the 71.9 percent thermal efficiency of Example 1 and these two examples use the same Kentucky bituminous coal, with a difference of 0.5 percent. This indicates that higher vapor efficiency can be achieved when the vaporizer supplies the total process hydrogen demand and the energy demand of the process 70 percent rather than 5 percent.

It is noteworthy that in commercial devices with the feed supply of these examples, a savings of about $ 5 million annually can be achieved with a 0.5 percent difference in thermal efficiency.

Example 3

The merged liquefaction-vaporization process is carried out in a similar process as in Example 2, using the same canister bituminous coal, except as follows.

That is, all syngas produced in the excess amount required to meet the process hydrogen demand is methane added for sale.

All process fuels are met by the C ₁ -C ₄ gas produced in the liquefaction step.

The following is a list of products of the liquefaction zone:

Yield: weight percent of dry coal

The yield below shows the residual product for sale after obtaining the fuel requirement of the device as described above.

Product yield of the device

Coal Supply Rate (Based on Dry): T / D (kg / D)

30,000 (27.2 × 10 °)

product

Pipeline gas: MMSCF / D (MMM ³ / D) 78 (2.21)

LPG: B / D (M / D) 16,883 (2,026)

Naphtha: B / D (M / D) 20,440 (2,453)

Distillate Fuel Oil: B / D (M ³ / D) 49,343 (5,921)

The following data shows the input energy, output energy and thermal efficiency of this process.

Device thermal efficiency

Thermal Efficiency: Percent 70.0

1,046 BTU / SCF (9,205 cal.kg/M ³ )

Examples 1 and 2 show thermal efficiency of 71.9 and 72.4 percent when excess syngas is produced in excess of the amount required to meet the process hydrogen requirements when the excess syngas is used directly as the device fuel, The thermal efficiency of 70.0 percent of this embodiment represents a thermal efficiency drawback when excess syngas is produced, where the excess syngas is improved to commercial fuel via hydrogenation instead of burning directly in the apparatus.

Example 4

The merged liquefaction-vaporization process is carried out in a similar process to Example 1 except that the coal is a Westa Virginia Pittsburgh seam bituminous coal. The adequate amount of hydrocarbonaceous material from the liquefaction zone passes through the vaporization zone so that the vaporization zone supplies about 5 percent of the total process hydrogen demand, including process losses, and about 5 percent of the process's total energy demand when burned directly in the process. It is possible to produce an amount of suitable synthesis gas.

The following is an analysis of the coal supply.

West Virginia Pittsburgh Sea Crushed Coal Weight Percent Based on Dry

The following is a list of liquefaction zone products.

Yield: weight percent of dry coal

The yield below shows the residual product for sale after obtaining the fuel demand as described above.

Product yield of the device

Coal Supply Rate (Based on Dry): T / D (kg / D) 30,000 (27.2 × 10 ⁶ )

product

Pipeline gas: MMSCF / D (MM M ³ / D) 26.2 (0.74)

LPG: B / D (M ³ / D) 23,078 (2,769)

Naphtha: B / D (M ³ / D) 21,885 (2,626)

Distillate Fuel Oil: B / D (M ³ / D) 45/060 (5,407)

The data below shows the input energy, output energy and thermal efficiency of this merge process.

Thermal efficiency of the device

Example 5

Another merged liquefaction-vaporization process is carried out in a similar process as in Example 4, using the same Wester Virginia Pittsburgh seam coal, except as follows. That is, the amount of hydrocarbonaceous material that passes through the vaporization zone from the liquefaction zone is adequate so that the vaporization zone produces an adequate amount of syngas to provide about 37 percent of the total process hydrogen demand and about 37 percent of the energy demand of the process when burned directly in the process. can do.

The following is a list of liquefaction zone products:

Yield: weight percent of dry coal

The yield below shows the residual product for sale after obtaining the fuel demand as described above.

Product yield of the device

Coal Supply Rate (Based on Dry): T / D (kg / D)

30,000 (27.2 × 10 ⁶ )

Pipeline gas: MMSCF / D (MMM ³ / D) 64.81 (1.83)

LPG: B / D (M ³ / D) 18,338 (2,200)

Naphtha: B / D (M ³ / D) 20,233 (2,428)

Distillate Fuel Oil: B / D (M ³ / D) 43,004 (5,160)

The data below shows the input energy, output energy and thermal efficiency of this merge process.

Thermal efficiency of the device

The thermal efficiency of this example is higher than that of Example 4 and these two examples use the same Pittsburgh seam coal, with a thermal efficiency difference of 1.3 percent.

The higher thermal efficiency of this example provides the advantage of supplying sufficient 850 ° C. + (454 ° C.) of dissolved coal to the vaporizer, thus providing a total process hydrogen demand and direct combustion of syngas to 5 percent. Rather, it can supply 37 percent of the energy requirements of the process.

Claims (1)

Mineral-containing feed coal, hydrogen, recycle liquid solvent, recycle Liquid coal and recycled residual minerals are introduced into the coal liquefaction zone, After separating the distillate and slurry from the slurry consisting of liquid coal, solvent and residual minerals, Part of the slurry is recycled to the liquefaction zone, The remainder is introduced into a distillation apparatus having a vacuum distillation column, As a result, a vaporizer feed slurry, which is formed in the vacuum distillation column and contains liquid coal, which becomes almost all hydrocarbon feeds, and the remaining minerals in the liquefaction zone without liquid coal and hydrocarbon gas, is introduced into the vaporization zone, 1,204 to convert enough hydrocarbon material in the vaporization zone to syngas with a molar ratio of H ₂ to CO sufficient to produce an additional amount of syngas over that required to produce treated hydrogen that, when burned as fuel, enhances thermal efficiency. Introducing water or water vapor into the vaporization zone having an oxidation zone of -1982 ° C, Converting some of the syngas into a first fluid having a high hydrogen content and sending the liquefaction zone for use as treated hydrogen; By separating CO and H ₂ from at least some of the syngas addition to provide a carbon monoxide-rich fluid and a second hydrogen-rich fluid that supplies at least a portion of the fuel being combusted, Integrated coal liquefaction and vaporization method characterized by the combustion of CO and H ₂ corresponding to 60 mol% of the additional amount of the syngas to supply 5-100% of the total heat energy required in the process.

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