CN113137854A - Hanging cylinder type parallel-flow heat storage double-hearth kiln - Google Patents

Abstract

The invention relates to a suspended cylinder type parallel-flow heat storage double-chamber kiln which comprises a double-chamber kiln body, a feeding device, a discharging device, an air supply system, a structural cooling air system and a waste gas discharge system. The double-chamber kiln body consists of an inner furnace wall and an outer furnace wall, and the inner furnace wall is hung on the outer furnace wall. The lower part of the inner furnace wall is provided with an annular suspension cylinder type furnace wall which is composed of a steel structure jacket, an inner pouring layer and an outer pouring layer. According to the hanging cylinder type parallel-flow heat storage double-hearth kiln provided by the invention, the fireproof concrete layers formed by the inner and outer pouring layers are built on the two sides of the steel structure jacket to form the annular hanging cylinder type furnace wall, the mode that the fireproof bricks are built on the two sides of the steel structure of a common hanging cylinder is abandoned, the problem that the bricks fall off from the common hanging cylinder is thoroughly solved while the high-temperature protection is carried out on the steel structure jacket of the hanging cylinder, the integral strength of the hanging cylinder is improved, and the service life of the hanging cylinder is prolonged.

Description

Hanging cylinder type parallel-flow heat storage double-hearth kiln

Technical Field

The invention belongs to the technical field of chemical building material production equipment, relates to an industrial furnace, and particularly relates to a suspended cylinder type parallel-flow heat storage double-chamber kiln.

Background

The double-hearth kiln is also called a double-hearth parallel-flow heat accumulating type lime kiln, and fuel enters from the upper end of a calcining zone and flows in parallel with raw materials. Since the fuel is injected from the upper part of the calcining zone, where the raw material can absorb most of the heat released by the fuel, the temperature of the calcining zone is 950 ℃ on average. Another important feature of the double-hearth kiln is heat storage, which is used to preheat a portion of the combustion air. The thermal characteristics of co-current calcination and counter-current heat storage determine that the double-hearth kiln has high thermal efficiency, the heat energy consumption is the lowest in all types of lime kilns including rotary kilns, sleeve kilns and the like, and the total heat consumption for producing lime is about 3.8 GJ/ton of lime. The double-hearth kiln has excellent performance in calcining limestone materials with small grain sizes, and the produced lime has good quality.

The suspension cylinder system is a key core device of the cocurrent flow double-chamber kiln, the cylinder body is arranged in the kiln chamber, and in order to prevent the cylinder body from being damaged by heat, the inside of the cylinder body is cooled by using circulating air. Because the internal structure of the suspension cylinder belongs to a hollow structure formed by heat-resistant stainless steel and is positioned at the calcining part of the kiln, in order to avoid the deformation of the structure under high temperature, measures must be taken to cool and protect the internal structure of the suspension cylinder so as to ensure the safe operation of the kiln. In addition, the common suspension cylinder is built by using refractory bricks on the inner side and the outer side of the stainless steel, so that the stainless steel is further protected from high-temperature damage. The method for building the refractory bricks can protect stainless steel at high temperature, but the problem of brick falling is often caused in the long-term use process.

Disclosure of Invention

The invention aims to provide a suspended cylinder type parallel-flow heat storage double-hearth kiln, which thoroughly solves the problem of brick falling by changing the method of building refractory bricks on two sides of a stainless steel structure of a suspended cylinder.

The technical scheme of the invention is as follows:

a suspended cylinder type parallel-flow heat storage double-chamber kiln comprises a double-chamber kiln body, a feeding device, a discharging device, an air supply system, a structural cooling air system and a waste gas discharge system, wherein the double-chamber kiln body is composed of an inner furnace wall located at the upper part and an outer furnace wall located at the lower part, and the inner furnace wall is suspended on the outer furnace wall. The double-hearth kiln body is internally provided with a preheating zone, a calcining zone and a cooling zone. The double-chamber kiln body comprises a kiln chamber A and a kiln chamber B, wherein the upper parts of the kiln chamber A and the kiln chamber B are respectively provided with an air inlet and an air outlet, and the air inlet and the air outlet are connected with an air blower and a waste gas discharge system through a three-way valve. The calcining zone is provided with a burner, the cooling zone is provided with a cooling air inlet, the lower part of the cooling zone is provided with a discharge hole, the discharge hole is connected with a discharge device, and the cooling air inlet is connected with a cooling fan through a three-way valve. The lower part of the inner furnace wall is provided with an annular suspension cylinder type furnace wall, and the annular suspension cylinder type furnace wall is suspended in the kiln. The annular suspension cylinder type furnace wall is composed of a steel structure jacket, an inner pouring layer and an outer pouring layer. The inside cooling air circulation cavity that is of steel construction jacket. The cooling air circulation cavity is provided with a structure cooling air inlet and a structure cooling air outlet, the structure cooling air inlet is connected with a structure cooling air system through a pipeline, and the structure cooling air outlet is connected with a combustion-supporting air pipeline through a pipeline.

Further, the outer pouring layer completely covers the outer side of the annular suspension cylinder type furnace wall; the inner casting layer covers the inner side of the annular suspension cylinder type furnace wall completely or partially from bottom to top.

Further, when the inner casting layer partially covers the inner side of the annular suspension cylinder type furnace wall, the remaining portion of the inner side of the annular suspension cylinder type furnace wall is constructed using refractory bricks.

Furthermore, the connection part of the annular suspension cylinder type furnace wall and the inner furnace wall is provided with refractory fiber. The steel structure jacket is provided with a supporting structure, two sides of the steel structure jacket are provided with anchoring pieces, and the anchoring pieces are embedded into the inner pouring layer or the outer pouring layer.

Further, the anchoring member includes a fixing member connected to the steel structure jacket, and an extension member connected to the fixing member. The top of the extension piece is provided with two or more branch pieces.

Furthermore, an annular channel is arranged between the annular suspension cylinder type furnace wall and the outer furnace wall.

Furthermore, a steel structure jacket in the annular suspension cylinder type furnace wall is of a segmented structure, and each segment of the steel structure jacket is provided with a structure cooling air inlet and a structure cooling air outlet. The steel structure jacket is divided into at least 1 section.

Further, the inner and outer casting layers include, but are not limited to, casting using high alumina and magnesia refractory concretes.

Further, the burner is an insertion burner, a combustion beam or a peripheral burner; the inserted burner is a gas fuel burner, a liquid fuel burner or a solid fuel burner.

According to the hanging cylinder type parallel-flow heat storage double-hearth kiln provided by the invention, the fireproof concrete layers formed by the inner and outer pouring layers are built on the two sides of the steel structure jacket to form the annular hanging cylinder type furnace wall, the mode that the fireproof bricks are built on the two sides of the steel structure of a common hanging cylinder is abandoned, the problem that the bricks fall off from the common hanging cylinder is thoroughly solved while the high-temperature protection is carried out on the steel structure jacket of the hanging cylinder, the integral strength of the hanging cylinder is improved, and the service life of the hanging cylinder is prolonged.

Drawings

FIG. 1 is a schematic structural diagram of a suspended cylinder type parallel-flow heat storage double-hearth kiln of the invention;

FIG. 2 is detail D of FIG. 1;

FIG. 3 is a cross-sectional view taken along line A-A of FIG. 1;

FIG. 4 is a cross-sectional expanded view of the steel jacket;

fig. 5 is a schematic structural view of the anchor.

Wherein: 1-feed inlet, 2-blower, 4-inlet and outlet, 5-inner furnace wall, 6-annular channel, 7-outer furnace wall, 9-cooling air inlet, 10-discharge outlet, 11-annular suspended cylinder furnace wall, 12-three-way valve, 13-burner, 14-flue gas channel, 16-cooling zone, 17-cooling fan, 18-waste gas discharge system, 19-preheating zone, 20-calcining zone, 21-refractory fiber, 22-inner casting layer, 23-steel structure jacket, 24-anchoring piece, 241-fixing piece, 242-extension piece, 243-branch piece, 25-support structure, 26-structure cooling air inlet, 27-structure cooling air outlet, 28-cooling air circulation cavity and 29-outer casting layer.

Detailed Description

The present invention will be described in detail with reference to the following examples and drawings. The scope of protection of the invention is not limited to the embodiments, and any modifications made by those skilled in the art within the scope defined by the claims also belong to the scope of protection of the invention.

The invention discloses a suspended cylinder type parallel-flow heat storage double-hearth kiln, which comprises double-hearth kiln bodies, feeding equipment, discharging equipment, an air supply system, a structural cooling air system and a waste gas discharge system 18 as shown in figure 1, wherein a flue gas channel 14 is arranged between the two kiln bodies. The double-hearth kiln body is composed of an inner furnace wall 5 positioned at the upper part and an outer furnace wall 7 positioned at the lower part, the inner furnace wall is hung on the outer furnace wall, and a preheating zone 19, a calcining zone 20 and a cooling zone 16 are arranged in the double-hearth kiln body. The double-chamber kiln body comprises a kiln chamber A and a kiln chamber B, wherein the upper parts of the two kiln chambers are provided with an air inlet and outlet 4, the lower parts of the two kiln chambers are provided with a discharge hole 10, the air inlet and outlet is connected with an air blower 2 and a waste gas discharge system 18 through a three-way valve 12, and the discharge hole is connected with a discharge device. The calcining zone is provided with a burner 13 which is an insert burner which is a gas fuel burner. The cooling zone is provided with a cooling air inlet 9 which is connected with a cooling fan 17 through a three-way valve. The waste gas discharge system comprises a dust remover, an induced draft fan and a chimney. The air supply system comprises a combustion-supporting air system and a cooling air system.

The lower part of the inner furnace wall 5 is provided with an annular suspension cylinder type furnace wall 11 which is suspended in the kiln. As shown in fig. 2 and 3, the annular suspension cylinder type furnace wall 11 is composed of a steel structure jacket 23, an inner casting layer 22 and an outer casting layer 29, the inner casting layer 22 is cast using magnesia refractory concrete, and the outer casting layer 29 is cast using high alumina refractory concrete.

In one embodiment, as shown in fig. 2, the outer casting layer 29 entirely covers the outside of the annular suspension cylinder furnace wall; the inner casting layer 22 covers the inner side of the annular suspension cylinder type furnace wall completely. In another embodiment, the outer casting layer 29 still completely covers the outside of the annular suspension cylinder furnace wall; however, the inner casting layer 22 partially covers the inside of the annular suspension cylinder furnace wall 11 from the bottom to the top, and the remaining portion inside the annular suspension cylinder furnace wall 11 is constructed using refractory bricks.

The common hanging cylinder is provided with refractory bricks built on two sides of a steel structure. In the long-term use process, dust and lime particles can enter gaps between refractory bricks, huge stress can be formed on a refractory brick masonry wall due to expansion with heat and contraction with cold in the switching process of shutdown and ignition operation of the double-hearth kiln, and particularly on the refractory brick masonry wall outside the suspension cylinder, the damage of the stress is very serious, and bricks falling from the outer side are often caused. The utility model provides a hang two thorax kilns of jar formula cocurrent flow heat accumulation, through the refractory concrete layer of pouring the layer constitution inside and outside the steel construction jacket both sides are established, form the annular jar formula brickwork that hangs, abandoned ordinary jar that hangs and built by laying bricks or stones the mode of nai firebrick in steel construction both sides, when the steel construction jacket to hanging the jar carries out high temperature protection, thoroughly solved ordinary jar that hangs and fall the problem of brick, the bulk strength who hangs the jar has been improved, be favorable to prolonging the life who hangs the jar.

The inside cooling air circulation cavity 28 that is of steel construction jacket, cooling air circulation cavity are equipped with structure cooling air entry 26 and structure cooling air export 27, and structure cooling air entry 26 passes through the pipeline and is connected with structure cooling air system, and structure cooling air export 27 passes through the pipeline and is connected with combustion-supporting wind pipe. The connection part of the annular suspension cylinder type furnace wall 11 and the inner furnace wall 5 is provided with refractory fiber 21. The steel structure jacket 23 is provided with a support structure 25, the two sides of the steel structure jacket are provided with anchoring pieces 24, and the anchoring pieces are embedded into an inner casting layer 22 and an outer casting layer 29. An annular channel 6 is arranged between the annular suspension cylinder type furnace wall 11 and the outer furnace wall 7.

As shown in FIG. 4, the steel structure jacket 23 in the annular suspension cylinder type furnace wall 11 is of a segmented structure, and each segment of the steel structure jacket 23 is provided with a structure cooling air inlet 26 and a structure cooling air outlet 27. The steel structure jacket 23 is divided into 4 sections or 6 sections.

Fig. 5 shows a schematic view of the anchor 24. As shown in fig. 5, the anchor member 24 includes a fixing member 241, and an extension member 242 connected to the fixing member 241. Two or more branches 243 are provided on the top of the extension 242. Specifically, the fixing member 241 is used for connecting the anchoring member 24 with the steel structure jacket 23, and the fixing member 241 may be connected with the steel structure jacket 23 by welding. In the anchor shown in fig. 5, a bolt is used to connect the extension 242 to the fixing member 241. Besides welding and bolts, other connection modes can be selected according to actual needs. In the anchor shown in fig. 5, the top of the extension 242 is provided with two branches 243 angled at 90 °. In practical applications, the angle between the branches may be changed, or the number of branches may be increased.

The operation process of the suspended cylinder type parallel-flow heat storage double-hearth kiln comprises the following steps: when the left kiln chamber A is calcined, fuel gas sprays fuel through an inserted burner 13 of the kiln chamber A, combustion-supporting air blown by the blower 2 enters the kiln chamber A from the air inlet and outlet 4 through the three-way valve 12 to be combusted in a combustion-supporting manner, and limestone materials in the left kiln chamber A are calcined. The hot air cooled in the cooling air circulation cavity 28 by the steel structure jacket enters the kiln chamber from the air inlet and outlet 4 through the structure cooling air outlet 27 for combustion supporting. The flue gas generated by calcination is delivered to the right kiln chamber B through the flue gas channel 14 to preheat the materials in the kiln chamber, and then is delivered to the waste gas discharge system 18 through the gas inlet and outlet 4 and the three-way valve of the right kiln chamber B to be discharged. When in calcination, the fuel is uniformly distributed on the cross section of the whole kiln chamber, and the temperature fields on the cross sections of the calcination zone are uniform, which is favorable for uniform calcination of limestone. And reversing after 12 minutes of operation, calcining the kiln chamber B on the right side after reversing, storing heat in the kiln chamber A on the left side, alternately performing cocurrent calcination and countercurrent heat storage in the kiln chambers on the two sides, and realizing automatic reversing operation through the actions of a three-way valve and a feeding valve. And the calcined lime enters a cooling zone 16, exchanges heat with lime cooling air entering from a cooling air inlet 9 to reduce the temperature of the lime to 60-80 ℃, and then is discharged from the kiln through a discharge hole 10. The temperature of lime cooling air after lime cooling rises, and the lime cooling air rises to the flue gas channel 14 to be mixed with combustion flue gas and enters the kiln chamber which is storing heat. The mixed gas and limestone directly carry out heat exchange, and the temperature is reduced to about 160-180 ℃ after heat energy is transferred to the limestone and then the limestone is discharged by a waste gas discharge system. An annular channel 6 is formed between the annular suspension cylinder type furnace wall 11 and the outer furnace wall, so that flue gas generated by combustion in one period can uniformly enter the annular channel 6 and uniformly enter the other kiln chamber through a flue gas channel 14 connecting the two kiln chambers.

After being pressurized by a high-pressure fan in the structural cooling air system, the air enters a cooling air circulation cavity of a steel structure jacket of the annular suspended cylinder type furnace wall, and after the steel structure jacket is cooled, the air enters an air supply system to be used as combustion-supporting air to participate in combustion.

Claims (9)

1. A suspended cylinder type parallel-flow heat storage double-chamber kiln comprises a double-chamber kiln body, a feeding device, a discharging device, an air supply system, a structural cooling air system and a waste gas discharge system (18), wherein the double-chamber kiln body is composed of an inner furnace wall (5) positioned at the upper part and an outer furnace wall (7) positioned at the lower part, the inner furnace wall is suspended on the outer furnace wall, and a preheating zone (19), a calcining zone (20) and a cooling zone (16) are arranged in the double-chamber kiln body; the double-chamber kiln body comprises a kiln chamber A and a kiln chamber B, the upper parts of the kiln chamber A and the kiln chamber B are respectively provided with an air inlet and outlet (4), and the air inlet and outlet are connected with an air blower (2) and a waste gas discharge system (18) through a three-way valve (12); the calcining zone is provided with a combustor (13), the cooling zone is provided with a cooling air inlet (9), the lower part of the cooling zone is provided with a discharge hole (10), the discharge hole is connected with a discharge device, and the cooling air inlet is connected with a cooling fan (17) through a three-way valve; the method is characterized in that: the lower part of the inner furnace wall (5) is provided with an annular suspension cylinder type furnace wall (11), and the annular suspension cylinder type furnace wall (11) is suspended in the kiln; the annular suspension cylinder type furnace wall (11) is composed of a steel structure jacket (23), an inner pouring layer (22) and an outer pouring layer (29), and a cooling air circulation cavity (28) is formed inside the steel structure jacket; the cooling air circulation cavity is provided with a structure cooling air inlet (26) and a structure cooling air outlet (27), the structure cooling air inlet (26) is connected with a structure cooling air system through a pipeline, and the structure cooling air outlet (27) is connected with a combustion-supporting air pipeline through a pipeline.

2. The hanging cylinder co-current thermal storage dual-chamber kiln as claimed in claim 1, wherein: the outer pouring layer (29) completely covers the outer side of the annular suspension cylinder type furnace wall (11); the inner casting layer (22) covers the inner side of the annular suspension cylinder type furnace wall (11) completely or partially from bottom to top.

3. The hanging cylinder co-current thermal storage dual-chamber kiln as claimed in claim 2, wherein: when the inner casting layer (22) partially covers the inner side of the annular suspension cylinder type furnace wall (11), the rest part of the inner side of the annular suspension cylinder type furnace wall (11) is built by using refractory bricks.

4. The hanging cylinder co-current thermal storage dual-chamber kiln as claimed in claim 1, wherein: the connection part of the annular suspension cylinder type furnace wall (11) and the inner furnace wall (5) is provided with refractory fibers (21); the steel structure jacket (23) is provided with a supporting structure (25), two sides of the steel structure jacket (23) are provided with anchoring pieces (24), and the anchoring pieces are embedded into the inner pouring layer (22) or the outer pouring layer (29).

5. The hanging cylinder co-current thermal storage dual-hearth kiln according to claim 4, the anchor (24) comprising a fixing member (241) connected with the steel structural jacket (23), and an extension member (242) connected with the fixing member (241); the top of the extension piece (242) is provided with two or more branch pieces (243).

6. The hanging cylinder co-current thermal storage dual-chamber kiln as claimed in claim 1, wherein: an annular channel (6) is arranged between the annular suspension cylinder type furnace wall (11) and the outer furnace wall (7).

7. The hanging cylinder co-current thermal storage dual-chamber kiln as claimed in claim 1, wherein: the steel structure jacket (23) in the annular suspension cylinder type furnace wall (11) is of a segmented structure, and each segment of the steel structure jacket (23) is provided with a structure cooling air inlet (26) and a structure cooling air outlet (27); the steel structure jacket (23) is at least divided into 1 section.

8. The hanging cylinder co-current thermal storage dual-chamber kiln as claimed in claim 1, wherein: the inner casting layer (22) and the outer casting layer (29) include, but are not limited to, casting using high alumina and magnesia refractory concretes.

9. The hanging cylinder co-current thermal storage dual-chamber kiln as claimed in claim 1, wherein: the burner (13) is an insertion burner, a combustion beam or a peripheral burner; the inserted burner is a gas fuel burner, a liquid fuel burner or a solid fuel burner.

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