JP6018516B2 - Aging apparatus for reducing spontaneous heat generation of modified low-grade coal, and operation method thereof - Google Patents

Description

  The present invention relates to an aging device for reducing the spontaneous heat generation of a modified low-grade coal obtained by reforming low-grade coal such as lignite and sub-bituminous coal, which has a lower degree of coalification than bituminous coal, and an operating method thereof.

  For example, Patent Document 1 is a document related to the technology in this field. In Patent Document 1, a high-temperature carbonaceous material (for example, low grade coal) is filled in a processing vessel, and the carbonaceous material is indirectly used with a coolant circulating in a heat exchange plate installed in the processing vessel. Is cooled to the target temperature. Further, in the processing container, the oxygen-containing gas and the carbonaceous material are brought into contact with each other to partially oxidize the carbonaceous material. The temperature of the carbonaceous material is controlled by a coolant that circulates in the heat exchange plate so that the temperature of the carbonaceous material during oxidation does not increase due to a rise in temperature.

Special Table 2002-506469

  The present applicant is researching and developing low-grade coal (low-grade coal) such as lignite and subbituminous coal to be used as fuel. The reforming of low-grade coal is, for example, drying (dehydrating) the low-grade coal, and the amount of heat generated is increased by dehydrating the low-grade coal. As a method for dehydrating low-grade coal, there is a method called dehydration in oil in which low-grade coal is dehydrated in oil.

  Here, the modified low-grade coal obtained by modifying the low-grade coal has a property of high pyrophoricity immediately after its production. As a method for reducing the pyrophoricity of the modified low-grade coal, for example, as described in Patent Document 1, a gas containing oxygen and a carbonaceous material are contacted to partially oxidize the carbonaceous material. There is a way. Thereby, the oxidation activity of the carbonaceous material produced at a low temperature is reduced, and its pyrophoricity is lowered. This method is called “aging” by the applicant.

  In this aging process, as described in Patent Document 1, the temperature of the carbonaceous material (product) filled in the processing container is controlled. However, with temperature control alone, the product dries immediately after the aging process due to oxidation in the aging process. The dried product absorbs moisture in the air and generates heat of adsorption. Also, dry products tend to generate heat in the first place. Accordingly, with temperature control alone, the product is likely to ignite due to spontaneous heating immediately after the aging process. In order to prevent the ignition due to the spontaneous heat generation, another process (Rehydration Cooler) is necessary in which water is supplied to the product after the aging process.

  Further, during the aging process, the temperature in the processing container (the temperature of the carbonaceous material filled in the processing container) may increase locally. A portion where the temperature rises locally in the processing container (the carbonaceous material filled in the processing container) is called a “hot spot”. In the temperature measurement in the processing container using a thermometer, the temperature measurement location is limited, and there is a problem that it is difficult to grasp a local temperature rise location (hot spot) in the processing vessel.

  This invention is made | formed in view of the said situation, The 1st objective is to provide the technique which can prevent a modified | denatured low rank coal adsorb | sucking water | moisture content and heat-generating after an aging process. . As a result, the modified low-grade coal after the aging process can be safely piled. Note that the “piling” means that the modified low-grade coal or the like is piled up, for example.

  A second object of the present invention is to provide a technique capable of performing aging while grasping hot spots generated in a processing container (carbonaceous material filled in the processing container).

  A first aspect of the present invention for achieving the first object described above is an aging device for reducing the spontaneous heat generation property of a modified low-grade coal, comprising a processing vessel filled with the modified low-grade coal, A gas supply means for supplying a gas containing oxygen to the processing container, an oxygen concentration adjusting means for adjusting the oxygen concentration in the gas, a humidity adjusting means for adjusting the humidity of the gas, and the processing A container thermometer for detecting the temperature in the container, and the oxygen concentration adjusting means is controlled based on the detected value of the container thermometer to adjust the oxygen concentration in the gas. An aging apparatus comprising: control means for adjusting the humidity of the gas by controlling the humidity adjusting means so that the low-quality coal does not dry due to a temperature rise due to oxidation.

  According to this configuration, the humidity of the modified low-grade coal can be adjusted during the aging process. As a result, it is possible to prevent the modified low-grade coal from adsorbing moisture and generating heat after the aging process.

  In the present invention, it is preferable that the control means controls the humidity adjusting means so that the moisture of the modified low-grade coal in the processing vessel reaches equilibrium moisture.

  According to this configuration, it is possible to further prevent the modified low-grade coal from adsorbing moisture and generating heat after the aging process.

  Further, in the present invention, the control means further controls the oxygen concentration adjusting means to control the oxygen concentration adjusting means when the ratio of the carbon dioxide concentration to the carbon monoxide concentration in the gas exiting the processing container increases. It is preferable to reduce the oxygen concentration.

  When the hot spot (local high temperature portion) is generated in the processing vessel (modified low-grade coal filled in the processing vessel), the present inventors have developed a carbon dioxide concentration relative to the carbon monoxide concentration in the gas subjected to aging. We found that the ratio of carbon concentration increased.

  In other words, according to this configuration, it is possible to perform aging while grasping hot spots generated in the processing vessel (modified low-grade coal filled in the processing vessel), and more safely (spontaneous ignition in the processing vessel). Aging can be performed while preventing).

  The second aspect of the first aspect of the present invention is a modified low-grade coal comprising a processing vessel filled with a modified low-grade coal, and a gas supply means for supplying a gas containing oxygen to the processing vessel. An operation method of an aging device for reducing spontaneous heat generation, wherein the oxygen concentration in the gas is adjusted based on a measured temperature value in the processing container, and a modified low-grade coal in the processing container An operating method of an aging apparatus, wherein the humidity of the gas is adjusted so as not to dry due to a temperature rise due to oxidation.

  According to this configuration, the humidity of the modified low-grade coal can be adjusted during the aging process. As a result, it is possible to prevent the modified low-grade coal from adsorbing moisture and generating heat after the aging process.

  Moreover, in this invention, it is preferable to adjust the humidity of the said gas so that the water | moisture content of the modification | reformation low grade coal in the said processing container may reach an equilibrium water | moisture content.

  According to this configuration, it is possible to further prevent the modified low-grade coal from adsorbing moisture and generating heat after the aging process.

  Furthermore, in this invention, when the ratio of the carbon dioxide concentration with respect to the carbon monoxide concentration in the said gas which left the said processing container rises, it is preferable to reduce the oxygen concentration in the said gas supplied to the said processing container.

  According to this configuration, it is possible to perform aging while grasping hot spots generated in the processing vessel (modified low-grade coal filled in the processing vessel), and more safely (preventing spontaneous ignition in the processing vessel). Aging) can be performed.

  The second aspect of the present invention for achieving the second object described above is an aging apparatus for reducing the spontaneous heat generation of the modified low-grade coal, in which the modified low-grade coal is charged. A container, gas supply means for supplying a gas containing oxygen to the processing container, oxygen concentration adjusting means for adjusting the oxygen concentration in the gas, and carbon monoxide concentration in the gas exiting the processing container An aging device comprising: control means for controlling the oxygen concentration adjusting means to reduce the oxygen concentration in the gas when the ratio of the carbon dioxide concentration to the gas rises.

  As a result of intensive studies to achieve the above-described second object, the present inventors have found that a hot spot (local high-temperature portion) is generated in the processing container (modified low-grade coal filled in the processing container). It was found that the ratio of the carbon dioxide concentration to the carbon monoxide concentration in the gas subjected to aging increases. Based on this knowledge, the second invention described above has been completed.

  According to the second aspect of the present invention, aging can be performed while grasping hot spots generated in the processing container (modified low-grade coal filled in the processing container). As a result, aging can be performed more safely (while preventing spontaneous ignition in the processing container).

  The second aspect of the second aspect of the present invention is a modified low-grade coal comprising a processing vessel filled with a modified low-grade coal, and a gas supply means for supplying a gas containing oxygen to the processing vessel. An operation method of an aging device for reducing spontaneous heat generation, wherein the ratio of carbon dioxide concentration to the concentration of carbon monoxide in the gas exiting the processing vessel is increased when supplied to the processing vessel. An operation method of an aging apparatus characterized by lowering an oxygen concentration in a gas.

  According to this configuration, aging can be performed while grasping hot spots generated in the processing vessel (modified low-grade coal filled in the processing vessel).

  According to the first aspect of the present invention, the humidity of the reformed low-grade coal can be adjusted during the aging process by controlling (adjusting) the humidity of the aging gas that has not had a control concept in the aging process. . As a result, it is possible to prevent the modified low-grade coal from adsorbing moisture and generating heat after the aging process. As a result, the modified low-grade coal after the aging process can be safely piled.

  Further, according to the second aspect of the present invention, the oxygen concentration in the gas is controlled (adjusted) based on the ratio of the carbon dioxide concentration to the carbon monoxide concentration in the aging gas. It is possible to perform aging while grasping hot spots generated in the modified low-grade coal filled in the steel.

1 is a block diagram showing an aging device according to a first embodiment of the present invention. During the aging process, the moisture content of the modified low-grade coal filled in the processing vessel constituting the aging apparatus shown in FIG. 1, the temperature in the processing vessel, the oxygen concentration, humidity, temperature, and flow rate of the aging gas It is a chart figure which shows a change. It is a block diagram which shows the aging apparatus which concerns on 2nd Embodiment of this invention.

  Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings. In the following description, the target of “aging” is modified lignite. As described above, “aging” means that the carbonaceous material is partially oxidized by bringing a gas containing oxygen into contact with the carbonaceous material to reduce the oxidation activity of the carbonaceous material generated at a low temperature. Say. Thereby, the pyrophoric property of a carbonaceous material falls.

  Further, the modified lignite refers to a product obtained by drying (dehydrating) lignite. The calorific value is increased by dehydrating lignite. As a dehydration method of lignite, there is a method called dehydration in oil in which lignite is dehydrated in oil. In addition, the modified low-grade coal obtained by modifying sub-bituminous coal, lignite, peat or the like instead of the modified lignite can be “aged” using an aging apparatus described below.

(First embodiment)
(Configuration of aging equipment)
An aging device 100 according to a first embodiment of the present invention will be described with reference to FIG. As shown in FIG. 1, the aging apparatus 100 includes a processing container 1 filled with modified lignite and a blower 2 for supplying an aging gas to the processing container 1. The aging gas is a gas containing oxygen.

  The blower 2 and the processing container 1 are connected to each other through a gas supply path 31 and a gas return path 32. The gas supply path 31 and the gas return path 32 are conduits (ducts) serving as gas passages. In this embodiment, the aging gas is circulated between the blower 2 and the processing container 1, but the aging gas may not be circulated between the blower 2 and the processing container 1. In other words, the aging gas discharged from the processing container 1 may be exhausted outside without returning to the blower 2.

  A heat exchanger 3 is provided in the gas supply path 31. The heat exchanger 3 is for adjusting the temperature and humidity of the aging gas by cooling the aging gas supplied to the processing vessel 1. A cooling water introduction path 37 (cooling water introduction pipe) for supplying cooling water to the heat exchanger 3 is connected to the heat exchanger 3. A cooling water amount adjusting valve 9 is attached to the cooling water introduction path 37.

  A gas supply path 31 between the blower 2 and the heat exchanger 3 has a nitrogen gas introduction path 34 (nitrogen gas introduction pipe) for supplying nitrogen gas to the gas supply path 31, and steam to the gas supply path 31. A steam introduction path 35 (steam introduction pipe) for supply is connected. The nitrogen gas introduction path 34 is disposed on the upstream side of the steam introduction path 35. A nitrogen supply valve 7 is attached to the nitrogen gas introduction path 34, and a steam supply valve 8 is attached to the steam introduction path 35.

  A return gas amount adjusting valve 5 is attached to the gas return path 32. An outside air introduction path 36 (outside air introduction pipe) for supplying outside air (air) to the gas return path 32 is connected to the gas return path 32 between the return gas amount adjusting valve 5 and the blower 2. An outside air supply valve 6 is attached to the outside air introduction path 36. An exhaust path 33 (exhaust pipe) that guides the gas exiting the processing container 1 to the outside is connected to the gas return path 32 between the processing container 1 and the return gas amount adjusting valve 5.

  The return gas amount adjustment valve 5, the outside air supply valve 6, the nitrogen supply valve 7, the steam supply valve 8, and the cooling water amount adjustment valve 9 are all electrically operated valves that can maintain the valve opening at an intermediate opening. is there.

  An in-container thermometer 10 for detecting the temperature in the container is attached to the processing container 1. In the aging process, since the processing container 1 is filled with the modified lignite, detecting the temperature in the container is equal to detecting the temperature of the filled modified lignite. That is, detecting the temperature in the container means detecting the temperature of the filled modified lignite. In addition, the modification | reformation lignite of the process target is made into the form of the compacted briquette, for example. The aging gas is supplied from the lower part of the processing container 1 into the processing container 1 and exits from the upper part of the processing container 1 to the gas return path 32. It is preferable that a plurality of in-container thermometers 10 are attached (inserted) to the processing container 1.

  In the gas supply path 31 between the heat exchanger 3 and the processing vessel 1, an oxygen concentration meter 11 for measuring the oxygen concentration in the gas of the aging gas supplied to the processing vessel 1, the humidity of the aging gas, A hygrometer 12, a thermometer 13, and a flow meter 14 for measuring temperature and flow rate are attached.

  Here, the aging device 100 includes a control unit 4. The control unit 4 determines the oxygen concentration of the aging gas supplied from the blower 2 to the processing container 1 based on the temperature in the processing container 1 detected by the in-container thermometer 10 (temperature of the filled modified brown coal). For controlling humidity, temperature and flow rate. For example, the control unit 4 adjusts the oxygen concentration, humidity, temperature, and flow rate of the aging gas so that the temperature in the processing container 1 (the temperature of the charged modified brown coal) is between 40 ° C. and 70 ° C. Control (see FIG. 2). In addition, the said temperature can be made into the optimal range suitably.

  The control unit 4 of this embodiment controls the opening degrees of the return gas amount adjustment valve 5, the outside air supply valve 6, the nitrogen supply valve 7, the steam supply valve 8, and the cooling water amount adjustment valve 9. Signals from the in-container thermometer 10, the oxygen concentration meter 11, the hygrometer 12, the thermometer 13, and the flow meter 14 are taken into the control unit 4.

(Oxygen concentration control)
The control unit 4 controls the opening degree of at least one of the return gas amount adjustment valve 5, the outside air supply valve 6, and the nitrogen supply valve 7 on the basis of the signal from the oximeter 11, thereby aging. Control the oxygen concentration of the gas. Since oxygen in the aging gas is consumed in the processing container 1, the oxygen concentration in the gas (circulation gas) leaving the processing container 1 decreases. In this embodiment, since the oxygen concentration of the aging gas is adjusted using this circulating gas, the amount of nitrogen gas used for oxygen concentration adjustment can be reduced. If the amount of outside air supplied from the outside air introduction path 36 is constant, the amount of gas (circulated gas) sucked into the blower 2 is increased by increasing the opening degree of the return gas amount adjusting valve 5, and the oxygen concentration in the aging gas is increased. If the opening of the return gas amount adjusting valve 5 is decreased, the amount of gas discharged outside from the exhaust passage 33 without being sucked into the blower 2 is increased, and the oxygen concentration in the aging gas is increased. Note that the oxygen concentration adjusting gas added to the aging gas need not be nitrogen gas, and an inert gas other than nitrogen gas may be used.

  In this embodiment, the return gas amount adjusting valve 5, the outside air supply valve 6, and the nitrogen supply valve 7 correspond to an oxygen concentration adjusting means for adjusting the oxygen concentration of the aging gas. When the aging gas is not circulated, the return gas amount adjusting valve 5 and the outside air supply valve 6 correspond to an oxygen concentration adjusting means for adjusting the oxygen concentration of the aging gas.

(Temperature and humidity control)
The control unit 4 controls the opening degree of at least one of the steam supply valve 8 and the cooling water amount adjusting valve 9 based on the signals from the hygrometer 12 and the thermometer 13, so that the inside of the processing container 1 The humidity (and temperature) of the aging gas is controlled so that the charged modified lignite does not dry due to a temperature rise caused by low-temperature oxidation due to contact with the aging gas. For example, in order to increase the humidity of the aging gas, the opening of the steam supply valve 8 is increased to increase the amount of steam supplied to the aging gas, or the opening of the cooling water amount adjusting valve 9 is increased to increase the heat exchanger 3. Control is performed to increase the amount of cooling water supplied to the gas and to lower the temperature of the aging gas.

  In the present embodiment, the steam supply valve 8 and the cooling water amount adjusting valve 9 correspond to humidity adjusting means (temperature / humidity adjusting means) for adjusting the humidity (and temperature) of the aging gas.

(Flow control)
The control unit 4 controls the opening degree of at least one of the return gas amount adjustment valve 5, the outside air supply valve 6, the nitrogen supply valve 7, and the steam supply valve 8 based on a signal from the flow meter 14. Thus, the flow rate of the aging gas is controlled. The control unit 4 performs flow rate control while performing oxygen concentration control and temperature / humidity control of the aging gas.

(Specific control example by control unit)
A specific control example by the control unit 4 will be described with reference to FIGS. 1 and 2. 2 shows the moisture content of the modified lignite filled in the processing vessel 1 during the aging process, the temperature in the processing vessel 1 (filled modified lignite), the oxygen concentration / humidity in the gas of the aging gas, It is a chart figure showing change of temperature and flow, and the horizontal axis is time.

  First, in response to a signal from the control unit 4, the outside air supply valve 6 is opened, and the return gas amount adjustment valve 5, the nitrogen supply valve 7, the steam supply valve 8, and the cooling water amount adjustment valve 9 are closed. It is assumed that the blower 2 is operating. Thereby, outside air (aging gas) is supplied to the processing container 1. When the outside air and the modified lignite are brought into contact with each other in the processing container 1, the modified lignite is partially oxidized at a low temperature and the temperature in the processing container 1 is increased. At this time, the entire amount of gas discharged from the processing container 1 is discharged from the exhaust path 33.

  The return gas amount adjusting valve 5 is opened, and the outside air supply valve 6, nitrogen supply valve 7, steam supply valve 8, and cooling water amount adjusting valve 9 are closed, and the gas supply path 31 and the gas return path 32 exist. After circulating the gas, the outside air supply valve 6 may be gradually opened to put in outside air. Further, the steam supply valve 8 and the cooling water amount adjusting valve 9 are not necessarily closed.

When the temperature in the processing chamber 1 reaches T _U, the control unit 4 to supply nitrogen to the aging gas by opening the nitrogen supply valve 7 to a predetermined opening degree. Thereby, the oxygen concentration in the gas of the aging gas is lowered, and the oxidation rate of the modified lignite is lowered. As a result, the temperature in the processing container 1 decreases. Here, the oxygen concentration in the gas of the aging gas is also lowered by opening the return gas amount adjusting valve 5 and circulating the aging gas. By adjusting the oxygen concentration according to the circulation amount of the aging gas, the amount of nitrogen gas used for adjusting the oxygen concentration can be reduced. At this time, the supply of outside air may be completely stopped by closing the outside air supply valve 6.

When the temperature in the processing container 1 decreases to _TL , the control unit 4 closes the nitrogen supply valve 7 and the return gas amount adjustment valve 5 and supplies the outside air again to the processing container 1 (or the ratio of the outside air is changed). increase). Thereby, the oxygen concentration in the gas of the aging gas is increased, and the temperature in the processing container 1 is increased. However, the temperature in the processing chamber 1 begins to fall before rises to T _U. This is because the oxidation activity of the modified lignite is decreasing.

  When the oxidation rate of the modified lignite in the processing container 1 is measured and the oxidation rate reaches a predetermined value, the modified lignite is taken out from the processing container 1. The oxidation rate of the modified lignite is measured by sampling a small amount from the processing vessel 1 and measuring the amount of oxygen consumed over a fixed time in the sealed vessel.

  During the above-described oxygen concentration control of the aging gas, the flow rate, temperature, and humidity of the aging gas are based on the temperature in the processing vessel 1 and the behavior of the modified lignite (oxidation rate, moisture content). Be controlled. The moisture content of the modified lignite is measured by industrial analysis JIS M 8812.5.

  For example, as shown in FIG. 2, the control unit 4 supplies the aging gas to the processing container 1 so that the flow rate, temperature, and humidity of the aging gas supplied to the processing container 1 are constant during the aging process. Control the flow rate, temperature, and humidity of the aging gas. The control target value of the humidity of the aging gas is set, for example, from the adsorption isotherm of the modified lignite.

  Here, it is preferable to control the humidity of the aging gas supplied to the processing vessel 1 so that the moisture of the modified lignite in the processing vessel 1 reaches the equilibrium moisture after the aging treatment. In addition, it is said that water | moisture content equilibrates that the water | moisture content of modified | denatured brown coal will not change any more, and the water | moisture value at this time is called equilibrium water | moisture content. The value of equilibrium moisture varies depending on the humidity of the modified lignite (modified low-grade coal).

(effect)
According to the aging device 100 of the present embodiment, moisture can be supplied to the modified low-grade coal during the aging process to adjust the humidity of the modified low-grade coal. As a result, it is possible to prevent the modified low-grade coal from adsorbing moisture and generating heat after the aging process. As a result, the modified low-grade coal after the aging process can be safely piled.

  In addition, by adjusting the humidity of the aging gas so that the moisture of the modified low-grade coal in the processing container 1 reaches equilibrium moisture, the modified low-grade coal adsorbs moisture after the aging process and generates heat. It is possible to prevent further, and after the aging treatment, the modified low-grade coal can be piled up more safely (in a form that can prevent spontaneous ignition more).

(Second Embodiment)
Next, an aging device 101 according to a second embodiment of the present invention will be described with reference to FIG. In addition, the same code | symbol is attached | subjected about the apparatus and instrument which comprise the aging apparatus 100 of 1st Embodiment shown in FIG. 1, and an instrument similar to an instrument.

  The difference between the aging apparatus 101 of the present embodiment and the aging apparatus 100 of the first embodiment is that the aging apparatus 101 of the present embodiment is different in the values of carbon monoxide concentration and carbon dioxide concentration in the gas discharged from the processing container 1. And the oxygen concentration of the aging gas is controlled not only based on the temperature in the processing container 1 but also based on these values.

  As a specific configuration, a carbon monoxide concentration meter 15 and a carbon dioxide concentration meter 16 are attached to a gas return path 32 between the processing vessel 1 and the return gas amount adjusting valve 5, and signals from these meters are controlled by a control unit. 4 Then, when the ratio of the carbon dioxide concentration to the carbon monoxide concentration in the gas exiting the processing container 1 is increased based on the detection values of the carbon monoxide concentration meter 15 and the carbon dioxide concentration meter 16, the control unit 4 Further, at least one of a plurality of oxygen concentration adjusting means (return gas amount adjusting valve 5, outside air supply valve 6, and nitrogen supply valve 7) is controlled to control to reduce the oxygen concentration in the gas. Has been.

Here, when a hot spot (local temperature rise location) does not occur in the modified lignite layer filled in the processing vessel 1, the concentration of carbon monoxide (volume ratio) in the gas exiting the processing vessel 1 The ratio of the carbon dioxide concentration (volume ratio) with respect to is constant at about 10 (CO ₂ / CO = 10). However, when a hot spot is generated in the modified lignite layer, the ratio of the carbon dioxide concentration (volume ratio) to the carbon monoxide concentration (volume ratio) in the gas exiting the processing vessel 1 increases, and 20 (CO ₂ / CO = 20). Therefore, in this embodiment, for example, when the ratio of the carbon dioxide concentration (volume ratio) to the carbon monoxide concentration (volume ratio) in the gas reaches 20 (CO ₂ / CO = 20), the oxygen concentration in the gas is reduced. To control.

In addition, when no hot spot is generated in the modified lignite layer, it is constant at about CO ₂ / CO = 10, and when a hot spot is generated in the modified lignite layer, it is about CO ₂ / CO = 20. Is the case of modified lignite, and this value will change if the coal type is different.

  On the other hand, in the temperature measurement in the processing container 1 by the in-container thermometer 10, the temperature measurement location is limited, so it is difficult to grasp the local temperature rise location (hot spot) in the processing vessel 1.

  However, according to the aging apparatus 101 of this embodiment, the hot spot which arises in the processing container 1 (filled modified brown coal layer) can be grasped | ascertained easily. Aging can be performed while suppressing the occurrence of hot spots. That is, aging can be performed more safely (while preventing spontaneous ignition in the processing container 1).

  Although the embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and various modifications can be made as long as they are described in the claims. .

1: Processing container 2: Blower (gas supply means)
3: Heat exchanger 4: Control unit 5: Return gas amount adjustment valve 6: Outside air supply valve 7: Nitrogen supply valve 8: Steam supply valve 9: Cooling water amount adjustment valve 10: Thermometer in vessel 11: Oxygen concentration meter 12: Hygrometer 13: Thermometer 14: Flow meter 100: Aging device

Claims (6)

An aging device for reducing the spontaneous heat generation of the modified low-grade coal,
A processing vessel filled with modified low-grade coal;
Gas supply means for supplying a gas containing oxygen to the processing vessel;
Oxygen concentration adjusting means for adjusting the oxygen concentration in the gas;
Humidity adjusting means for adjusting the humidity of the gas;
A thermometer in the container for detecting the temperature in the processing container;
Based on the detected value of the thermometer in the container, the oxygen concentration adjusting means is controlled to adjust the oxygen concentration in the gas, and the modified low-grade coal in the processing container is prevented from drying due to a temperature rise due to oxidation. Control means for controlling the humidity adjusting means to adjust the humidity of the gas;
Equipped with a,
The control means further controls the oxygen concentration adjusting means to lower the oxygen concentration in the gas when the ratio of the carbon dioxide concentration to the carbon monoxide concentration in the gas exiting the processing container increases. An aging device, characterized in that The aging device according to claim 1,
The aging apparatus characterized in that the control means controls the humidity adjusting means so that the moisture of the modified low-grade coal in the processing vessel reaches equilibrium moisture. A method of operating an aging apparatus for reducing the spontaneous heat generation of the modified low-grade coal, comprising: a processing vessel filled with the modified low-grade coal; and a gas supply means for supplying a gas containing oxygen to the processing vessel. Because
Adjusting the oxygen concentration in the gas based on the measured temperature value in the processing vessel, and adjusting the humidity of the gas so that the modified low-grade coal in the processing vessel does not dry due to temperature rise due to oxidation ,
When the ratio of the carbon dioxide concentration to the carbon monoxide concentration in the gas exiting the processing container is increased, the oxygen concentration in the gas supplied to the processing container is decreased . how to drive. In the operating method of the aging apparatus of Claim 3 ,
A method for operating an aging apparatus, wherein the humidity of the gas is adjusted so that the moisture of the modified low-grade coal in the processing vessel reaches equilibrium moisture. An aging device for reducing the spontaneous heat generation of the modified low-grade coal,
A processing vessel filled with modified low-grade coal;
Gas supply means for supplying a gas containing oxygen to the processing vessel;
Oxygen concentration adjusting means for adjusting the oxygen concentration in the gas;
Control means for controlling the oxygen concentration adjusting means to lower the oxygen concentration in the gas when the ratio of the carbon dioxide concentration to the carbon monoxide concentration in the gas exiting the processing container increases;
An aging device comprising: A method of operating an aging apparatus for reducing the spontaneous heat generation of the modified low-grade coal, comprising: a processing vessel filled with the modified low-grade coal; and a gas supply means for supplying a gas containing oxygen to the processing vessel. Because
When the ratio of the carbon dioxide concentration to the carbon monoxide concentration in the gas exiting the processing container is increased, the oxygen concentration in the gas supplied to the processing container is decreased. how to drive.