KR20040032368A - The re-carbonizing system using calcific exhaust gas - Google Patents

Abstract

PURPOSE: A lime burning recarbonation system is provided which is capable of suppressing hydration and reducing degradation ratio during storage and transportation by recarbonizing the surface of produced quicklime using flue gas. CONSTITUTION: The recarbonation system using lime burning flue gas comprises a shaft kiln stack(10); a dust collector(20) connected to the shaft kiln stack to filter the dust and mist by flowing flue gas generated from the shaft kiln stack in the dust collector, thereby collecting the dust and mist; a heat exchanger(40) connected to the dust collector to cool the flue gas filtered in the dust collector; a cooling water line for supplying and circulating cooling water into the heat exchanger; an exhaust line(80) connected to the heat exchanger to transfer the flue gas cooled in the heat exchanger; a discharge line(94) communicated with the exhaust line to discharge the flue gas discharged from the exhaust line; and a cooler(100) connected to the discharge line to receive quicklime burnt in rotary kiln and coat the burning lime with the flue gas by injecting the flue gas supplied from the discharge line onto the burning lime.

Description

Re-CARBONIZING SYSTEM USING CALCIFIC EXHAUST GAS}

The present invention relates to a calcined recarbonation system, and more particularly, to a calcined recarbonation system capable of recarbonizing the surface of quicklime produced with flue gas to suppress hydration reactions and to reduce the differentiation rate during storage and transportation. will be.

Generally, although not limited, quicklime is mainly used as a preparation for refining such as desulfurization in a steelmaking process of an ironworks. In particular, high-quality quicklime is required for the production of high clean steel.

On the other hand, such quicklime is largely manufactured by a calcining recarbonation system in a lime firing plant having an exhaust gas line and a cooling water line, and is generally used in a kiln furnace using combustion heat of COG (Coke Oven Gas). It is manufactured by baking limestone at the high temperature of 1100 degreeC or more. The calcined quicklime is also used in the steelmaking process after being cooled to about 70 ° C. or less in a cooler and stored in a product hopper after a predetermined time.

However, such a general calcined recarbonation system has been shown to cause some problems. First, there is a problem in that the surface of the quicklime produced to produce a hydration panel to increase the differentiation rate during storage or transportation, thereby degrading the productability.

In addition, the cooling efficiency in the cooling line is reduced, condensation of the exhaust gas is delayed, as well as the temperature is delayed, there is a problem that productivity and productability is lowered.

Accordingly, the present invention has been invented to solve the above-mentioned problems, an object of the present invention is to provide a lime-calcinated recarbonation system that prevents the hydration reaction of the surface of quicklime and reduces the differentiation rate during storage or transportation to improve the productability It is.

Another object of the present invention is to provide a calcining recarbonation system in which cooling efficiency is improved and condensation of exhaust gas and a decrease in temperature are continuously and rapidly performed.

It is still another object of the present invention to provide a calcined recarbonation system capable of recycling flue gas discharged to the atmosphere and reducing flue gas emission.

Still another object of the present invention is to provide a calcining recarbonation method in which productability is improved and productivity is improved.

1 is a schematic view showing a calcined recarbonation system and a recarbonation method thereof according to the present invention.

♣ Explanation of symbols for the main parts of the drawing ♣

10: shaft kiln stack 20: dust collector

30: sump tank 50: cooling water tank

60: freezer 70: cooling tower

80: exhaust line 90: delivery line

100: cooler

Such objects include: shaft kiln stack; A dust collector connected to the shaft kiln stack and configured to collect and filter dust and mist by introducing exhaust gas generated from the shaft kiln stack; A heat exchanger connected to the dust collector for cooling the exhaust gas filtered by the dust collector; A cooling water line for supplying and circulating cooling water to the heat exchanger; An exhaust line connected to the heat exchanger and configured to transfer exhaust gas cooled by the heat exchanger; A delivery line communicating with the exhaust line and for sending exhaust gas discharged from the exhaust line; And a cooler connected to the delivery line, supplied with calcined quicklime in the rotary kiln, and including a cooler for spraying and coating the calcined lime exhaust gas supplied from the delivery line to the calcined lime.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Referring to Figure 1, the calcined recarbonation system according to the present invention is basically classified into an exhaust gas line and a cooling water line, the exhaust gas line as a vertical granular kiln to produce a desired product by applying heat to the charged raw materials It is provided with a shaft kiln stack 10 which transforms limestone into calcareous material by heating the limestone in the back and uses COG as a heat source. The shaft kiln stack 10 includes a scrubber 12 for removing impurities such as dust and the like from the COG flowing into the shaft kilon, and COG filtered firstly from the scrubber by second filtering to obtain a shaft kiln stack 10. Filters 14 for feeding in are continuously connected.

The dust collector 20 is connected to the shaft kiln stack 10 by the duct 18 provided with the exhaust gas fan 16. The dust collector 20 is comprised from the outer cylinder 22 and the inner cylinder 24. As shown in FIG. As described later, the inner cylinder 24 is preferably provided with a filter 24a for collecting dust such as dust and mist such as moisture. In addition, the dust collector 20 is connected to a supply line 26 for supplying water during its operation, the supply line 26 is provided with a control valve 28 for regulating the supply of water. According to the configuration of the dust collector, the exhaust gas discharged through the duct 18 is rotated by the exhaust gas fan 16 is introduced into the outer cylinder 22 of the dust collector and mixed with the sprayed water flowing through the water supply line 26 at the same time. While being discharged from the outer cylinder 22 to the inner cylinder 24. In the process of discharging as described above, the exhaust gas is suddenly crushed to produce saturated steam, and the dust and moisture contained in the gas are collected by the filter 24a built into the inner cylinder 24.

In particular, in the embodiment shown in the figure is shown that only one dust collector is provided, the number of installation is that two or more may be installed depending on the capacity of the entire system or the throughput of the exhaust gas.

At the bottom of the dust collector 20, a water collecting tank 30 for collecting dust and mist collected by the dust collector is spoken. Discharge motor 32 is connected to the sump 30 to transfer dust and mist to the sludge channel for post-processing or disposal.

In addition, the heat exchanger 40 is connected to the dust collector 20 by a duct 36 having a blower 34 to cool the exhaust gas filtered by the dust collector. Moreover, the thermometer 36a for detecting the temperature of the flue gas blown by the eye in the duct 36 after the blower 34 is provided. The blower 34 is connected to a water spray line 34 for injecting water into the exhaust gas sent by the blower. In particular, the heat exchanger 40 is preferably provided in the center of the heat exchange plate 42 is supplied from the cooling line to be described later to exhaust the exhaust gas cooling water for cooling the exhaust gas cooling water.

As described above, the cooling water line 50 connected to the heat exchanger 40 to supply the exhaust gas cooling water is provided with a cooling water tank 50 connected to the heat exchanger 40 by the return line 44. Optionally, the return line 44 may be provided with a thermometer 44a and a flow switch 44b for detecting the temperature of the exhaust gas cooling water returned. A supply line 52 is provided between the heat exchanger 40 and the cooling water tank 50 to supply the cooling water from the cooling water tank 50 to the heat exchanger 40. More specifically, the supply line 52 is connected to the heat exchange plate 42 of the heat exchanger 40. In addition, the supply line 52 is provided with a first circulation pump 54 for delivering the cooling water of the cooling water tank 50 to the heat exchanger (40). Optionally, the supply line 52 is preferably provided with a flow meter 56 for detecting the amount of exhaust gas cooling water supplied to the heat exchanger 40, and a control valve 58 for adjusting the supply amount. Of course, the control valve 58 is also addressed to the return line 44 is preferably installed so that the discharge from the heat exchanger 40 can be adjusted at the same time. Of course, the cooling water tank 50 is preferably provided with a water supply line 50a for receiving water from the outside, and a water level indicator 50b for detecting the amount of water in the cooling water tank 50.

The refrigerator 60 for supplying the cooling water optimally cooled to the cooling water tank to the cooling water tank 50 is connected by the supply pipe 62. In addition, between the cooling water tank 50 and the freezer 60, a return pipe 64 for returning the relatively high temperature exhaust gas cooling water returned from the heat exchanger 40 to the freezer 60 is provided. It is preferred that 64 is provided with a second circulation pump 66 for delivering cooling water to the freezer. Optionally, the supply pipe 62 may be provided with a thermometer 62a, a flow switch 62b, or the like for detecting the temperature of the exhaust gas cooling water supplied.

The refrigerator 60 is connected by a conveying pipe 72 to a cooling tower 70 for generating cooling water for cooling the chiller 60a in the refrigerator. The transfer pipe 72 is preferably provided with a third circulation pump 74 to facilitate the transfer of the cooling water. On the other hand, the refrigerator 60 is connected to the cooling tower 70 by the return pipe 76, which is to return the cooling water after cooling the chiller chiller to the cooling tower 70. The return tube 76 is preferably provided with a thermometer 76a and a pro switch 76b. Loose course, the cooling tower 70 is connected to the raw water supply line 78 for supplying the necessary or insufficient raw water to the cooling tower.

On the other hand, the heat exchanger 40 is connected to the exhaust line 80 for discharging the exhaust gas cooled in the heat exchanger. The exhaust line 80 includes a CO ₂ analyzer 82 for detecting the concentration of CO ₂ in the exhaust gas discharged through the exhaust line, a pressure gauge 84 for detecting the pressure of the exhaust gas, and a flow meter for detecting the exhaust amount of the exhaust gas. 86, a control valve 88 for adjusting the exhaust amount of the exhaust gas is provided. In particular, the pressure gauge 84, the flow meter 86 and the control valve 88 is connected to the flow rate display control unit 90, the flow rate display control unit 90 from the pressure gauge 84 and the flow meter 86, respectively By receiving the detection value it is possible to control the discharge and discharge state of the exhaust gas through the exhaust line 80 by adjusting the ?? ke of the control valve 88. In addition, the exhaust line 80 is provided with a thermometer 92 for detecting the temperature of the exhaust gas discharged, the thermometer 92 is connected to the flow rate display control unit 90, the detected temperature value of the flow rate display control unit 90 is passed.

The cooler 100 is communicated to the rear end of the exhaust line 80 by the delivery line 94. Cooling air fan 102 for pumping the exhaust gas discharged through the exhaust line 80 to the cooler described later is installed in the delivery line 94. Of course, the cooling air fan 102 is a standby for receiving air Line 104 is connected. In particular, in the delivery line 94 at the rear of the cooling air fan 102, a collecting unit 106 for acquiring a sample of the discharged exhaust gas is installed. Has two jipbu 106 and the sampler 108 connection, the sampler 108 is coupled to future thio (RATIO), that is, CO ₂ concentration analyzer 110 for analyzing the CO ₂ in practice.

Optionally, the delivery line 94 at the rear of the cooling air fan 102 may also be provided with a flow meter 112 for detecting the amount of exhaust gas to be sent, which flow meter 112 described above is a CO ₂ concentration analyzer. It is connected to the flow rate display control unit 114 is connected to (110). In addition, the flow rate display control unit 114 is connected to a control valve 116 installed in front of the cooling air fan 102 to adjust the amount of exhaust gas sent by controlling the opening and closing of the control valve 116.

On the other hand, the rotary kiln 118 is burned quicklime is connected to the cooler 100 installed at the end of the discharge line 94, accordingly, the quicklime calcined in the rotary kiln 118 is supplied to the cooler 100 and sent out at the same time Exhaust gas supplied from line 104 may be introduced to coat the surface of calcined quicklime.

Of course, the lower portion of the cooler 120 is provided with a conveyor 122 for transferring the calcined lime coated by the exhaust gas in the cooler to the steelmaking process or to the post-treatment process.

Further, although not shown in the figures, all the components as described above are linked to a PLC (PROGRAMMING LOGIC CONTROLLER), which can automatically or arbitrarily control the system and is preferably controlled by it.

Alternatively, the recarbonation system described above is illustrated with one dust collector for filtering one dust and mist, but it is obvious that two or more dust collectors may be installed depending on the capacity or purpose of the system. something to do.

Hereinafter, the operation of the calcined recarbonation system configured as described above and the method for producing calcined lime will be described in detail.

For example, when the shaft kiln stack 10 using COG as a heat source is operated to produce high-quality quicklime for producing high clean steel, flue gas is generated, and the flue gas is ducted by the flue gas fan 16. It is conveyed to the dust collector 20 can be installed one or two through. At this time, the state of the exhaust gas is, for example, 50 ℃ to 70 ℃, CO ₂ concentration is 20 ~ 24%, the amount of dust is 10 ~ 50mgNm ³ .

At the same time that the exhaust gas is introduced into the dust collector 20, water is injected into the dust collector 20 through the water supply line 26 connected to the dust collector, so that they meet and rotate in the outer cylinder 22. In particular, the exhaust gas and injected water flow into the outer cylinder 22 and are discharged into the inner cylinder 24. Thus, in the discharge process, the exhaust gas suddenly loses pressure and eventually becomes saturated steam, and the dust contained in the gas and Moisture is collected by the filter 24a built into the inner cylinder 24. The dust and mist collected as described above are discharged to the water collecting tank 30 installed below the dust collector 20 and transferred to the sludge channel or disposed of after being treated. Of course, when two or more dust collectors 20 are installed, it is apparent that the above-described processes may be sequentially performed in each dust collector.

Thereafter, the exhaust gas filtered by the dust collector 20 is transferred to the heat exchanger 40 through the duct 36 by the blower 34 and cooled. That is, the exhaust gas flowing into the heat exchanger 40 is cooled to a predetermined temperature by the cooling water supplied to the heat exchange plate 42 from the cooling line and circulated.

Meanwhile, the cooling water supplied to the heat exchanger 40 is supplied from the cooling water tank 50, and the collection tank 50 is supplied with the exhaust gas cooling water cooled in the refrigerator 60, and the exhaust gas cooling water is exchanged through the supply line. It is supplied to the heat exchange plate 42 of the group 40. Of course, the refrigerator 60 is supplied with cooling water cooled in the cooling tower 70 to cool the heat generated while the exhaust gas cooling water is generated by the chiller 60a therein. The exhaust gas coolant is capable of supplying exhaust gas coolant at an optimum temperature to the heat exchanger while continuously circulating the coolant tank 50, the heat exchanger 40, and the freezer 60. This optimum supply of exhaust gas coolant is supplied to the respective lines 44, 52, 62, 64, 72 connecting the cooling water tank 50, the heat exchanger 40, the freezer 60 and the cooling tower 70. Thermometer 44a, flow switch 44b, first circulation pump 54, flow meter 56, control valve 58, level indicator 50b, second circulation pump 66, thermometer 62a ), The flow switch 62b, the third circulation pump 74 and the like can be achieved by the respective functions and the interconnected operation.

As described above, looking at the state of the exhaust gas after cooling in the heat exchanger, for example, the temperature of the exhaust gas is 20 ℃ or less, below the atmospheric temperature, the humidity is 5% or less, the CO ₂ concentration is 20 ~ 22%, the dust of The amount is 5 mgNm ³ .

Meanwhile, the exhaust gas cooled in the heat exchanger 40 is injected into the cooler 100 by the cooling air fan 102 through the exhaust line 80 and the delivery line 94. At this time, the exhaust gas discharged through the exhaust line 80, the concentration of CO ₂ of the exhaust gas is detected by the CO ₂ analyzer 82 installed in the exhaust gas line 80, the pressure of the exhaust gas is detected by the pressure gauge 84 The discharge amount of the exhaust gas is detected by the flow meter 86, and the detected values are transmitted to the flow rate display control unit 90 to adjust the opening degree of the control valve 88 based on the flow rate control unit 90. It is possible to control the emission and emission status of the flue gas through. In addition, the exhaust gas is collected by the exhaust gas collecting unit 106 and the sampler 108 of the delivery line 94 at the rear of the cooling air fan 102, and the CO ₂ in the exhaust gas is analyzed to analyze the CO _{2 in} the CO ₂ concentration analyzer 110. ₂ concentration can be analyzed, on the basis of this it is possible to control the temperature of the coolant as well as the operation of the dust collector 20 and the heat exchanger 40 using a PLC. Furthermore, the amount of exhaust gas discharged by using the flow meter 112, the flow rate display control unit 114 and the control valve 116, which can be additionally installed in the delivery line 94 behind the cooling air fan 102. Can finally be adjusted. In particular, the concentration of CO ₂ is adjusted to 5-8% by the respective control valves, CO ₂ analyzer, and CO ₂ concentration analyzer as described above to be supplied to the cooler 100.

Finally, the exhaust gas injected through the delivery line 94 to the cooler 100 installed at the end thereof is already fired in the rotary kiln 118 and injected into the calcined lime supplied to the cooler 100, so that the surface thereof To be coated.

Thereafter, the coated quicklime is transferred to and used in the steelmaking process by a conveyor 122 installed under the cooler 120.

As such, the exhaust gas discharged from the shaft kiln stack is collected through filtration, filtration, cooling, and carbon dioxide concentration to generate an optimal exhaust gas, and the exhaust gas is applied to the surface of quicklime to produce high clean steel. High quality quicklime can be produced.

As a result, according to the calcined recarbonation system according to the present invention, the exhaust gas discharged into the atmosphere can be recycled, the exhaust gas emission can be reduced, and the surface of quicklime is coated by treating the exhaust gas in an optimal state to coat the quicklime. By preventing the hydration of hydride and the differentiation rate is reduced during storage or transportation, high quality quicklime is provided, thereby improving product quality and reliability.

In addition, the cooling efficiency of the exhaust gas is improved, the condensation of the exhaust gas and the temperature is reduced continuously and quickly has the advantage of improving the yield and workability of quicklime.

While a preferred embodiment according to the present invention has been described above, it will be understood by those skilled in the art that various modifications and changes can be made without departing from the scope of the appended claims.

Claims (13)

Shaft kiln stack; A dust collector connected to the shaft kiln stack and configured to collect dust and mist by injecting exhaust gas generated from the shaft kiln stack; A heat exchanger connected to the dust collector and configured to cool the exhaust gas filtered by the dust collector; A cooling water line for supplying and circulating cooling water to the heat exchanger; And An exhaust line connected to the heat exchanger and configured to transfer exhaust gas cooled by the heat exchanger; A delivery line communicating with the exhaust line and for sending exhaust gas discharged from the exhaust line; And And a cooler connected to the delivery line and receiving the quicklime calcined in the rotary kiln and including a cooler for spraying and coating the exhaust gas supplied from the delivery line on the calcined lime. The dust collector of claim 1, wherein the exhaust gas flows from the shaft kiln stack in a rotational manner and a water supply line for injecting moisture into the exhaust gas is in communication with the outer cylinder, and the exhaust gas is provided from the outer cylinder. Recarbonation system using a calcined flue gas, characterized in that it includes an inner cylinder in which pressure is introduced and the filter is installed to collect dust and mist. The recarbonation system using a calcined flue gas, characterized in that one or two dust collectors are installed. The recarbonation system of claim 1, wherein the heat exchanger includes a heat exchanger plate through which coolant supplied from the cooling line is circulated. According to claim 1, wherein the cooling water line is connected to the heat exchanger by a supply line and a return line and a cooling water tank for collecting exhaust gas coolant; A refrigerator connected to the cooling water tank by a return pipe to return the exhaust gas cooling water used in the supply pipe and the heat exchanger to supply the cooled exhaust gas cooling water to the cooling water tank; And Re-carbonation system using a calcined flue gas, characterized in that it comprises a cooling tower connected by a transfer pipe to produce a cooling water for cooling the chiller (chiller) in the refrigerator. The method of claim 5, wherein the return line is connected to the heat exchanger and the coolant tank is installed with a thermometer and a flow switch for detecting the temperature of the returning coolant, the supply line is a first circulation for sending the coolant from the coolant tank to the heat exchanger Recarbonation system using a calcined flue gas, characterized in that the pump is provided. The method of claim 6, wherein the supply line is further provided with a flow meter for detecting the amount of cooling water supplied to the heat exchanger, a control valve for regulating the amount of constant supply, the control valve is also addressed to the return line Recarbonation system using lime-fired exhaust gas. The method of claim 5, wherein the return pipe connecting between the coolant tank and the freezer is provided with a second circulation pump for sending exhaust gas coolant to the freezer, the supply pipe is a thermometer for detecting the temperature of the exhaust gas coolant supplied; Recarbonation system using a calcined flue gas, characterized in that the flow switch is installed. 6. The recarbonation system according to claim 5, wherein a third circulation pump is installed in a transfer pipe connecting the refrigerator and the cooling tower to facilitate the transfer of the cooling water. The exhaust line of claim 1, wherein the exhaust line includes a CO ₂ analyzer for detecting the concentration of CO ₂ of the exhaust gas discharged through the exhaust line, a pressure gauge for detecting the pressure of the exhaust gas, a flow meter for detecting the exhaust amount of the exhaust gas, and an exhaust gas. Recarbonation system using a calcined flue gas, characterized in that the control valve for controlling the displacement is installed. The method of claim 10, wherein the pressure gauge, the flow meter and the control valve is connected, by receiving the respective detection value from the pressure gauge and the flow meter to adjust the opening degree of the control valve to adjust the discharge and discharge state of the exhaust gas through the exhaust line Recarbonation system using a calcined flue gas further comprises a flow rate display control unit. The method of claim 1, wherein the discharge line is a cooling air fan for pumping the exhaust gas discharged to the cooler through the exhaust line, a collecting unit for obtaining a sample of the exhaust gas, and sampling the exhaust gas collected by the collecting unit And a CO ₂ concentration analyzer for analyzing the CO ₂ concentration of the exhaust gas sampled by the sampler. The method according to any one of claims 1 to 12. Re-carbonization system using a calcined flue gas further comprises a PLC (PLC: PROGRAMMING LOGIC CONTROLLER) for the overall control of the calcinable recarbonation system.