JP2020041780A - Powder dryer, and method of drying powder - Google Patents

Abstract

To utilize an economically low cost medium and to substantially control a risk of a fire in a powder dryer.SOLUTION: There are provided a powder dryer which is downsized, made to have improved performance and improved heat efficiency, and made substantially free of risks of a fire and an explosion, by heating steam evaporated from powder and discharged therefrom to produce superheated steam which is returned to the dryer as superheated steam to increase the steam concentration in the dryer, whereby keeping the oxygen concentration in the dryer below the explosion limit oxygen concentration with respect to powder, and a method of operating the same.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a flash dryer, a ring dryer, a spray dryer, and the like, which are one type of a powder drying apparatus, and more particularly to a device configuration and an operation method for preventing a fire accident which has been reported in many of these drying apparatuses.

  These drying devices are devices for throwing a wet powder into a rapidly flowing high-temperature medium, colliding the wet powder with the high-temperature medium, and performing rapid drying while transporting the device in a floating state. As the powder, for example, flour, powder, toner, fertilizer, titanium oxide, activated carbon, cement, alumina, powdered metal and the like are used, and are applied in various industrial fields. In addition, there is also an example in which a substance having a larger particle size than a powder such as ore, or a substance which is slightly different in shape from the powder but which is a flocculent substance such as wood pulp is used. Further, there is a case where a substance dissolved in a liquid as a finer emulsion than a powder such as milk or a substance completely dissolved in a liquid such as salt water is dried and taken out as a powder. These particles, flocculants, emulsions or solutions are collectively referred to as “powder” below, but the object of the present invention is not limited to the substances exemplified here.

  In these powder dryers, especially when drying powders that are easily oxidized, fires and explosions have been reported to occur if the temperature is raised too high. An example of installing a fire extinguisher / fire extinguisher is seen. Alternatively, it has been practiced to lower the drying efficiency and the processing capacity so as to fall below a combustion limit temperature which is a temperature causing spontaneous ignition, and to set an upper limit on the operating temperature to ensure safety.

  Patent Document 1 (Japanese Patent Application Laid-Open No. 9-48612) deals with drying of a substance produced as a by-product of alcohols during drying. However, paragraphs 0015 and 0016 describe "operating safely to prevent explosion and fire." For this purpose, the oxygen concentration in the gas used for drying should be kept at 10% or less, preferably 5% or less. ”In order to satisfy such a condition, the medium gas should be“ nitrogen, carbon dioxide, argon ”. It is good to use a heating medium gas that does not react with an organic solvent such as the above. " Although this example is a case of a special condition that by-product alcohol is generated during drying, it can be applied to drying of a normal flammable substance that does not generate flammable by-products.

JP-A-9-48612

  The method according to Patent Document 1 is an effective method for truly safely drying a substance having a combustible oxygen concentration of more than 10% to 5%. Good, but from a cost standpoint, it is also possible to adopt a closed method in which water and organic solvents evaporated from the medium gas used for drying are collected by cooling or the like, and the medium gas is recycled. ' The cost of the medium gas is a problem, and even if the medium gas is recycled in a closed system, equipment for cooling and recovering the evaporated water is indispensable. Equipment costs and operating costs became issues, and it was hard to say that the equipment was suitable for widespread industrialization.

  As described above, Patent Document 1 is a truly safe method that does not generate fire or explosion in principle, and should be widely applied. However, it is not limited to the drying of expensive materials that are not restricted by cost. It was difficult from an economic perspective.

  Therefore, an object of the present invention is to provide a powder drying apparatus and an operation method thereof that can essentially suppress the risk of fire by using a low-cost medium economically.

  The inventor proposes to use superheated steam as a medium gas as a means for solving this cost problem. Water behaves as a gas when it exceeds 100 ° C., and has no flammability like nitrogen. In Patent Literature 1, it is natural to send a dehumidified medium to the drying cylinder, so that not only alcohols but also water is selected from the medium, and the superheated steam is a dry gas and is used for drying. It is presumed that he did not come up with the truth that it could be a medium.

  However, if superheated steam exceeding 100 ° C. is generated from water, a heat source corresponding to latent heat of evaporation is required in addition to sensible heat, and it is clear that the cost is a new problem. Therefore, in the first place, the basic function of the drying device is to evaporate water and exhaust it. Especially when the exhaust temperature exceeds 100 ° C, the moisture in the exhaust is superheated steam. Thus, it has been found that if the superheated steam is used as a medium supply source and recycled as necessary, the problem of the cost of generating latent heat of vaporization can be solved, and the present invention has been completed.

  A first aspect of the present invention relates to a powder drying apparatus that employs a method of drying a powder by colliding a high-temperature medium with a wet powder. In the drying device according to the present invention, the temperature of a part of the steam evaporated and exhausted from the powder is raised to be superheated steam, and the superheated steam is returned to the drying device as a high-temperature medium. By increasing the concentration, the oxygen concentration in the drying device is kept lower than the combustion limit oxygen concentration of the powder. In the present invention, the internal pressure of the high-temperature medium is preferably kept within ± 10% of the pressure around the apparatus.

  Specifically, the drying device according to the present invention includes a drying pipe (column) for drying the powder by bringing the wet powder into contact with a heating medium (for example, superheated steam), and a heating medium supplied to the drying pipe. A heating device for heating the heating medium, a separation device (cyclone) for separating the heating medium from the drying tube and the powder, and a circulation line for supplying the heating medium to the heating device after passing the separation device. Preferably, at least the oxygen concentration in the powder transport line from the drying tube to the separation device is 16% or less, and the temperature of the heating medium is controlled to be higher than 100 ° C.

  In particular, it is preferable that air (make-up air or the like) outside the apparatus does not flow into the circulation line. Specifically, it is preferable that there is no mechanism for flowing external air into the circulation line. The inventor has noticed that superheated steam (heating medium) exceeding 100 ° C. at normal pressure is a physically perfect gas, and has found that the use of this fact can greatly reduce drying heat energy. That is, the superheated steam has almost the same physical properties as an ideal gas, as well as known gases in the atmosphere such as nitrogen, oxygen, argon, and carbon dioxide. Thus, the superheated steam and the other gas can be mixed with each other in any ratio between 0 and 100%. In other words, as long as the temperature exceeds 100 ° C. at normal pressure, there is no need to be bound by the concept of humidity, which means that air is carried by air. You can. Therefore, if the superheated steam is used as a heating medium for drying the powder, it is not necessary to supply makeup air into the circulation path. It can be said that it is possible to prevent a decrease in the temperature, and to improve the thermal efficiency and eventually reduce the drying energy. For this reason, it is preferable not to supply an atmosphere called makeup air other than air necessary for combustion in the heating device in the circulation path.

  A second aspect of the present invention relates to a powder drying method that employs a method of drying a powder by causing a high-temperature medium to collide with a wet powder. In the drying method according to the present invention, a part of the water vapor evaporated and exhausted from the powder in the drying device is heated to form superheated steam, and the superheated steam is returned to the drying device as a high-temperature medium. Control the oxygen concentration in the dryer below the combustion limit oxygen concentration of the powder.

  Specifically, the drying method according to the present invention includes a step of heating a medium supplied to a drying tube by a heating device, and a method of heating a wet powder in the drying tube (column) by heating the wet powder (for example, superheated steam). Drying the powder by bringing the heating medium into contact with the heating device, separating the heating medium and the powder that have passed through the drying tube by a separation device (cyclone), and supplying the heating medium that has passed through the separation device to the heating device. Supplying. It is preferable that at least the oxygen concentration in the powder transport line from the drying tube to the separation device be 16% or less, and the temperature of the heating medium be controlled to be higher than 100 ° C. In particular, it is preferable to prevent air outside the apparatus from flowing into the circulation line.

  ADVANTAGE OF THE INVENTION According to this invention, the drying apparatus of the powder which can suppress the danger of a fire essentially using a low-cost medium economically, and its operating method can be provided.

FIG. 1 shows a conventional example in which the spray dryer described in Patent Document 1 is applied to a single-column flash dryer. FIG. 2 shows a first embodiment of the present invention, in which the present invention is applied to a single-column flash dryer. FIG. 3 shows a second embodiment of the present invention, in which the present invention is applied to a double-column flash dryer. FIG. 4 shows a third embodiment of the present invention, in which the present invention is applied to a single-column flash dryer provided with a direct-heat-type direct heat exchange type heating device.

  Although Patent Document 1 has a spray dryer in mind, the principle of drying is the same for a flash dryer. FIG. 1 shows an example in which the device configuration disclosed in Patent Document 1 is applied to a single-column flash dryer having one drying tube (column).

As shown in FIG. 1, the medium dehumidified by the cooling tower is heated by the heating device and encounters the wet powder at the lower part of the column. The wet powder is dried by receiving heat from the medium in the column, and then sent to a cyclone to be separated from the medium and taken out as a dry powder. At that time, some of the medium goes outside, so that N ₂ (nitrogen) gas is supplied to the cyclone. In the drying process, the powder decomposes to produce alcohols as a by-product. The medium containing water and alcohol separated from the dry powder in the cyclone is sent to the cooling tower by the circulation fan. In the cooling tower, water and alcohols in the medium are condensed by the cooling water, separated from the medium as drain water, and the medium is regenerated.

Although powder Patent Document 1 had decomposing and generating an inflammable alcohol, medium is mainly water vapor evaporated with N ₂ gas, there is no combustion-supporting in the medium. Although there is a possibility that some oxygen has entered from the feeder section, the combustion of alcohols is monitored by monitoring with an oximeter installed in the route and monitoring that it is 10% to 5% or less. It is below the limit oxygen concentration and guarantees no possibility of combustion or explosion.

  A first embodiment of the present invention is shown in FIG. 2 and will be described using a single-column flash dryer. As shown in FIG. 2, the first embodiment of the present invention includes a feeder, a column, a heating device, a cyclone, an exhaust fan, a circulation line, a blower fan, and an oximeter. The feeder supplies a wet powder to be dried to the column. The column dries the powder by contacting the wet powder with a heating medium. The heating device generates a heating medium (superheated steam) by heating the medium, and supplies the heating medium to the column. The cyclone separates the powder from the heating medium that has passed through the column. Further, in the cyclone, the powder may be separated into a dried powder that has been completely dried and a wet powder that is insufficiently dried, and the wet powder may be returned to the feeder. The dried powder is collected as a product. The exhaust fan exhausts a part of the heating medium separated in the cyclone. In the exhaust fan, the exhaust amount of the heating medium can be adjusted. The exhaust fan may be stopped to reduce the amount of exhaust of the heating medium to zero, or the exhaust fan itself may not be provided. The circulation line supplies the heating device with all or a part of the heating medium separated in the cyclone. The blower fan is disposed in the circulation line and adjusts the amount of the heating medium supplied to the heating device. The entire amount of the heating medium separated in the cyclone can also be supplied to the heating device via a circulation line. The oximeter can be provided, for example, at one or both of the inlet side and the outlet side of the column, and measures the oxygen concentration in the medium supplied to the column or the oxygen concentration in the medium discharged from the column. In accordance with the measured oxygen concentration, the amount of exhaust air by the exhaust fan or the amount of air blown by the blower fan can be adjusted.

  In the present invention, the steam discharged from the cyclone is not cooled and separated, but is actively used as a heating medium. Therefore, compared with Patent Document 1, a cooling tower and cooling water are not required. It can be understood that equipment and operation costs are reduced. Even when a combustible gas such as alcohol is generated as in Patent Literature 1, there is no danger of fire or explosion because there is no combustible gas in the system. The installation position of the oxygen concentration meter is not limited to the embodiment, and it is preferable to select a place where air can easily enter when the equipment is damaged.

  When the drying process according to the present invention progresses beyond a certain level, all the air in the drying device at the initial stage is replaced with superheated steam as a heating medium. Thereafter, the entire discharged medium becomes superheated steam, and the amount is equal to the amount of water evaporated from the wet powder. This is because, if the amount of exhaust gas is larger than the amount of water evaporated from the wet powder, the negative pressure in the apparatus is increased and the amount of exhaust is reduced, and the balance becomes the same as the amount of water evaporated from the wet powder. When the amount decreases, the opposite effect occurs, and the balance becomes equal again.

  In this way, the operating pressure of the device forms a stable system, so the device can be operated even if it is left naturally, but more positively has an internal pressure detection mechanism and pressure adjusting means to keep the pressure inside the device constant It is also possible. For example, if the internal pressure of the equipment is kept higher than the surroundings of the equipment, even if the equipment is cracked or ruptured, the outside air will not immediately enter from that part, and a configuration that is resistant to fire and explosion can be achieved. it can. The exhaust fan shown in FIG. 1 can function as pressure adjusting means. Further, as the pressure detecting mechanism, a pressure gauge may be provided at an arbitrary position in the pipe through which the medium circulates.

  Conversely, when the internal pressure is set to a negative pressure, it is possible to prevent the medium from leaking from a small gap in the device or a poorly sealed part of the feeder, and if the wet powder contains an odor, Control of the outflow to the outside becomes easy.

  However, in the range where the inventor operated the drying apparatus, the pressure should be kept within ± 10% of the surrounding pressure, and a pressure difference exceeding that would cause damage due to expansion and contraction of the apparatus. preferable.

  FIG. 3 shows a second embodiment of the present invention, in which the present invention is applied to a double-column flash dryer. In the second embodiment, as in the first embodiment described above, the outlet of the exhaust fan and the inlet of the blower fan are connected, most of the medium is circulated, and no air is taken in.

  As shown in FIG. 3, the second embodiment of the present invention includes a feeder, a first column, a first cyclone, a second column, a second cyclone, a boost fan, a heating device, an exhaust fan, a circulation line, and a blower fan. , And an oximeter. The feeder supplies wet powder to be dried to the first column. The first column dries the powder by bringing the wet powder into contact with a heating medium. The heating medium is supplied to the first column by a boost fan. The first cyclone separates the powder from the heating medium that has passed through the first column. The powder separated in the first cyclone is supplied to a second column. The second column further dries the powder separated by the first cyclone by bringing the powder into contact with a heating medium. In the second cyclone, the powder is separated into a dried powder that has been completely dried and a wet powder that is insufficiently dried, and the wet powder is returned to the first column together with the heating medium via a boost fan. It is. The dried powder is collected as a product. The heating device generates a heating medium (superheated steam) by heating the medium, and supplies the heating medium to the second column. The exhaust fan exhausts a part of the heating medium separated in the first cyclone. In the exhaust fan, the exhaust amount of the heating medium can be adjusted. The exhaust fan may be stopped to reduce the amount of exhaust of the heating medium to zero, or the exhaust fan itself may not be provided. The circulation line supplies all or a part of the heating medium separated in the first cyclone to the heating device. The blower fan is disposed in the circulation line and adjusts the amount of the heating medium supplied to the heating device. The entire amount of the heating medium separated in the first cyclone can also be supplied to the heating device via a circulation line. The oximeter can be provided, for example, on both or one of the inlet side and the outlet side of the first column, and the oxygen concentration in the medium supplied to the first column or the oxygen concentration in the medium discharged from the first column. Is measured. In accordance with the measured oxygen concentration, the amount of exhaust air by the exhaust fan or the amount of air blown by the blower fan can be adjusted.

  Although two column devices are arranged so that the powder and the medium are countercurrent dried, the functions and features are the same as those of the first embodiment. In addition, the blowers are appropriately divided and arranged because the equipment becomes large and the blowing resistance increases.

  FIG. 4 shows a third embodiment in which a direct heat exchange type of direct fire system is used as a heating device. The third embodiment employs, as a heating device, a direct-fire system in which combustion air is heated by using thermal energy obtained by burning fuel to generate hot air. This is the same as the first embodiment shown in FIG.

In the direct fire method, gaseous fossil fuels such as city gas, propane gas, and methane gas, and liquid fossil fuels such as kerosene and heavy oil are often used. Since air is mainly used to burn them, oxygen (residual O ₂ ) and gases such as nitrogen and carbon dioxide that have not been used for combustion are present in the medium. If the combustion air is excessively supplied, the residual O ₂ increases, and as a result, the medium may have an oxygen concentration equal to or higher than the combustion limit oxygen concentration of the powder. is there. In addition, an excessive amount of air means a heat loss due to the exhaust taking out heat. In this sense, it is necessary to limit the flow rate of the combustion air with respect to the fuel flow rate.

For example, when methane gas is used as fuel, the stoichiometric air-fuel ratio is 1 for methane gas and 10 for air as a ratio of volume flow rate. However, considering that no unburned gas remains, it is said that the air-fuel ratio that maximizes the thermal efficiency is about 1:12. For other fuels, guidelines for an ideal air-fuel ratio are generally known. It is also known that when the fuel is burned in accordance with the air-fuel ratio, the residual O ₂ concentration in the combustion gas becomes about 4 to 6%. Therefore, the oxygen concentration in the medium in which the combustion gas and the superheated steam are mixed is less than 4 to 6%.

  Regarding the flammable powder's flammable oxygen concentration limit, when the gas coexisting with oxygen is nitrogen, there are data of 11% for flour and 10% for sawdust. In a conventional air-based flash dryer, a medium having an oxygen concentration of 21% and a combustion gas having an oxygen concentration of 4 to 6% are mixed. As a result, the oxygen concentration in the medium may become a combustion limit oxygen concentration depending on the mixing ratio. there were. This is why many fires occurred. However, in the present invention, the medium is a mixture of the combustion gas and the superheated steam, and the oxygen concentration does not exceed the oxygen concentration of the combustion gas of 4 to 6%. In that sense, it is a drying method that is essentially free of fire risk when drying many combustible powders such as flour and sawdust.

  However, in order to accurately control the air-fuel ratio, it is necessary to correctly measure and control the air flow rate, and when using gaseous fossil fuel, it is also necessary to measure and control the flow rate. However, the gas flow rate measuring instrument is a measuring instrument in which an error easily occurs, and depending on the degree of the error, the air flow rate may increase unintentionally and the oxygen concentration of the medium may increase. In order to prevent the occurrence of fire accidents due to this, it is recommended to monitor by installing an oximeter.

  As described above, when a medium mainly composed of superheated steam is used, the oxygen concentration in the medium can be maintained at a level lower than the combustion limit oxygen concentration, thereby providing a facility free from fire. This is a truly useful invention in terms of safety and disaster prevention. However, this greatly diminishes the drying capacity or significantly increases the fuel consumption to obtain the same drying level, which detracts from industrial value. Therefore, it will be described below that the present invention is superior in thermal efficiency and improves the drying rate as compared with the conventional technology, and is advantageous in both operating cost and equipment cost, and is an industrially useful method.

  In a flash dryer, heat is transferred from a medium to a wet powder in a fixed volume, and the powder is dried by evaporating moisture contained in the powder. Therefore, a medium containing more heat in a given volume and having a higher speed at which the heat of the medium is transferred to the powder is a more advantageous medium for drying. Thus, as an example, physical properties of superheated steam and air at 200 ° C. are compared.

(1) Comparison of thermal efficiency The amount of heat required to evaporate 1 kg of water does not depend on the drying method. The thermal efficiency is determined by how much heat is lost outside the system during the drying process. In the method of the present invention, the only substance that goes out of the system is evaporated water. On the other hand, in the prior art, the temperature of the air, which is a medium, together with the evaporated water is raised and exhausted at the same time. In this sense, the present invention is excellent in terms of thermal efficiency because there is no air going out of the system although there is an effect of the difference in temperature at the time of discharge.

(2) Comparison of retained heat The drying by the flash dryer is mainly performed in a drying tube having a fixed volume. As shown in Table 1, the specific heat per unit volume of the superheated steam is larger, and a larger amount of heat can be held in the same volume. That is, even a facility having a smaller capacity can operate while retaining the same amount of heat, so that the facility can be downsized or more powder can be dried with the same facility.

(3) Comparison of heat transfer speed Superheated steam can transfer condensation heat to water at 100 ° C. or lower, and it is known that the speed is two to three orders of magnitude faster than contact heat transfer. That is, the speed at which heat is transmitted is overwhelmingly high. Therefore, the same amount of heat can be transmitted with a smaller contact area, so that the equipment can be made smaller or more powder can be dried with the same equipment.

  From the above, it can be said that superheated steam has more suitable physical properties than air as a heat transfer medium.

  Superheated steam exceeding 100 ° C is a gas that can be simulated as an ideal gas like air, and does not become a liquid, that is, it does not wet the powder, but rather can dry the powder . And its ability is better than air.

  As described above, the embodiments of the present invention have been described with reference to the drawings in order to express the contents of the present invention. However, the present invention is not limited to the above-described embodiment, and includes modifications and improvements obvious to those skilled in the art based on the matters described in the present specification.

Claims (3)

  A powder drying apparatus that employs a method of drying a powder by colliding a high-temperature medium with a wet powder, and elevating the temperature of a part of water vapor evaporated and exhausted from the powder to form superheated steam. A powder drying apparatus that raises the steam concentration in the drying apparatus by returning the superheated steam as a high-temperature medium to the drying apparatus, thereby keeping the oxygen concentration in the drying apparatus lower than the combustion limit oxygen concentration of the powder. .   The powder drying apparatus according to claim 1, wherein the internal pressure of the medium is maintained within a pressure around the apparatus ± 10%.   This is a method of drying a powder that employs a method in which a high-temperature medium and a wet powder collide with each other to dry the powder. A powder that forms steam and returns the superheated steam to the drying device as a high-temperature medium, thereby increasing the steam concentration in the drying device and thereby controlling the oxygen concentration in the drying device to be lower than the combustion limit oxygen concentration of the powder. How to dry the body.

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