KR20050036374A - A rotary type pre-heater for a sintering furnace - Google Patents

Abstract

The present invention relates to a preheating apparatus provided in a rotary kiln for preparing quicklime (CaO) by injecting limestone (CaCO ₃ ).

The present invention has a hollow outer cylinder and a middle cylinder located therein, wherein a limestone is charged from the upper side of the outer cylinder to the middle barrel and preheated, and the preheating apparatus of a rotary firing furnace for supplying to a firing furnace, wherein the outer cylinder A ring gear mounted on the bottom outer circumference of the wheel; A drive unit having a drive gear geared to the ring gear and having a drive motor for rotating the ring gear; and a plurality of rollers disposed along a virtual circle at the bottom of the outer cylinder, and a circular rail supporting the rollers. It provides a rotary preheater of the rotary kiln, characterized in that for supplying the limestone between the barrel and the outer cylinder to the firing furnace side while rotating by the operation of the drive unit, including.

According to the present invention, when the heat generated in the kiln flows to the inside of the preheater, the heat can be flowed evenly without biasing a certain part, thereby obtaining an effect of remarkably improving the yield per unit time.

Description

Rotary preheater of rotary kiln {A ROTARY TYPE PRE-HEATER FOR A SINTERING FURNACE}

The present invention relates to a preheating apparatus provided in a rotary kiln for preparing quicklime (CaO) by adding limestone (CaCO ₃ ), and more specifically, when heat generated in the kiln flows inward, the heat is removed from a certain portion. The present invention relates to a rotary preheater of a rotary kiln, which is able to flow evenly without hitting, thereby significantly improving the production per unit time.

As shown in FIG. 1, the conventional quicklime manufacturing apparatus 200 includes a preheater 210 at one side of the firing furnace 205, and passes limestone (CaCO ₃ ) into the firing furnace 205 through the preheater 210. do. In addition, the baking furnace 205 is provided with a burner 220 on the opposite side of the preheater 210, and an outlet 222 is formed to discharge the quicklime (CaO) from which baking is completed.

In addition, the outlet 222 is provided with a cooler 230 for cooling the quicklime, and the calcining furnace 205 is rotated and calcined into the quicklime by the heat source of the burner 220 while the limestone contained therein is rotated.

Such quicklime manufacturing apparatus 200 is the quicklime manufacturing process is as follows. That is, the limestone is washed cleanly in a separate centuries (not shown), and then sorted into granules having a size of 10 to 30 mm, charged into a pre-heator 210, and stored for about 9 to 10 hours. After preheating with the exhaust gas of about 1000 ~ 1100 ℃ discharged from the kiln 205, it is charged to the rotary kiln 205 in the direction opposite to the exhaust gas.

   In the rotary kiln 205, the limestone preheated to a predetermined temperature is heated. Thus, the burner 220 burns fuel to generate hot combustion gas, and the inside of the kiln 205 is 1250 to 1300 ° C. The limestone is calcined while rotating the kiln 205 at a temperature of 2.5 to 3 hours. Then, the quicklime is taken out from the kiln 205, charged in the cooler 230, and cooled for 2 to 3 hours to produce the final product (quicklime).

   Such a conventional rotary kiln 205 is very advantageous in producing high quality quicklime compared to the linear kiln 205 in which limestone is not rotated because limestone is uniformly heated by rotation.

As such, in order to manufacture high-quality quicklime, a uniform amount of heat is introduced into the kiln 205 and a uniform limestone particle size is added to prevent uncalcified products from being generated.

On the other hand, in such a quick lime manufacturing apparatus, the limestone is introduced into the firing furnace 205 through the preheater 210 as shown in FIG. 2. The preheater 210 is limestone is introduced into the hopper 214 through the belt conveyor 212 from the upper end, the hopper 214 sequentially quantified limestone to the outer cylinder 216 of the lower portion. Inside the outer cylinder 216 is located a barrel 217 for preventing the firing by limestone, to prevent overheating of the preheater 210, the cooling air is introduced into the barrel 217 is circulated and discharged Has a structure of cooling system 218.

In addition, a plurality of pushers 219 are positioned at the lower side of the outer cylinder 216 in the circumferential direction to charge limestone in the firing furnace 205, and the exhaust gas discharged from the firing furnace 205 is the outer cylinder 216. Heats with the limestone in the outer cylinder 216 while flowing inward to preheat it, and is discharged to the dust collector 250 through the discharge pipe 216a at the top of the outer cylinder 216, and finally the stack 260 in a dust-damped state. Is discharged through). Thus, the present invention is to charge the limestone in the preheating state of the kiln 205 through the preheater 210.

However, in the process of introducing the exhaust gas of the rotary firing furnace 205 into the preheater 210 in the conventional preheater 210 as described above, the heat of the exhaust gas is transferred to the charged raw material layer of each part charged in the preheater 210. By not absorbing the heat evenly, the exhaust gas passes through a portion of the charged raw material, so that the heat retained in the exhaust gas partially heats the charged raw material.

That is, the heat of the exhaust gas flowing into the lower part of the preheater 210 from the kiln 205 into which the preheating raw material is charged is "A-2" where the flow length is short, and the flow length of the exhaust gas is relatively long. A-1 "can be divided into sections. Therefore, the charging raw material which is stagnant at the "A-1" site and absorbs heat is delayed in preheating. On the contrary, the A-2 site is preheated relatively quickly by the exhaust gas flowing in the kiln 205. Site -1 and site A-2 are subject to conditions in which heat flow at the same temperature cannot be achieved.

In order to solve such a problem, conventionally, the number of operations of each pusher 219 is reduced, so that the raw material having a low preheating temperature stops the operation of the pusher 219 once or twice to stagnate the raw material to preheat the raw material. Was raised and then the pusher 219 was operated to descend to the firing furnace 205 side. On the contrary, the site having a relatively high temperature has been trying to maintain the temperature of the preheating material charged in the preheater 210 by operating the pusher 219 once or twice more.

However, if the operation is to be restarted after the sudden stop in the initial operation or in the firing state in progress, the partial pre-firing of the preheating raw material in the preheater 210 and congestion resulting therefrom to take measures against this This becomes difficult, and in the latter case, it is difficult to determine how much the preheating raw material inside the preheater 210 is caused by falling of each part temperature rapidly.

Therefore, if the heat is not uniform in the preheating process, such a partial bias, it causes a partial hanging on the raw material being preheated, and there is a problem that continuous operation cannot be performed when this condition continues. In particular, when the exhaust gas is combusted while intensively flowing through a part of the preheater 210, there is a problem that causes the surface of the raw material to burn black and the phenomenon of melting the surface of the raw material in the preheating section of the raw material. Cause.

This phenomenon causes the limestone (CaCO3) to rapidly receive a lot of heat in a short period of time, and the surface of the gemstone is underestimated (black burning) and minus (melting) to prevent the CO2 gas that must be ejected from the inside of the gemstone to the outside. Blocking while forming a film, that is, blocking the decarbonate reaction. Therefore, such a phenomenon is a major cause of the hanging phenomenon of the preheating raw material, and the production of quicklime in the kiln 205 is greatly reduced due to such a phenomenon.

The present invention is to solve the conventional problems as described above, the object is that the heat of the exhaust gas flowing when the heat generated in the kiln flows to the preheater flows evenly in the interior, without biasing to any predetermined portion, The present invention provides a rotary preheater of a rotary kiln, which can prevent under and phenomena in the kiln, and thus can significantly improve the amount of quicklime production per unit time.

In order to achieve the above object, the present invention is a rotary firing furnace having a hollow outer cylinder and a middle cylinder located therein, charged with limestone between the upper barrels and preheated, and supplied to a firing furnace from an upper side of the outer cylinder. In the preheater of

A ring gear mounted to a lower outer circumferential surface of the outer cylinder;

A drive unit having a drive gear geared to the ring gear and having a drive motor to rotate the ring gear; and

Rotating portion having a plurality of rollers disposed along the imaginary circle in the lower portion of the outer cylinder and a circular rail for supporting the rollers to supply the limestone between the barrel and the outer cylinder to the firing furnace side while rotating by the operation of the drive unit. By providing a rotary preheater of the rotary firing furnace, characterized in that.

Hereinafter, the present invention will be described in more detail with reference to the drawings.

The rotary preheater 1 of the rotary kiln according to the present invention has a hollow outer cylinder 216 and a middle cylinder 217 located therein, as shown in FIGS. The limestone is charged and preheated between the barrel and the barrel 217 on the upper side, and supplied to the firing furnace 205.

The present invention includes a ring gear 10 mounted on a lower outer circumferential surface of the outer cylinder 216, wherein the ring gear 10 is integrally fixed to the outer cylinder 216, and is coupled to a rotation shaft of the drive motor 12. It is gear-coupled with the mounted drive gear 14.

As described above, the present invention includes a drive gear 14 geared to the ring gear 10 and a drive unit 20 having a drive motor 12 for rotating the ring gear 10, thereby operating the drive motor 12. When the shaft rotates, the ring gear 10 is rotated through the drive gear 14 to rotate the outer cylinder 216 and the middle cylinder 217 on which the ring gear 10 is mounted.

In addition, the present invention includes a rotary part 30 having a plurality of rollers 32 arranged along a virtual circle at the bottom of the outer cylinder 216 and a circular rail 34 supporting the rollers 32. As shown in FIGS. 3 and 4, the rotating part 30 includes a support frame 42 on which the discharge chute 40 disposed successively disposed at the lower outlet 210a of the preheater 210 is mounted. A round circular rail 34 is formed on the upper surface, and a plurality of rollers 32 to slide on the rail 34 are fixed to the lower surface of the outer cylinder 216.

This rotation part 30 is to allow the rollers 32 to rotate along the rail 34, which is the motor 12 of the drive unit 20 is activated to the outer cylinder 216 through the ring gear 10 ), The outer cylinder 216 is rotated on the support frame 42 through the rollers 32 and the rail 34.

On the other hand, the outer cylinder 216 forms a structure rotatable with respect to the discharge duct 216a leading to the dust collector 250 and the upper side charging portion 50 of the preheater 210 to which the discharge duct 216a is fixed. In order to form the water sealing portion 60, as shown in Figure 5 in the upper corner. The water sealing portion 60 forms a bent portion 62 having a 단면 -shaped cross section, and water 65 is filled inside the bent portion 62, and a lower edge thereof into the water of the bent portion 62. The bottom edge 50a of the charging unit 50 is disposed so as to be locked.

Through the structure of the water sealing unit 60, the lower edge 50a of the charging unit 50 and the upper bent portion 62 of the outer cylinder 216 are connected to the charging unit 50 while preventing the outflow of the exhaust gas. It is to ensure the smooth rotation of the outer cylinder 216 with respect to.

In addition, the cooling system 70 for cooling the barrel 217 forms a pedestal 72 on one side of the outer cylinder 216, and an air inflow pump 74 is mounted on the pedestal 72. Rotate together with the outer cylinder 216. And, the cooling air introduced into the inside of the barrel 217 from the air inlet pump 74 through the conduit 76 is discharged to the conduit 76 on the opposite side via the barrel 217, the conduit ( It is configured to be opened and closed by a damper 80 mounted at the end of the 76.

In addition, the present invention includes a power supply unit 90 that receives power from the outside to provide power to the air inflow pump 74 and the pusher 219, as shown in FIGS. Similarly, a round annular terminal frame 92 is connected to the peripheral support 93 to be fixed to the upper side of the outer cylinder 216, and is coupled to the terminal frame 92 to receive a power supply trolley (Trolley) ( 95 is connected to the outer cylinder 216 to be rotated.

The power supply unit 90 is supplied with power from the three-phase terminal 92a of the terminal frame 92 to the three-phase terminal 95a provided in the trolley 95, and this power is supplied to the cable 97 It is used to operate the cylinder of the air inlet pump 74 or the pusher 219 through.

In the rotary preheater 210 of the rotary kiln 205 according to the present invention configured as described above, the limestone is introduced into the charging unit 50 side through the charging hopper 214, which is the outer cylinder 216 and the middle barrel ( 217 is introduced into the interspace, and in this state, the outer cylinder 216 is rotated. When the outer cylinder 216 is rotated as described above, the exhaust gas flowing into the interior of the outer cylinder 216 from the firing furnace 205 via the discharge chute 40 located on the lower side of the outer cylinder 216 is Due to the rotation of the outer cylinder 216 is applied to the limestone as a whole.

At the same time, the air inlet pump 74 of the cooling system 70 for the barrel 217 also operates to provide cooling air to the interior of the barrel 217 and allow it to be discharged through the damper 80. Effective cooling is achieved.

In addition, the exhaust gas discharged while preheating the limestone located in the space between the outer cylinder 216 and the middle cylinder 217 is discharged to the stack 260 via the dust collector 250, and periodically the pusher ( 219 is operated to lower the limestone to the discharge chute 40 and to supply it to the firing furnace 205 side.

Therefore, the present invention is to transmit a uniform heat to the limestone which is the raw material ore in the preheater 210 to prevent the under-calculation or partial phenomena of the partial limestone, it is possible to achieve a good quick lime production in the kiln 205.

As described above, according to the present invention, when the high-quality quicklime is manufactured in the rotary kiln 205, uniform preheating of the raw stone (limestone) preheated by the preheater 210 can be achieved. Therefore, it is possible to prevent the conventional hanging phenomenon caused by partial underdevelopment or phenomena, to increase the quality of quicklime quicklime products, and to significantly improve the yield of quicklime per unit time.

1 is a block diagram showing the overall process of a typical quicklime manufacturing apparatus;

2 is a side cross-sectional view showing a preheater according to the prior art;

3 is a side cross-sectional view showing a rotary preheater of a rotary kiln according to the present invention;

4 is a cross-sectional view along the line A-A of FIG.

5 is a structural diagram of the water sealing portion provided in the rotary preheater of the rotary firing furnace according to the present invention;

6 is a partial cutaway perspective view showing a power supply device provided in the rotary preheater of the rotary kiln according to the present invention.

<Description of the symbols for the main parts of the drawings>

1 .... Rotary preheater in rotary kiln 10 .... Ring gear

12 ... drive motor 14 .... drive gear

20 .... Drive 30 .... Rotating

32 .... roller 34 .... rail

42 .... support frame 50 .... charging

60 .... Suture 62 .... Bend

65 ... water 70 ... cooling system

72 .. Pedestal 74 .... Air Inlet Pump

76 .... Conduit 80 ... Damper

90 .... Power Supply 95 .... Trolley

200 .... Conventional quicklime manufacturing apparatus 205 .... Firing furnace

210 .... Preheater 214 .... Hopper

216 .... Foreign 217 .... Chinese

218 .... cooling system 220 .... burner

222 .... outlet 230 .... cooler

250 .... dust collector 260 .... stack

Claims (4)

A hollow outer cylinder 216 and a middle cylinder 217 located inside thereof are provided, and the limestone is charged and preheated from the upper side of the outer cylinder 216 to the middle cylinder 217 and supplied to the firing furnace 205. In the preheating apparatus of the rotary firing furnace 205, A ring gear 10 mounted on a lower outer circumferential surface of the outer cylinder 216; A drive unit 20 having a drive gear 14 geared to the ring gear 10 and having a drive motor 12 for rotating the ring gear 10; and And a rotating part (30) having a plurality of rollers (32) disposed along an imaginary circle under the outer cylinder (216) and a circular rail (34) for supporting the rollers (32). A rotary preheater of a rotary kiln, characterized in that for supplying limestone between the barrel (217) and the outer cylinder (216) to the firing furnace (205) side while rotating in operation. According to claim 1, wherein the outer cylinder 216 is rotated with respect to the discharge duct 216a leading to the dust collector 250 and the upper side charging portion 50 of the preheater 210 to which the discharge duct 216a is fixed. In order to achieve a possible structure, the water sealing part 60 is further included at an upper edge thereof, and the water sealing part 60 forms a bent part 62, and water 65 is filled inside the bent part 62. And a lower edge (50a) of the charging portion (50) is disposed so as to be immersed in the water of the bent portion (62). The apparatus of claim 1, further comprising a cooling system (70) for cooling the barrel (217), wherein the cooling system (70) forms a pedestal (72) to one side of the outer cylinder (216). An upper portion of the 72 is equipped with an air inlet pump 74 so as to be rotatable with the outer cylinder 216, and flows into the inside of the barrel 217 from the air inlet pump 74 through a conduit 76. The cooled cooling air is discharged to the conduit 76 on the opposite side via the middle barrel 217, and the rotary kiln is configured to be opened and closed by a damper 80 mounted at the end of the conduit 76. Rotary preheater. The apparatus of claim 1, further comprising a power supply unit 90 that receives power from the outside, wherein the power supply unit 90 has a circular ring terminal frame 92 on the upper side of the outer cylinder 216. The rotary preheater of the rotary kiln, characterized in that to be connected to the (93), and to be connected to the terminal frame 92, the trolley (95), which is supplied with power, to the outer cylinder (216) to be rotated. .