JP6234901B2 - Ashless coal manufacturing method and ashless coal manufacturing apparatus - Google Patents

Description

  The present invention relates to a method for producing ashless coal and an apparatus for producing ashless coal.

  Patent Document 1 describes a conventional method for producing ashless coal. Claim 1 of the patent document has the following description. “Slurry preparation step of preparing a slurry by mixing coal raw material and solvent; extraction step of heating the slurry obtained in the slurry preparation step to extract coal components soluble in the solvent; obtained in the extraction step A separation step of separating the solution portion containing the coal component soluble in the solvent and the non-solution portion containing the coal component insoluble in the solvent; and the solvent from the solution portion separated in the separation step An ashless coal acquisition step for obtaining ashless coal by separation;

JP 2009-227718 A

  In the method for producing ashless coal described in Patent Document 1, the slurry is heated. Although not described in the document, the solvent may be heated in some cases. It is conceivable that natural gas, propane gas, heavy oil or the like is used as a fuel for heating the slurry or solvent. However, since these fuels are expensive, there is a problem that the fuel cost becomes high.

  In addition, it is desired that a device (heating device) for heating the slurry or solvent can be stably operated.

  Therefore, the present invention provides an ashless coal production method and an ashless coal production apparatus that can suppress the fuel cost for heating the slurry or the solvent and that can stably operate the heating device for heating the slurry or the solvent. The purpose is to provide.

  The manufacturing method of the ashless coal of 1st invention is equipped with the isolation | separation process, the ashless coal acquisition process, and the byproduct coal acquisition process. In the separation step, a slurry obtained by mixing coal and a solvent is heated to extract a coal component soluble in the solvent to obtain a solid liquid, a solution in which the coal component soluble in the solvent is dissolved, and It is the process of separating into the solid content concentrate which the said coal component insoluble in a solvent concentrated. The ashless coal acquisition step is a step of obtaining ashless coal by evaporating and separating the solvent from the solution separated in the separation step. The byproduct charcoal acquisition step is a step of obtaining byproduct charcoal by evaporating and separating the solvent from the solid content concentrate separated in the separation step. Further, the method for producing ashless coal includes a gasification step of obtaining a process gas by gasifying the by-product coal obtained in the by-product coal acquisition step, and the process gas obtained in the gasification step. And a heating step of heating the slurry or the solvent.

  The apparatus for producing ashless coal of the second invention comprises an extraction tank, a separation device, a first solvent separation device, and a second solvent separation device. The said extraction tank heats the slurry obtained by mixing coal and a solvent, and extracts the coal component soluble in the said solvent. The separation device separates the slurry obtained in the extraction tank into a solution in which the coal component soluble in the solvent is dissolved and a solid content concentrate in which the coal component insoluble in the solvent is concentrated. . The first solvent separation device is a device for obtaining ashless coal by evaporating and separating the solvent from the solution separated by the separation device. The second solvent separation device is a device for obtaining by-product coal by evaporating and separating the solvent from the solid content concentrate separated by the separation device. Further, the ashless coal manufacturing apparatus includes a gasification furnace that obtains a process gas by gasifying the by-product coal obtained by the second solvent separation device, and the process gas obtained by the gasification furnace. And a heating device for heating the slurry or the solvent.

  In each of the first invention and the second invention, the fuel cost for heating the slurry or the solvent can be suppressed, and the heating device for heating the slurry or the solvent can be stably operated.

It is a schematic diagram of the ashless coal manufacturing apparatus 1 of 1st Embodiment. It is a schematic diagram of the byproduct coal conversion apparatus 50 shown in FIG. It is the FIG. 1 equivalent view which shows the ashless-coal manufacturing apparatus 101 of 2nd Embodiment. FIG. 2 is a view corresponding to FIG. FIG. 3 is a view corresponding to FIG.

(First embodiment)
With reference to FIGS. 1-2, the ashless coal manufacturing method (ashless coal manufacturing method) of 1st Embodiment and the ashless coal manufacturing apparatus 1 (ashless coal manufacturing apparatus) shown in FIG. 1 are demonstrated. To do.

  The ashless coal production apparatus 1 is used in an ashless coal production method. The ashless coal production method is a method of producing ashless coal (HPC: Hyper-coal) by removing ash from raw coal. The ashless coal production apparatus 1 is an HPC production plant. Hereinafter, the raw material coal is also simply referred to as “coal” (excluding the description regarding the gasification furnace 51 described later). The ashless coal manufacturing apparatus 1 includes a coal / slurry processing device 10, a circulation path 41, a heat exchanger 42 (heating device), and a byproduct coal conversion device 50.

  The coal / slurry processing device 10 is a device that performs a coal / slurry processing step. The coal / slurry processing step is a step of processing coal and slurry (described later). The coal / slurry processing apparatus 10 includes a solvent tank 11 and a coal hopper 12. The coal / slurry processing apparatus 10 includes a slurry preparation tank 21 (heating device), a transfer pump 22, a preheater 23 (heating device), and an extraction tank 24 in order from the upstream side (upstream side in the ashless coal production method). (Heating device), a separation device 25, and a solvent separation device 30.

  A solvent is stored in the solvent tank 11 (solvent storage step).

  The coal hopper 12 stores and supplies coal (coal storage and supply process).

  The slurry preparation tank 21 (heating device) is a tank that performs a slurry preparation step. A slurry preparation process is a process of preparing a slurry by mixing coal and a solvent. For example, the slurry preparation tank 21 may be supplied with a solvent from the circulation path 41, and may be supplied with a solvent other than the circulation path 41, for example. The solvent stored in the solvent tank 11 is supplied to the slurry preparation tank 21. This solvent dissolves coal. This solvent is, for example, a coal derivative. This solvent is mainly purified from the dry distillation product of coal. This solvent is, for example, a solvent containing an aromatic compound (aromatic solvent). Coal is supplied to the slurry preparation tank 21 from the coal hopper 12. This coal is, for example, bituminous coal or low-grade coal (brown coal, subbituminous coal). Bituminous coal has a higher extraction rate (ratio of soluble components of coal extracted into solvent) than low-grade coal. Low-grade coal is less expensive than bituminous coal. The mixing ratio of coal to the solvent in the slurry preparation tank 21 is, for example, 0.5 to 4.0, preferably 0.75 to 2.0, based on dry coal. The slurry preparation tank 21 may heat the slurry. The details of the heating of at least one of the solvent and the slurry (hereinafter also referred to as “heating of the slurry”) will be described later.

  The transfer pump 22 is a device that performs a transfer process. The transfer step is a step of transferring the slurry prepared in the slurry preparation tank 21 to the downstream side of the transfer pump 22. The transfer pump 22 transfers the slurry to the preheater 23. The transfer pump 22 transfers the slurry to the extraction tank 24 via the preheater 23.

  The preheater 23 (heating device) is a device that performs a preheating step (heating step). The preheating step is a step of heating the slurry prepared in the slurry preparation tank 21 and a step of heating the slurry in advance before the slurry is supplied to the extraction tank 24 (before an extraction step described later is performed). It is. The preheater 23 is a gas-fired heating furnace (described later) that heats the inside of the furnace with heat generated by burning gas fuel (described later). The fuel of the preheater 23 includes a process gas G1 described later. The fuel of the preheater 23 is, for example, only the process gas G1. The exhaust gas E is discharged from the preheater 23.

  The extraction tank 24 (heating device) is a tank that performs an extraction process (a part of the following separation process). The extraction step is a step of heating a slurry (a slurry obtained by mixing coal and a solvent) to extract a coal component (solvent soluble component) soluble in the solvent. The slurry is supplied from the slurry preparation tank 21 to the extraction tank 24. The slurry is supplied from the preheater 23 to the extraction tank 24. The extraction tank 24 extracts the organic component in coal. Details of this extraction are as follows. The slurry supplied to the extraction tank 24 is heated and held at a predetermined temperature (described later) while being stirred by a stirrer provided in the extraction tank 24. Thereby, a solvent soluble component is extracted from a slurry. However, the extract includes not only a solvent-soluble component but also a component insoluble in a solvent (a solvent-insoluble component) (for example, ash). The heating temperature of the slurry in the extraction tank 24 is set to a temperature at which the solvent-soluble component can be dissolved in the solvent. Specifically, the heating temperature of the slurry is, for example, 300 ° C. or higher, preferably 360 ° C. or higher. The heating temperature of the slurry is, for example, 420 ° C. or less, preferably 400 ° C. or less.

In the extraction tank 24, an extraction tank generated gas G2 (see FIG. 3) is generated during extraction. The extraction tank product gas G2 includes, for example, CH ₄ , C ₂ H ₄ , C ₂ H ₆ , C ₃ H ₈ , C ₄ H ₁₀ , H ₂ , CO, and the like. The calorific value of the extraction tank product gas G2 is high enough to be used as a heating fuel such as slurry, and specifically, for example, about 8000 kcal / kg.

  The separation device 25 is a device that performs a separation process (excluding an extraction process). The separation step is performed by the extraction tank 24 and the separation device 25. In the separation step, the slurry obtained in the extraction tank 24 is separated by a separator 25 with a solution in which a solvent-soluble component is dissolved (solution part, supernatant liquid, overflow) and a solid content concentrate in which a solvent-insoluble component is concentrated (under It is a process of separating into (flow). Examples of the separation method include a gravity sedimentation method, a filtration method, and a centrifugal separation method. The gravitational sedimentation method is a system in which a slurry is held in a tank of the separation device 25 and a solvent-insoluble component is settled using gravity to separate the solution into a solid concentrate.

  The solvent separation device 30 (solvent recovery facility) is a device that performs a solvent separation step. The solvent separation step is a step of evaporating and separating the solvent from the solution separated by the separation device 25. The solvent separation device 30 is a device for obtaining ashless coal (HPC) and by-product coal (RC; Residue coal) described later from the solution separated by the separation device 25. The solvent separation device 30 includes a first solvent separation device 31 and a second solvent separation device 32.

  The 1st solvent separation apparatus 31 is an apparatus which performs an ashless coal acquisition process. The ashless coal acquisition step is a step of obtaining ashless coal by evaporating and separating the solvent from the solution separated by the separation device 25. Examples of the evaporation separation method include a distillation method and an evaporation method. The details of this ashless coal are as follows. Ashless charcoal is charcoal that has no moisture and contains almost no ash. Ash content contained in ashless coal is 5% by weight or less, preferably 3% by weight or less. Ashless coal has a higher calorific value than raw material coal, and has better ignitability and burnout. Ashless coal is used as fuel for boilers, for example. Ashless coal has higher fluidity (softening and melting property) than raw coal. Ashless coal is used, for example, as a raw material for iron-making coke or a part of the raw material (mixed coal).

  The 2nd solvent separation apparatus 32 is an apparatus which performs a byproduct charcoal acquisition process. The byproduct charcoal acquisition step is a step of obtaining byproduct charcoal (also referred to as residual charcoal) by evaporating and separating the solvent from the solid concentration liquid separated by the separation device 25. The details of this byproduct coal are as follows. Byproduct charcoal is charcoal enriched with solvent-insoluble components (such as ash). By-product coal may have a higher ash concentration and a lower market value as fuel than raw material coal or ashless coal. The calorific value of by-product coal is inferior to ashless coal. However, the calorific value of byproduct charcoal is high enough to be used as a heating fuel such as slurry, and specifically, for example, 6000 kcal / kg or more. By-product coal exhibits higher ignitability and burn-off performance than raw coal. The by-product charcoal obtained by the second solvent separation device 32 (by-product charcoal having passed through the dryer 32b described later) is, for example, fine powder, and specifically has a particle size of, for example, less than 1 mm. The second solvent separation device 32 includes a solvent separator 32a and a dryer 32b.

  The solvent separator 32a is a device that performs a by-product charcoal mixture acquisition step. The by-product charcoal mixture acquisition step is a step of obtaining a by-product charcoal mixture by evaporating and separating the solvent from the solid concentration liquid separated by the separation device 25. This byproduct charcoal mixture contains byproduct charcoal and the solvent remaining without being separated by the solvent separator 32a. The solvent in the byproduct charcoal mixture is, for example, 5 to 10% by weight. As a method for evaporating and separating the solvent in the second solvent separation device 32, there are a distillation method and an evaporation method, as in the method for evaporating and separating the solvent in the first solvent separation device 31. This evaporative separation is preferably performed in the presence of an inert gas such as nitrogen (the same applies to the dryer 32b).

  The dryer 32b is an apparatus that performs a by-product charcoal mixture drying process. The byproduct charcoal mixture drying step is a step of evaporating and separating the solvent (residual solvent) from the byproduct charcoal mixture obtained by the solvent separator 32a. The byproduct charcoal mixture drying step is a step of obtaining byproduct charcoal that does not contain (or hardly contains) a solvent by drying the solvent contained in the byproduct charcoal mixture. The dryer 32b is, for example, a steam tube dryer. For example, the dryer 32b heats, stays, and stirs the by-product coal mixture while circulating nitrogen gas as a carrier gas inside the dryer 32b.

  The circulation path 41 is a flow path (passage, piping) for performing a circulation process. The circulation step is a step of circulating the solvent evaporated and separated by the solvent separation device 30. The circulation path 41 is a flow path through which the solvent flows. The circulation path 41 supplies the solvent evaporated and separated by the solvent separator 30 to the slurry preparation tank 21 through the solvent tank 11 (not necessarily through the solvent tank 11). The circulation path 41 allows the solvent to be repeatedly used in the ashless coal production apparatus 1.

  The heat exchanger 42 (heating device) is a device that performs a circulation path temperature raising step (heating step). The circulation path temperature raising step is a step of raising the temperature of the solvent flowing through the circulation path 41. The heat exchanger 42 is disposed in the circulation path 41. The heat exchanger 42 is disposed in a circulation path 41 between the solvent separation device 30 and the solvent tank 11. The heat exchanger 42 may be disposed in a circulation path 41 between the solvent tank 11 and the slurry preparation tank 21 (not shown). Although only one heat exchanger 42 is shown in FIG. 1, two or more heat exchangers 42 may be provided.

  The byproduct coal conversion device 50 is a device that performs a byproduct coal conversion process. The by-product coal conversion step is a step of gasifying the by-product coal obtained by the second solvent separation device 32. As shown in FIG. 2, the by-product coal conversion device 50 includes a gasification furnace 51, a reforming furnace 52, a heat recovery device 55, a process gas purification facility 61, and a gas holder 62. In FIG. 1, only a part of the byproduct coal conversion device 50 is shown.

  The gasification furnace 51 is a furnace that performs a gasification process. The gasification step is a step of obtaining process gas G1 (by-product coal production gas) by gasifying the by-product coal obtained by the second solvent separation device 32 shown in FIG. The process gas G1 is a gas generated from by-product coal generated in the production process (process) of ashless coal. The gasification furnace 51 gasifies the by-product coal obtained by the dryer 32b. The gasifier 51 may gasify the by-product coal in the by-product coal mixture obtained by the solvent separator 32a. The gasification furnace 51 is a coal gasification furnace. The coal gasification furnace reacts coal (by-product coal in this embodiment) with an oxidant under high temperature and high pressure, and thermally decomposes coal at a high temperature, thereby generating coal gas (process gas G1 in this embodiment). Is generated. In the present embodiment, what is gasified by the gasification furnace 51 is by-product coal, but generally, what is gasified by the coal gasification furnace is coal. Therefore, what is gasified (coal gasification) in the gasification furnace 51 is hereinafter referred to as “coal”.

(Basic reaction of coal gasification)
In the gasification furnace 51, coal is thermally decomposed. Then, oxygen and water vapor react with carbon. As a result, combustible gases (for example, CO and H ₂ ) are generated. More specifically, the following reaction occurs in the gasification furnace 51.
Pyrolysis of coal (by-product coal) → C, H, etc. C + O ₂ → CO ₂ + 97 kcal / mol
C + 1 / 2O ₂ → 2CO + 29.4 kcal / mol
_{C + CO 2 → 2CO - 38.2kcal} / mol
C + H ₂ O → CO + H ₂ −31.4 kcal / mol
C + 2H ₂ O → CO ₂ + 2H ₂ − 18.2 kcal / mol
CO + H ₂ O → CO ₂ + H ₂ +10.0 kcal / mol

(Coal gasification method)
The type of the gasification furnace 51 is, for example, a fixed bed gasification furnace, for example, a fluidized bed gasification furnace, for example, a spouted bed gasification furnace. Depending on the type of the gasification furnace 51, the particle size of the coal used, the gasification temperature, and the carbon conversion rate (ratio of the amount of carbon in the produced gas to the amount of carbon in the coal charged into the gasification furnace 51) Different.

In a fixed bed gasification furnace, coal is gasified in a state where the coal (coal coal) charged into the furnace is almost stationary. Details of the fixed bed gasifier are as follows. The coal used for gasification is a lump coal. Specifically, the average particle diameter of the coal used for gasification is 3 to 50 mm. Coal is fed into the furnace through a lock hopper (not shown). Coal in the furnace moves through the furnace from top to bottom to counter the upflow of gasifying agents (eg, oxygen and water vapor). During this transfer, the coal is first dried, then carbonized, and finally gasified. The gasification temperature is 800 to 1000 ° C. Ash (coal ash) is removed from the furnace in a solid or molten state depending on the type of process. Simultaneously with this gasification, methanation occurs and CH ₄ in the product gas increases. As CH ₄ increases, the proportion of chemical energy in the process gas G1 increases. As a result, the cold gas efficiency of the process gas G1 is increased (available energy is increased). In a fixed bed gasifier, heavy oil components such as tar (hereinafter referred to as “tar”) are more likely to be generated than in a fluidized bed gasifier or a spouted bed gasifier. More specifically, the gasification temperature of the fixed bed gasifier is lower than other methods. When the gasification temperature is low, tar or the like is not converted into a low-molecular product, and the tar or the like condenses during cooling. Therefore, tar and the like are likely to be generated in a fixed bed gasifier compared to other methods.

  In a fluidized bed gasification furnace, coal is gasified in a state where coal (pulverized coal) charged into the furnace forms a fluidized layer such as liquid. The details of the fluidized bed gasifier are as follows. The coal used for gasification is pulverized coal. Specifically, the average particle diameter of coal used for gasification is 1 to 6 mm. Since pulverized coal is used, the pulverization power of the coal can be reduced (as compared with a spouted bed gasifier using pulverized coal), or the pulverization power can be eliminated. The coal in the furnace is fluidized by a gasifying agent (for example, oxygen, air, and water vapor) to form a fluidized layer. Coal is gasified in this layer. The gasification temperature is set lower than the softening temperature of ash so that the flow state of the bed is not disturbed by the agglomeration phenomenon of particles. Specifically, the gasification temperature needs to be maintained at 800 to 1100 ° C. Since the gasification temperature can be increased as the melting point of ash (ash melting point) is higher, generation of tar and the like can be suppressed. Therefore, the fluidized bed gasifier is suitable for gasification of high ash melting point coal. This gasification temperature is lower than the gasification temperature of the spouted bed gasifier. Therefore, compared with the spouted bed gasifier, the carbon conversion rate is low despite the long residence time of the coal particles in the furnace. In order to increase the carbon conversion rate, it is necessary to use highly reactive coal.

  In the spouted bed gasification furnace, coal (pulverized coal) charged into the furnace is gasified in a jet state. The details of the spouted bed gasifier are as follows. Coal used for gasification is pulverized coal. Specifically, the average particle diameter of coal used for gasification is about 0.1 mm. Since pulverized coal is used, it is necessary to pulverize coal (by-product coal) (for example, as in pulverized coal thermal power generation). The coal in the furnace is in a jet state with the flow of the gasifying agent. The gasifying agent is oxygen or air. The gasifying agent contains a small amount of water vapor (small amount relative to oxygen or air) depending on the purpose. The gasification temperature is about 1500 to 1800 ° C. above the ash melting point (coal is gasified in a high temperature atmosphere). The ash is quenched with water and taken out of the furnace as an amorphous vitrified slag (in the slag state). In the furnace, char that remains without being gasified is generated. Char mainly contains fixed carbon and ash. The char is collected by a dust collector (such as a cyclone or an electric dust collector (not shown)) installed at the outlet of the gasification furnace 51, and then recharged into the gasification furnace 51. Advantages of the spouted bed gasifier compared with the fixed bed gasifier and fluidized bed gasifier (hereinafter “other methods”) are as follows. The gasification temperature of the spouted bed gasifier is higher than that of other systems, and is so high that tar and the like are not generated. Since this gasification temperature is higher than other methods, there is less unburned carbon content in the discharged ash than other methods. Since the gasification temperature is equal to or higher than the ash melting point (since the upper limit of the gasification temperature is not limited by the ash melting point), the spouted bed gasifier can be applied to coals with various ash melting points (the applicable range of coal types is wide). In general, the spouted bed gasifier has a larger coal throughput per volume of the gasifier 51 than the other methods, and can easily increase the capacity.

  As the gasification furnace 51, a fluidized bed type gasification furnace or a spouted bed type gasification furnace is preferable to a fixed bed gasification furnace. This is because the by-product charcoal obtained from the second solvent separation device 32 is in the form of powder or fine powder (for example, the average particle diameter is less than about 1 mm). Moreover, it is because the coal used for a fluidized bed type gasification furnace and a spouted bed type gasification furnace is good in gasification reactivity by having a large specific surface area compared with a fixed bed gasification furnace.

  The reforming furnace 52 (see FIG. 2) performs a reforming process. The reforming step is a step of reforming and gasifying a product (such as the above tar) in the gasification furnace 51 shown in FIG. When the gasification furnace 51 is a spouted bed type gasification furnace, tar and the like are not generated, so the reforming furnace 52 is unnecessary.

  The heat recovery device 55 performs a heat recovery process. The heat recovery process is a process of recovering thermal energy generated in the gasification furnace 51. The heat recovery device 55 performs sensible heat recovery of the process gas G <b> 1 obtained in the gasification furnace 51. The heat recovery device 55 recovers thermal energy as steam or electricity (electric power). The thermal energy recovered by the heat recovery device 55 is supplied to, for example, a component of the ashless coal production device 1 (see FIG. 1), and may be supplied to the outside of the ashless coal production device 1, for example. The heat recovery device 55 includes, for example, a waste heat boiler 56 and a steam turbine 57.

  The waste heat boiler 56 generates steam using the heat energy generated in the gasification furnace 51 (steam generation process).

  The steam turbine 57 generates electricity using the steam generated in the waste heat boiler 56 (electricity generation process).

  The process gas purification facility 61 purifies the process gas G1 generated in the gasification furnace 51 (process gas purification step).

  The gas holder 62 stores the process gas G1 purified by the process gas purification facility 61 (process gas storage step).

(Heating process)
This process gas G1 is used in the heating process. The heating step is a step in which slurry or the like (at least one of the slurry and the solvent) is heated using the process gas G1 obtained in the gasification furnace 51 as a fuel (energy source). The apparatus (heating apparatus) used for a heating process is the preheater 23, for example. The preheater 23 heats the slurry in the furnace with heat generated by burning the process gas G1. In addition, the other specific example of a heating process is mentioned later.

(Comparison of running costs)
The running costs of the ashless coal production apparatus 1 of the present embodiment shown in FIG. 1 and the ashless coal production apparatus 201 (described later) of Comparative Example 1 shown in FIG. 4 were compared.

(Running cost of this embodiment)
In the ashless coal manufacturing apparatus 1 shown in FIG. 1, the fuel for heating the slurry in the preheater 23 (hereinafter “slurry heating”) is a process gas G1 generated from byproduct coal. For this reason, by-product coal necessary for generating the process gas G1 cannot be sold. Therefore, the loss (outside sales opportunity loss) caused by the inability to sell by-product coal was calculated. An example of the calculation is as follows. Assume that the slurry preparation tank 21 prepares a slurry by mixing 500 kg / h of raw material coal (water content 10 wt%) and 1800 kg / h of a solvent. At this time, the energy required for heating the slurry by the preheater 23 is about 0.037 × 10 ⁶ kcal / h (the same applies to Comparative Example 1 described later). The lower heating value (LHV) of the process gas G1 is assumed to be 1100 kcal / Nm ³ . Then, the process gas G1 required for slurry heating is about 33.6 Nm ³ / h. Assuming that the process gas G1 obtained for 1 kg of by-product coal is about 2.9 Nm ³ / h, the by-product coal required to generate the process gas G1 required for slurry heating is about 11.6 kg / h. It is. If the price of by-product coal is 7,000 yen / ton (which is cheaper than the price of steam coal), the loss of opportunity for external sales of by-product coal will be 80.5 yen / h (64,000 yen per year).

(Running cost of Comparative Example 1)
In FIG. 4, the ashless-coal manufacturing apparatus 201 of the comparative example 1 is shown. The difference between the ashless coal production apparatus 201 and the ashless coal production apparatus 1 (see FIG. 1) is that the fuel of the preheater 23 is only natural gas (NG) or LP gas (LPG; Liquefied Petroleum Gas). It is only a point. The running cost (fuel cost) of the ashless coal manufacturing apparatus 201 of Comparative Example 1 was calculated.

(When the fuel is only natural gas) When the fuel in the preheater 23 is only natural gas, the natural gas required for slurry heating is about 4.331 Nm ³ / h. If the price of natural gas is about 60 yen / Nm ³ , the fuel cost of natural gas required for slurry heating is 260 yen / h (2,080,000 yen per year). Therefore, compared with the case where only natural gas is used as the fuel for the preheater 23, the ashless coal production apparatus 1 (see FIG. 1) of the present embodiment reduces the running cost by about 180 yen / h (144,000 yen per year). It becomes.

  (When the fuel is only LP gas) When the fuel of the preheater 23 is only LP gas, the LP gas required for slurry heating is about 3.7 kg / h. If the price of LP gas is about 90 yen / kg, the fuel cost of LP gas required for slurry heating is 333 yen / h (266.4 million yen per year). Therefore, compared with the case where only LP gas is used as fuel for the preheater 23, the ashless coal production apparatus 1 (see FIG. 1) of the present embodiment reduces the running cost of about 250 yen / h (2 million yen per year) It becomes.

(Comparison between solid fuel and gas fuel)
The process gas G1 used as fuel in the heating process is a gas fuel. The merit of gas fuel over solid fuel is explained.

(Solid fuel)
In FIG. 5, the ashless-coal manufacturing apparatus 301 of the comparative example 2 is shown. The ashless coal production apparatus 301 of Comparative Example 2 is an example of a case where the heating fuel such as slurry is a solid fuel. Differences of the ashless coal production apparatus 301 of Comparative Example 2 with respect to the ashless coal production apparatus 1 (see FIG. 1) are the following [difference a] and [difference b]. [Difference a] The fuel of the preheater 23 is by-product coal (RC) that has not been gasified, and is a solid fuel. [Difference b] A humidifier 370 for adjusting the water content of the by-product coal is provided. The humidifier 370 is provided in order to improve the handling property of byproduct charcoal (for example, to suppress scattering by wind).

(Gas fuel)
As shown in FIG. 1, in the ashless coal manufacturing apparatus 1 of the present embodiment, the fuel of the preheater 23 (fuel used in the heating process) is a process gas G1 that is a gas fuel. Therefore, compared with the case where the fuel used for a heating process is a solid fuel, there exist the following [merits a]-[merits e]. [Merit a] Fuel handling (eg, movement and storage of fuel) is easy. For example, in the ashless coal production apparatus 301 of Comparative Example 2 (see FIG. 5), a humidifier 370 (see FIG. 5) is provided to improve the handleability of solid fuel, but ashless coal production using gas fuel is used. In the device 1, the humidifier 370 is not necessary. [Merit b] Fuel can be stably supplied to the preheater 23. [Merit c] The property of the fuel (for example, the degree of drying) is stable. [Merit d] Good fuel combustion performance.

  Furthermore, when a spouted bed type gasification furnace is used as the gasification furnace 51, the following [merit e] is obtained with respect to the ashless coal production apparatus 301 (see FIG. 5) of Comparative Example 2. [Merit e] The ash discharge volume can be reduced. More specifically, in the ashless coal production apparatus 301 of Comparative Example 2 (see FIG. 5), ash (referred to as “ash α”) is generated when by-product coal as a solid fuel is burned. On the other hand, as described above, in the ashless coal production apparatus 1, slag ash is generated in the gasification step (gasification furnace 51). The slag ash has a smaller volume than the “ash α”.

(Comparison of fluid heating means)
The preheater 23 used in the heating process is a gas-fired heating furnace. The characteristics (properties) of the gas-fired heating furnace will be described. As the fluid heating means, for example, an electric heater, a heat medium heater, an induction heat transfer type heating furnace, a gas-fired heating furnace, an oil-fired heating furnace, and the like are generally known. Also, as a fluid heating means, there is generally a coal-fired heating furnace that is not widespread. Table 1 shows an outline (image) of the properties of each heating means.

  The disadvantages of each heating means are as follows. Electric heaters and heat medium heaters are not suitable for large-capacity heating that is used in ashless coal production methods. An induction heat transfer type heating furnace has a higher equipment cost than other heating means and is difficult to apply to large-capacity heating. The fuel of a gas-fired heating furnace or an oil-fired heating furnace (hereinafter referred to as “gas-fired heating furnace”) is generally, for example, natural gas, propane gas, or heavy oil. These fuels are hardly cheap (see “(Running Cost of Comparative Example 1)” above). As a result of the high fuel cost, the running cost required for the production of ashless coal increases. Coal-fired furnaces are generally not widespread, and therefore have a large development factor (risk). The development factors of the coal-fired heating furnace include, for example, the effects on heat transfer performance due to ash adhesion, countermeasures for slagging and fouling, and coking and corrosion countermeasures for heating tubes by local heating. In addition, since solid fuel is used in the coal-fired heating furnace, as described above, it is inferior in terms of fuel handling properties and the like as compared with the case where gas fuel is used.

  The advantages of gas-fired heating furnaces and coal-fired heating furnaces are as follows. A gas-fired heating furnace or the like is used for large-capacity heating of various process fluids, and can be applied to an ashless coal production method (ashless coal production apparatus 1). Furthermore, a gas-fired heating furnace or the like does not require an exhaust gas treatment facility or a post-combustion residue treatment facility (for example, an ash treatment facility). In addition, when by-product coal is used as the fuel for the coal-fired heating furnace, the fuel cost can be reduced compared to the case where the fuel is natural gas or the like.

  Therefore, in the heating process of the ashless coal manufacturing method (ashless coal manufacturing apparatus 1) of the present embodiment, the slurry or the like is heated using the process gas G1 gasified from the by-product coal as fuel. Therefore, the disadvantages of the gas-fired heating furnace (high fuel cost) and the disadvantages of the coal-fired heating furnace (solid fuel, development factor) can be eliminated. Further, the advantages of a gas-fired heating furnace (applicable for large-capacity heating, use of gas fuel, etc.) and the advantages of a coal-fired heating furnace (reduction in fuel cost) can be obtained.

(effect)
The effects of the ashless coal production apparatus 1 and the ashless coal production method shown in FIG. 1 will be described. Below, the apparatus (equipment corresponding to each process) used in order to perform each process is shown in parentheses after the process name.

(Effect 1) (Invention 1, 3)
The ashless coal production method (ashless coal production device 1) includes a separation step (extraction tank 24 and separation device 25), an ashless coal acquisition step (first solvent separation device 31), and a byproduct coal acquisition step (first). Two-solvent separator 32). The ashless coal production method (ashless coal production apparatus 1) includes a gasification step (gasification furnace 51) and a heating step (preheater 23). The separation step (extraction step (extraction tank 24)) is a step of heating a slurry obtained by mixing coal and a solvent to extract coal components soluble in the solvent. The separation step (separation device 25) includes a slurry (slurry obtained in the extraction step (extraction tank 24)), a solution in which a coal component soluble in a solvent (solvent soluble component) is dissolved, and coal insoluble in a solvent. This is a step of separating the solid (concentrated insoluble component) into a solid concentrate. The ashless coal acquisition step (first solvent separation device 31) is a step of obtaining ashless coal (HPC) by evaporating and separating the solvent from the solution separated in the separation step (separation device 25). The byproduct charcoal acquisition step (second solvent separation device 32) is a step of obtaining byproduct charcoal (RC) by evaporating and separating the solvent from the solid content concentrate separated in the separation step (separation device 25).
[Configuration 1-1] The gasification step (gasification furnace 51) is a step of obtaining the process gas G1 by gasifying the by-product coal obtained in the by-product coal acquisition step (second solvent separation device 32). is there.
[Configuration 1-2] The heating step (preheater 23) is a step of heating the slurry or solvent using the process gas G1 obtained in the gasification step (gasification furnace 51) as a fuel (about heating of the solvent). Later).

  In the above [Configuration 1-1] and [Configuration 1-2], the raw material of the fuel used in the heating step (preheater 23) is a byproduct obtained in the byproduct coal acquisition step (second solvent separation device 32). Charcoal. Therefore, compared with the case where only fuel other than by-product coal obtained in the by-product coal acquisition process (second solvent separation device 32) is used for the heating process (pre-heater 23), it is used for the heating process (pre-heater 23). The fuel cost of the produced fuel can be suppressed. Therefore, the fuel cost for heating the slurry or the solvent (at least one of the slurry and the solvent) can be suppressed. As a result, the running cost required for producing ashless coal can be suppressed. As a result, ashless coal can be manufactured at low cost.

  In the above [Configuration 1-2], the fuel used for the heating step (preheater 23) is the process gas G1, which is a gas fuel. Therefore, compared with the case where the by-product coal obtained in the by-product coal acquisition step (second solvent separation device 32) is used in the heating step (preheater 23) as a solid fuel without being gasified, the fuel is handled. Can be easily performed. Therefore, the fuel can be easily (reliably and stably) supplied to the heating device (preheater 23). Therefore, the heating device (preheater 23) for heating the slurry or the solvent can be stably operated.

(Second Embodiment)
With reference to FIG. 3, the difference with 1st Embodiment is demonstrated about the ashless coal manufacturing apparatus 101 of 2nd Embodiment. In addition, about the common point with 1st Embodiment among the ashless coal manufacturing apparatuses 101, the code | symbol (refer FIG. 1) same as 1st Embodiment was attached | subjected, and description was abbreviate | omitted. In the ashless coal manufacturing apparatus 101, the fuel used for the heating step (preheater 23) is a mixed gas G3 in which the process gas G1 and the extraction tank generated gas G2 are mixed. The extraction tank product gas G2 is used as an auxiliary fuel for the heating process (preheater 23). The fuel used for the heating process (preheater 23) is, for example, only the mixed gas G3.

(Effect 2) (Invention 2)
[Configuration 2] The fuel in the heating step (preheater 23) is the extraction tank generated gas G2 generated in the extraction step (extraction tank 24) for extracting the coal component soluble in the solvent by heating the slurry, and the process gas G1. And a mixed gas G3.

  With the above [Configuration 2], the fuel cost of the fuel used in the heating step (preheater 23) can be further reduced as compared with the case where the extraction tank generated gas G2 is not used in the heating step (preheater 23).

(Modification of heating process)
The heating process can be variously modified. The heating mode of the heating step is, for example, the following [direct heating], and for example, the following [indirect heating] may be performed, and both [direct heating] and [indirect heating] may be performed.
[Direct heating] The slurry and the like are directly heated by heat generated by burning the process gas G1. For example, as described above, the preheater 23 heats the slurry in the furnace with the heat generated by burning the process gas G1.
[Indirect heating] A heat exchange medium (for example, liquid or gas) is heated by heat generated by burning the process gas G1, and the heat exchange is performed between the heat exchange medium and the slurry. It may be heated. The heat exchange medium is heated by a gas-fired furnace (not shown). Heat exchange between the heat exchange medium and the slurry is performed by, for example, the heat exchanger 42, the slurry preparation tank 21, or the extraction tank 24.

The heating target in the heating step is at least one of slurry and solvent. The heating target in the heating step is, for example, the following [heating target a], and may be [heating target b] to [heating target d] or the like. The heating target in the heating process may be one or a plurality of the following heating targets.
[Heating object a] The heating object in the heating process is the slurry before being prepared in the slurry preparation tank 21 and supplied to the extraction tank 24. In this case, the heating device that performs the heating process is the preheater 23 that performs the preheating process.
[Heating object b] The heating object in the heating step may be the slurry in the slurry preparation tank 21. In this case, the heating apparatus that performs the heating process is the slurry preparation tank 21 (the heating apparatus and the slurry preparation tank 21 are used together).
[Heating target c] The heating target in the heating step may be slurry in the extraction tank 24. In this case, the heating apparatus that performs the heating process is the extraction tank 24 (the heating apparatus and the extraction tank 24 are used together).
[Heating target d] The heating target in the heating step may be a solvent before being supplied to the slurry preparation tank 21. For example, the heating target in the heating step is the following [heating target d-1] or [heating target d-2].
[Heating target d-1] The heating target in the heating step may be a solvent passing through the circulation path 41. In this case, the heating device that performs the heating process is the heat exchanger 42 that performs the circuit heating process.
[Heating target d-2] The heating target in the heating step may be a solvent that does not pass through the circulation path 41 and may be a solvent supplied to the slurry preparation tank 21.

  The fuel used in the heating step (for example, the preheater 23) is only the process gas G1 (see FIG. 1) in the first embodiment, for example, and is only the mixed gas G3 (see FIG. 3) in the second embodiment, for example. . However, the fuel used in the heating process (for example, the preheater 23) only needs to contain at least the process gas G1. For example, the fuel used in the heating process may include natural gas, LP gas, heavy oil, or the like.

  Some of the components of the above-described embodiment may be omitted. For example, the circulation path 41 may not be provided. Further, for example, at least one heating device (such as the preheater 23 and the heat exchanger 42) used in the heating process may be used.

1 Ashless coal production equipment (ashless coal production equipment)
21 Slurry preparation tank (heating device)
23 Preheater (heating device)
24 Extraction tank (heating device)
25 Separator 31 First solvent separator 32 Second solvent separator 42 Heat exchanger (heating device)
51 Gasification furnace G1 Process gas G2 Extraction tank product gas G3 Mixed gas

Claims (3)

A slurry obtained by mixing coal and a solvent is heated to extract a coal component soluble in the solvent, a solution in which the coal component soluble in the solvent is dissolved, and the coal component insoluble in the solvent A separation step of separating into a concentrated solid content liquid,
Ashless coal acquisition step of obtaining ashless coal by evaporating and separating the solvent from the solution separated in the separation step;
By-product charcoal obtaining step for obtaining by-product coal by evaporating and separating the solvent from the solid concentrate separated in the separation step;
A gasification step of obtaining a process gas by gasifying the by-product coal obtained in the by-product coal acquisition step;
A heating step of heating the slurry or the solvent using the process gas obtained in the gasification step as a fuel;
A method for producing ashless coal. The fuel in the heating step is a mixed gas in which the process gas is mixed with a gas generated in the extraction step of extracting the coal component soluble in the solvent by heating the slurry.
The manufacturing method of the ashless coal of Claim 1. An extraction tank for heating a slurry obtained by mixing coal and a solvent to extract a coal component soluble in the solvent;
A separator for separating the slurry obtained in the extraction tank into a solution in which the coal component soluble in the solvent is dissolved and a solid content concentrate in which the coal component insoluble in the solvent is concentrated;
A first solvent separation device for obtaining ashless coal by evaporating and separating the solvent from the solution separated by the separation device;
A second solvent separation device for obtaining by-product charcoal by evaporating and separating the solvent from the solid concentrate separated by the separation device;
A gasification furnace for obtaining a process gas by gasifying the by-product coal obtained by the second solvent separation device;
A heating device for heating the slurry or the solvent using the process gas obtained in the gasification furnace as a fuel;
An apparatus for producing ashless coal.

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