CN107796229B - Movable tank type cooler and sinter cooling method - Google Patents

Abstract

A mobile can cooler, the cooler comprising: 1) an annular groove-shaped cooling bin; 2) the driving device drives the annular groove-shaped cooling bin to move; 3) the annular hot air cover is arranged on the annular groove-shaped cooling bin; 4) at least one hot air collecting pipe connected with the top or side of the hot air cover; 5) the cooling air duct is arranged on the outer side of the annular groove-shaped cooling bin and comprises a cooling air duct moving seat and a cooling air duct fixing cover; 6) the annular rotary rack is arranged at the bottoms of the annular groove-shaped cooling bin and the cooling air duct, and an air passing beam is arranged in the annular rotary rack in a hollow manner; 7) the ore discharge hopper is arranged at the lower part of the annular groove-shaped cooling bin; 8) the air outlets of the cooling fans are communicated to the cooling air duct through the corresponding cooling air pipes respectively; 9) and the cooling air communicating pipe is arranged between the cooling air channel moving seat and the annular rotary table frame. The invention eliminates all air leakage links, ensures the good sealing performance of the cooling of the movable tank and greatly improves the waste heat recovery.

Description

Movable tank type cooler and sinter cooling method

Technical Field

The invention belongs to the field of iron making and the field of environmental protection, and particularly relates to a movable tank type cooler and a sinter cooling method.

Background

Before the powdered iron ore concentrate powder enters a blast furnace, agglomeration treatment must be carried out, and a sintering process is a main process for iron ore agglomeration in the steel industry. The discharging temperature of the sinter is generally 600-700 ℃, the hot ore enters a raw material bin for standby after being cooled, and the temperature of the cooled sinter is not more than 150 ℃. Because the output of the sinter is huge, the annual iron yield in China is calculated according to 8 hundred million tons, the sinter needs to be produced by more than 17 hundred million tons all year round, and therefore, the heat energy released in the cooling process of the sinter is considerable.

At the end of the last century, with the development of technology and the progress of industrial policy, enterprises take measures to recycle heat energy in sintered hot ores. At present, the main technology for recovering the heat energy of the sintered ore is a waste heat power generation technology, and the specific method is to collect hot air exhausted from a high-temperature section and a medium-temperature section of a circular cooler for power generation.

The sinter is cooled by a ring cooler commonly known as a ring cooler. The use of the circular cooler starts in the 80 th century, and in view of the current technical level and industrial policy, the circular cooler only considers the cooling performance of the circular cooler on hot ores and does not consider the protection and utilization of the heat energy in the hot ores, and because of this, the waste heat which can be recovered by the existing sintered ore waste heat recovery technology based on the circular cooler cannot be 40% of the total sensible heat in the sintered ores, and a large amount of heat energy cannot be utilized.

In recent years, under the guidance of new national industrial policies of energy conservation, emission reduction and green production, the pressure of energy conservation, emission reduction, cost reduction and efficiency improvement of enterprises is getting larger, the industry pays more and more attention to the efficient utilization of the waste heat of the sinter, and the improvement and innovation of the sinter cooling technology and equipment are also driven, so that the tank type cooler is the new sinter cooling technology appearing under the background.

The pot cooling technology of the sintering industry is derived from the dry quenching technology of the coking industry. Because of the combustibility of coke, the hot coke discharged from a coke oven must be cooled in a completely closed environment, which is achieved by dry-quenching ovens of the coking industry.

The dry quenching furnace is a barrel-shaped tank body, the upper part of the dry quenching furnace is provided with a feeding port and a hot air outlet, and the lower part of the dry quenching furnace is provided with a discharging port and a cold machine inlet. The red coke from the coke-making machine is poured into the dry quenching furnace through a charging port by a lifter, a cooling air inlet at the lower part of the nitrogen dry quenching furnace for cooling is introduced into the dry quenching furnace, heat exchange is completed between the red coke and the dry quenching furnace, hot air which obtains heat is discharged from an air outlet at the upper part of the dry quenching furnace, and the cooled coke is discharged from a discharge port at the lower part of the dry quenching furnace.

The dry quenching furnace has the characteristics of good sealing performance and less heat loss, and more than 80 percent of sensible heat can be recycled. Because of this, in recent years, the dry quenching technology has gained more and more attention in the steel industry. However, the output of the sintering machine per unit time is much larger than that of the coke oven, so that the single-tank structure adopted by the dry quenching furnace is difficult to realize the cooling of the sintered ore. The reason is that the capacity limit of the single-tank structure cannot meet the huge yield requirement of the sintering machine.

Disclosure of Invention

In order to solve the problems of the prior art, the invention aims to provide a mobile tank type cooler. On the premise of inheriting the advantages of the dry quenching furnace, the provided mobile pot type scheme can meet the process requirements of cooling the sinter.

According to a first embodiment provided by the present invention, there is provided a mobile can cooler, including:

1) an annular groove-shaped cooling bin for accumulating the sintered ore from the sintering machine from the upper part;

2) the driving device is used for driving the annular groove-shaped cooling bin to do rotary motion in the horizontal direction or on the horizontal plane;

3) the annular hot air cover is arranged on the annular groove-shaped cooling bin and covers the upper part of the annular groove-shaped cooling bin;

4) at least one hot air collecting pipe (for example, 1-10, 2-6 or 3-4) connected with the top or the side of the hot air hood;

5) the cooling air duct (annular or full-circle annular) is arranged at the outer side of the annular groove-shaped cooling bin, wherein the cooling air duct comprises a cooling air duct moving seat arranged at the lower part and a cooling air duct fixing cover covering the upper part of the cooling air duct moving seat;

6) the annular rotary table frame is arranged at the bottoms of the annular groove-shaped cooling bin and the cooling air duct, the annular groove-shaped cooling bin is supported on the annular rotary table frame, and the cooling air duct moving seat is fixed on the annular rotary table frame, wherein the annular rotary table frame is provided with a hollow air passing beam;

7) the ore discharge hopper is arranged at the lower part of the annular groove-shaped cooling bin;

8) the air outlets of the cooling fans are communicated to a cooling air duct (of a whole circle of annular shape) through the corresponding cooling air pipes respectively;

9) the cooling air communicating pipe is arranged between the cooling air channel moving seat and the annular rotary rack, the cooling air channel is communicated with a hollow air passing beam arranged in the annular rotary rack through the cooling air communicating pipe, and the interior of the air passing beam is communicated with the bottom of the annular groove-shaped cooling bin;

10) the second ore discharging device is arranged at the tail end of the ore discharging pipe. Preferably, the second discharge apparatus is an ore discharge apparatus having a discharge gate (i.e., a second discharge gate) with a weight, which is lifted by the lifting rail.

In the present application, the hot air hood is fixedly mounted on the support frame, and the cooling air duct fixing hood is suspended on the support frame. The annular groove-shaped cooling bin, the cooling air duct moving seat and the annular rotary table frame perform rotary motion together.

Preferably, the cooling machine includes: 6) the annular rotary rack is arranged at the bottoms of the annular groove-shaped cooling bin and the cooling air duct on the rotary circumference (direction) of the annular groove-shaped cooling bin, the annular groove-shaped cooling bin is supported on the annular rotary rack, and the cooling air duct moving seat is fixed on the annular rotary rack which is provided with a hollow air passing beam;

preferably, the cooling machine includes: 7) the ore discharge hoppers are arranged at the lower part of the annular groove-shaped cooling bin at equal intervals or unequal intervals on the rotation circumference (direction) of the annular groove-shaped cooling bin.

Preferably, liquid seal grooves (annular or full-circle annular) are respectively arranged on two sides of the cooling air duct moving seat. Two side walls (of a whole ring shape) of the cooling air duct fixing cover are inserted into the cooling air duct liquid seal groove.

In this application, "full ring" refers to the circumference of revolution of the annular trough-shaped cooling bin.

In the present application, "disposed outside the ring-groove-shaped cooling bin" in the "cooling air duct (annular or full-circle annular) disposed outside the ring-groove-shaped cooling bin" means that the cooling air duct (annular or full-circle annular) is located outside the ring of the ring-groove-shaped cooling bin.

Like the annular groove-shaped cooling bin, the annular rotary table frame is also in a full-circle annular shape or a full-circle continuous annular shape.

In the present application, the ring-shaped cooling silos of the cooler make a revolution along their circumference of revolution (or circumference of revolution). The circumference of revolution or circumference of revolution (2 π R) of the cooling silos in the form of a ring groove is generally in the range from 40 to 350 m, preferably from 45 to 340 m, preferably from 48 to 335 m, preferably from 50 to 330 m, preferably from 55 to 320 m, preferably from 60 to 310 m, preferably from 70 to 300 m, preferably from 80 to 280 m, more preferably from 90 to 250 m, for example from 100 to 200 m.

The height of the ring-shaped cooling bin of the cooler, i.e. the height of the bottom of the mine discharge hopper to the upper edge of the ring-shaped cooling bin, is 1.5-7.0 meters, preferably 1.8-6.8 meters, preferably 2-6.7 meters, preferably 2.2-6.5 meters, preferably 2.5-6 meters, more preferably 3-5.5 meters, more preferably 3.5-5 meters, e.g. 4 meters.

In this application, the cooling bin of the ring groove shape can also adopt a partition plate to divide the whole cooling bin of the ring groove shape into a plurality of sub-bins, and at least one ore discharge hopper is arranged below each sub-bin. The partition has a certain height, for example 1/2 to 2/3, up to the height of the interior space of the cooling silo.

In the present application, the cooling machine further includes: the ore discharging device comprises an ore discharging pipe arranged below the ore discharging hopper and communicated with the ore discharging hopper, and an ore discharging device arranged at the tail end of the ore discharging pipe.

In this application, ore discharge device is first ore discharge device, and the latter includes hinge, first control wheel, the track of unloading, first counter weight and first discharge door, and wherein the track of unloading is installed in the district of unloading, is received the top of material belt, and first discharge door passes through the hinge mount on ore discharge pipe, and first control wheel is installed in the middle part of first discharge door, and first counter weight setting is in the lower part of first discharge door.

In this application, the ore discharging device is the second ore discharging device, and the latter is including hanging the seat, hang the cover, the second control wheel, prevent stifled groove, the lifting track, second counter weight and second discharge door, and wherein the lifting track sets up in the exit of the district section of unloading, and the entrance of the district section of unloading is provided with and bumps the piece, and the vertical setting of second discharge door is on the orificial lower border of ore discharge pipe, and the seat of hanging is installed at the orificial last border of ore discharge pipe, and it sets up on second discharge door upper portion to hang the cover, and the middle part at the second discharge door is installed to the second control wheel, and the second counter weight setting is in the lower part of second discharge door, prevent stifled groove setting on ore discharge pipe, be located the front end of hanging.

In the present application, the cooling machine further includes: the feeding hopper is arranged at the upper part of the annular groove-shaped cooling bin, and the feeding chute is arranged above the inside of the annular groove-shaped cooling bin, wherein the feeding hopper is communicated with the feeding chute.

Preferably, the cooling machine further includes: and the hot air cover sealing device is arranged between the annular groove-shaped cooling bin and the hot air cover.

In this application, as the driving means, a wheel-rail driving means may be adopted, in which bearing rails are respectively installed at both lower portions of the ring-shaped cooling compartment, and bearing wheels for supporting the rails are installed on a bracket of the cooling machine, the bearing wheels including power wheels and driven wheels. The power wheel is driven by a motor. For example, the driving device includes the following wheel-rail driving devices: and a rotary table frame supporting rail and a rotary table frame supporting wheel are arranged at the lower part of the annular rotary table frame. In addition, the side part of the annular rotary table frame is provided with a rotary table frame side retaining wheel and a rotary table frame side retaining rail. These support wheels include power wheels and driven wheels. The support wheels are mounted on the brackets and support frame of the cooler stand.

Further, as the driving device, a friction wheel driving device may be adopted. The friction wheel driving device is arranged on the outer side or the inner side of the box body of the annular groove-shaped cooling bin, or the friction wheel driving device is arranged on the outer side and the inner side simultaneously. Such friction wheel drives are known from the prior art.

In addition, a magnetic lifting device may be used as the driving device. Such magnetic lifting devices are known in the art.

In the invention, the lower part of the hot air cover is provided with a hot air cover bracket, and the lower part of the hot air collecting pipe is provided with a hot air collecting pipe bracket.

In the invention, the hot air collecting pipe is communicated to a waste heat utilization device, such as a waste heat power generation device.

An air inlet cap is arranged at the middle lower part of the inner space of the annular groove-shaped cooling bin and above the ore discharge hopper. And the air inlet of the air inlet cap is communicated with the inside of the air passing beam.

According to a second embodiment of the present invention, there is provided a method for cooling sintered ore using the above-described cooling machine, the method comprising: 1) loading the high-temperature sintered ore unloaded from the sintering machine into an annular groove-shaped cooling bin of a movable tank type cooler through a feed hopper; 2) the cooling air pipe sends cooling air of the cooling fan to the cooling air duct; 3) the cooling air communicating pipe leads cooling air in the cooling air duct into a hollow air passing beam of the annular rotary rack, and the air passing beam leads the cooling air into the annular groove-shaped cooling bin; 4) the annular groove-shaped cooling bin and the cooling air duct moving seat perform rotary motion along with the annular rotary table frame, and introduced cooling air performs gas-solid heat exchange with the hot sinter; 5) after gas-solid heat exchange is completed, hot ore is changed into cold ore, cooling air is changed into hot air, wherein the cold ore is discharged from the first ore discharging device through an ore discharging hopper, and the hot air is conveyed to a waste heat utilization device, such as a waste heat power generation device, through a hot air collecting pipe.

In the invention, the operation state of the first ore discharging device is specifically as follows: when the cold ore is not discharged, the first discharging door is tightly attached to the opening of the ore discharge pipe under the action of the first balance weight, so that the cold ore in the ore discharge pipe is blocked and cannot be discharged; after the first discharging door enters the discharging section along with the ore discharging pipe, the first control wheel arranged in the middle of the first discharging door is in contact with the discharging track, rolls along the discharging track and lifts up the first discharging door gradually, and when an opening between the ore discharging pipe and the first discharging door is large enough, cold ore in the ore discharging pipe is discharged from the opening and falls into the receiving belt, so that the discharging purpose of the cold ore is realized.

According to a third embodiment provided by the present invention, there is provided a method for cooling sintered ore, the method including: 1) loading the high-temperature sintered ore unloaded from the sintering machine into an annular groove-shaped cooling bin of a movable tank type cooler through a feed hopper; 2) the cooling air pipe sends cooling air of the cooling fan to the cooling air duct; 3) the cooling air communicating pipe leads cooling air in the cooling air duct into a hollow air passing beam of the annular rotary rack, and the air passing beam leads the cooling air into the annular groove-shaped cooling bin; 4) the annular groove-shaped cooling bin and the cooling air duct moving seat perform rotary motion along with the annular rotary table frame, and introduced cooling air performs gas-solid heat exchange with the hot sinter; 5) after the gas-solid heat exchange is finished, the hot ore is changed into cold ore, the cooling air is changed into hot air, wherein the cold ore is discharged from the second ore discharging device through an ore discharging hopper, and the hot air is conveyed to a waste heat utilization device, such as a waste heat power generation device, through a hot air collecting pipe.

The operation state of the second ore discharging device is specifically as follows: when the material is not discharged, the second discharging door is hung on the hanging seat through a hanging sleeve arranged on the second discharging door, and the hanging seat supports the weight of the second discharging door through the hanging sleeve so that the second discharging door is in a closed state; after the second discharging door enters the discharging section, the collision block at the inlet of the discharging section firstly contacts with the hanging seat and collides the hanging seat, the second discharging door loses the support of the hanging seat, slides downwards under the action of a second counterweight arranged on the second discharging door, and is opened to enter a discharging state; the second discharge door continues to run along with the ore discharge pipe, when the second discharge door leaves the discharge area, the second control wheel arranged on the second discharge door is in contact with the lifting track at the outlet of the discharge area, the second control wheel rolls along the lifting track and gradually lifts the second discharge door, after the second discharge door is lifted to a certain height, the hanging seat arranged on the ore discharge pipe is jacked open by the hanging sleeve arranged on the second discharge door, the hanging seat and the hanging sleeve are automatically occluded and locked, and the second discharge door enters a closed state, so that the operation is reciprocating.

In the present invention, there is no particular requirement for the design of the driving means for driving the ring-shaped cooling chamber to make a revolving motion in the horizontal direction, and for example, a wheel-rail driving means, a friction wheel driving means, a magnetic lifting, etc. may be used.

In the present invention, the hot air hood is connected with at least one hot air collecting pipe at the top or the side, which means that a plurality of hot air collecting pipes can be arranged, such as 1-10, 2-6 or 3-4. The number of the cooling air communicating pipes is the same as that of the annular rotary table frame or the air passing beam. The ore discharge hoppers are arranged at the lower part of the annular groove-shaped cooling bin at equal intervals or unequal intervals, which means that the ore discharge hoppers can be arranged in plurality, and the distances among the ore discharge hoppers along the direction of the rotation circumference can be equal or unequal.

In the invention, the cooling air duct is arranged on one side of the annular groove-shaped cooling bin, which means that the annular groove-shaped cooling bin can be arranged on the outer side of the cooling air duct and also can be arranged on the inner side of the cooling air duct. Correspondingly, the cooling air duct can be arranged on the inner side of the annular groove-shaped cooling bin and also can be arranged on the outer side of the annular groove-shaped cooling bin.

In the invention, the high-temperature sintered ore discharged from the sintering machine is loaded into the annular groove-shaped cooling bin of the movable tank type cooler through the feed hopper. The annular groove-shaped cooling bin is supported on the annular rotary table frame, the cooling air duct moving seat is fixed on the annular rotary table frame, the hollow air passing beam is arranged in the annular rotary table frame, and the annular groove-shaped cooling bin and the cooling air duct moving seat perform rotary motion along with the annular rotary table frame, namely, relative motion does not exist among the annular groove-shaped cooling bin, the cooling air duct and the air passing beam, so that the sealing performance in the cooling process is ensured. The whole feeding process is continuous, and the feeding hoppers can be arranged in a plurality according to requirements. And a cooling air duct liquid seal groove is also arranged between the cooling air duct moving seat and the cooling air duct fixing cover, so that the sealing property of the cooling air duct is ensured.

In the invention, the annular groove-shaped cooling bin makes rotary motion, and the unloading section is arranged according to experience and the requirements of subsequent processes. Wherein the discharge rail of the first ore discharging device is arranged above the discharge section and the receiving belt. The lifting track of the second ore discharging device is arranged at the outlet of the discharging section, and the inlet of the discharging section is provided with a collision block. An anti-blocking groove is arranged in the second ore discharging device. The function of the anti-blocking groove is to prevent the second discharge door from being blocked by massive materials in the rising process.

The invention can be divided into three functional blocks, namely a solid-state flow processing functional block taking an annular groove-shaped cooling bin as a main component, a gaseous flow processing functional block taking a cooling air duct as a main component and a gaseous flow and solid flow communication functional module taking a cooling air communication pipe as a main component. The three functional blocks act together to realize the heat exchange between the high-temperature solid medium and the low-temperature gaseous medium, thereby achieving the purposes of cooling the solid medium and collecting the waste heat.

Compared with the prior art, the invention has the beneficial effects that:

1. the movable tank type cooler cancels a trolley structure of a ring type cooler, adopts a controllable progressive discharging mode, and a static sealing structure of the ring type cooler is replaced by a continuous structural welding line, so that structural factors causing air leakage in the cooling process are eliminated; cooling air is introduced from the interior of the annular groove-shaped cooling bin, and air leakage does not exist in the air inducing process; the cooling air duct of the movable tank type cooler is a complete continuous annular air duct, the end sealing of the liquid sealing annular cooler is cancelled, and the flow field in the cooling air duct is uniform and stable; the cooling bin of the movable tank type cooler is a continuous and complete annular tank-shaped accumulation box body, and cooling air or hot air cannot leak due to discontinuous gaps in the cooling bin in the heat exchange process; the cooling air and the hot mine are connected through the air passing beam with the closed inner part, and the air passing beam and the annular groove-shaped cooling bin do not move relatively.

2. The lower part of the annular groove-shaped cooling bin of the movable tank type cooler is uniformly provided with a plurality of ore discharge hoppers, the upper parts of the ore discharge hoppers are horn-shaped, the sintered ore is collected into the ore discharge hoppers after being cooled by the annular groove-shaped cooling bin and is discharged by the ore discharge pipes, and the ore materials in the ore discharge pipes also play a role in material sealing. The mouth of pipe department of ore discharge pipe is provided with ore discharging device, opens by oneself when unloading the door and getting into the district section of unloading, closes by oneself when leaving the district section of unloading for whole simple and convenient automation more of operation.

3. The movable tank type cooler adopts a cooling mode of countercurrent heat exchange and slow cooling by fine air, so that heat exchange is more sufficient, heat loss is prevented by adopting heat retention measures, and the waste heat recovery is improved by 40 percent compared with a ring type cooler.

4. The movable tank type cooler is cooled by a thick material layer, the heat thickness can reach 6m or even higher, the hot air temperature can be increased to 500-600 ℃, even 560-600 ℃, and the efficiency of a power generation system is obviously improved.

5. The movable tank type cooling machine eliminates all air leakage links, and compared with a ring type cooling machine, the movable tank type cooling machine reduces the air leakage quantity and can reduce the installed power of a fan by more than 20%.

Drawings

Fig. 1 is a structural view of a prior art dry quenching furnace.

FIG. 2 is a front view of the mobile can cooler cooling bin of the present invention on the outside.

FIG. 3 is a longitudinal section view of an annular rotary table frame with a cooling bin of a mobile tank cooler on the outer side.

FIG. 4 is a cross-sectional view of the mobile can cooler of the present invention taken along the centerline of the annular trough-shaped cooling bin.

FIG. 5 is a front view of the mobile can cooler cooling bin of the present invention on the inside.

FIG. 6 is a top view of the mobile can cooler cooling bin of the present invention on the inside.

Fig. 7 is a structural view of a first mine drainage apparatus of the mobile can cooler of the present invention.

Fig. 8 is a schematic view illustrating an operation state of a second ore discharging device of the mobile can cooler of the present invention.

FIG. 9 is a partial enlarged view of the second mine drainage device of the mobile can cooler of the present invention.

FIG. 10 is a second enlarged view of a second mine drainage device of the mobile can cooler of the present invention.

Reference numerals: 1: a cooling machine; 2: an annular groove-shaped cooling bin; 3: a drive device; 4: a hot air hood; 401: a hot air hood bracket; 5: a hot air collecting pipe; 5 a: a hot air branch pipe; 501: a hot air collecting pipe bracket; 6: a cooling air duct; 601: a cooling air duct moving seat; 602: a cooling air duct fixing cover; 603: a cooling air duct liquid seal groove; 7: an annular rotating gantry; 701: a revolving stage support rail; 702: a rotating gantry support wheel; 702 a: a bracket; 702 b: a support frame; 703: a side catch wheel of the rotary table frame; 704: a side stop rail of the rotary table frame; 8: an air-passing beam; 9: a discharge hopper; 10: a cooling fan; 11: cooling the air pipe; 12: a cooling air communicating pipe; 13: a support frame; 14: a mine drainage pipe; 15: a first mine discharge device; 1501: a hinge; 1502: a first control wheel; 1503: a discharge rail; 1504: a first counterweight; 1505: a first discharge door; 16: a second mine discharge device; 1601: hanging a seat; 1602: hanging a sleeve; 1603: a second control wheel; 1604: anti-blocking grooves; 1605: lifting the track; 1606: a second counterweight; 1607: a second discharge gate; 17: a feed hopper; 18: a feed chute; 19: a hot air cover sealing device; l: and a hot air outlet.

Detailed Description

According to a first embodiment provided by the present invention, there is provided a mobile can cooler 1 comprising:

1) an annular groove-shaped cooling bin 2 for accumulating sintered ore from a sintering machine from above;

2) the driving device 3 is used for driving the annular groove-shaped cooling bin to do rotary motion in the horizontal direction or on the horizontal plane;

3) an annular hot air cover 4 which is arranged on the annular groove-shaped cooling bin 2 and covers the upper part of the annular groove-shaped cooling bin;

4) at least one (e.g., 1 to 10, such as 2 to 6 or 2 to 4) hot air collecting pipe 5 connected to the top or side of the hot air hood 4;

5) the cooling air duct 6 (annular or complete annular) is arranged outside the annular groove-shaped cooling bin 2, wherein the cooling air duct 6 comprises a cooling air duct moving seat 601 arranged at the lower part and a cooling air duct fixing cover 602 covering the upper part of the cooling air duct moving seat 601;

6) the annular rotary table frame 7 is arranged at the bottoms of the annular groove-shaped cooling bin 2 and the cooling air duct 6, the annular groove-shaped cooling bin 2 is supported on the annular rotary table frame 7, the cooling air duct moving seat 601 is fixed on the annular rotary table frame 7, and the annular rotary table frame 7 is provided with a hollow air passing beam 8;

7) a ore discharge hopper 9 arranged at the lower part of the annular groove-shaped cooling bin;

8) the air outlets of the cooling fans 10 are communicated to the (full-circle annular) cooling air duct 6 through the corresponding cooling air pipes 11 respectively;

9) a cooling air communicating pipe 12 arranged between the cooling air duct moving seat 601 and the annular rotary table frame 7, wherein the cooling air duct 6 is communicated with a hollow air passing beam 8 arranged in the annular rotary table frame 7 through the cooling air communicating pipe 12, and the interior of the air passing beam 8 is communicated with the bottom of the annular groove-shaped cooling bin 2;

10) a mine discharging pipe 14 arranged below the mine discharging hopper 9 and communicated with the mine discharging hopper 9, and a second mine discharging device 16 arranged at the tail end of the mine discharging pipe 14. Preferably, the second discharge apparatus 16 is a kind of discharge apparatus having a discharge gate (i.e., a second discharge gate) 1607 with a weight raised and lowered by the lifting rail 1605.

Preferably, the cooling machine includes: 6) an annular rotary table frame 7 arranged at the bottoms of the annular groove-shaped cooling bin 2 and the cooling air duct 6 is arranged on the rotary circumference (direction) of the annular groove-shaped cooling bin 2, the annular groove-shaped cooling bin 2 is supported on the annular rotary table frame 7, a cooling air duct moving seat 601 is fixed on the annular rotary table frame 7, and the annular rotary table frame 7 is provided with a hollow air passing beam 8.

A plurality of hot air branch pipes 5a are arranged at the top or the upper side part of the annular groove-shaped cooling bin 2 and are respectively communicated with the hot air collecting pipe 5. The hot air collecting pipe 5 is provided with at least one hot air outlet L. The hot air is delivered to the waste heat utilization device through the hot air outlet L.

Preferably, the cooling machine includes: 7) ore discharge hoppers 9 are arranged at the lower part of the annular groove-shaped cooling bin at equal intervals or unequal intervals on the rotation circumference (direction) of the annular groove-shaped cooling bin (2).

In the present invention, the hot air cover 4 is fixedly mounted on the supporting frame 13, and the cooling air duct fixing cover 602 is suspended from the supporting frame 13. The annular groove-shaped cooling bin 2, the cooling air duct moving seat 601 and the annular rotary table frame 7 rotate together.

Preferably, cooling air duct liquid seal grooves 603 (annular or full-circle annular) are respectively arranged on both sides of the cooling air duct moving base 601. Two side walls (of a whole circle and a ring) of the cooling air duct fixing cover 602 are inserted into the cooling air duct liquid seal groove 603.

In the present invention, the cooling machine further includes: a mine discharging pipe 14 which is arranged below the mine discharging hopper 9 and communicated with the mine discharging hopper 9, and a mine discharging device which is arranged at the tail end of the mine discharging pipe 14.

In the present application, "full ring-shaped" refers to the revolution circumference of the annular groove-shaped cooling bin 2.

In the present application, "disposed outside the ring-groove-shaped cooling compartment 2" in the "cooling air duct 6 (annular or full-circle annular) disposed outside the ring-groove-shaped cooling compartment 2" means that the cooling air duct 6 (annular or full-circle annular) is located outside the ring of the ring-groove-shaped cooling compartment 2.

Like the annular trough-shaped cooling chamber 2, the annular rotary gantry 7 is also annular in a full circle or is continuous in a full circle.

In the present application, the ring-shaped cooling silos 2 of the cooler make a revolution along their circumference of revolution (or circumference of revolution). The circumference of revolution or circumference of revolution (2 π R) of the cooling silo 2 in the form of a ring channel is generally in the range from 40 to 350 m, preferably from 45 to 340 m, preferably from 48 to 335 m, preferably from 50 to 330 m, preferably from 55 to 320 m, preferably from 60 to 310 m, preferably from 70 to 300 m, preferably from 80 to 280 m, more preferably from 90 to 250 m, for example from 100 to 200 m.

The height of the ring-shaped cooling bin 2 of the cooler, i.e. the height of the bottom of the mine discharge hopper to the upper edge of the ring-shaped cooling bin, is 1.5-7.0 meters, preferably 1.8-6.8 meters, preferably 2-6.7 meters, preferably 2.2-6.5 meters, preferably 2.5-6 meters, more preferably 3-5.5 meters, more preferably 3.5-5 meters, e.g. 4 meters.

In the present invention, the discharge device is a first discharge device 15 comprising a hinge 1501, a first control wheel 1502, a discharge rail 1503 mounted above the discharge section, receiving belt, a first counterweight 1504 and a first discharge gate 1505, wherein the first discharge gate 1505 is mounted on the discharge pipe 14 via the hinge 1501, the first control wheel 1502 is mounted in the middle of the first discharge gate 1505, and the first counterweight 1504 is disposed below the first discharge gate 1505.

In the invention, the ore discharging device is a second ore discharging device 16, which comprises a hanging seat 1601, a hanging sleeve 1602, a second control wheel 1603, an anti-blocking slot 1604, a lifting rail 1605, a second counterweight 1606 and a second discharging door 1607, wherein the lifting rail 1605 is arranged at the outlet of the discharging section, a collision block (not shown in the figure) is arranged at the inlet of the discharging section, the second discharging door 1607 is vertically arranged at the lower edge of the orifice of the ore discharging pipe 14, the hanging seat 1601 is arranged at the upper edge of the orifice of the ore discharging pipe 14, the hanging sleeve 1602 is arranged at the upper part of the second discharging door 1607, the second control wheel 1603 is arranged at the middle part of the second discharging door 1607, the second counterweight 1606 is arranged at the lower part of the second discharging door 1607, and the anti-blocking slot 1604 is arranged on the ore discharging pipe 14 and is positioned at the front end of the hanging seat 1601.

In the present invention, the cooling machine further includes: a feed hopper 17 arranged at the upper part of the ring groove-shaped cooling bin 2 and a feeding chute 18 arranged at the upper part inside the ring groove-shaped cooling bin 2, wherein the feed hopper 17 is communicated with the feeding chute 18.

Preferably, the cooling machine further includes: and the hot air cover sealing device 19 is arranged between the annular groove-shaped cooling bin 2 and the hot air cover 4. In the present invention, as the driving means 3, a wheel-rail driving means may be adopted in which support rails are respectively installed at both lower portions of the ring-shaped cooling compartment 2, and support wheels for supporting the rails are installed on the support frame 13, the support wheels including power wheels and driven wheels. The power wheel is driven by a motor. The drive device 3 includes, for example, the following wheel-rail drive devices: a revolving stage support rail 701 and a revolving stage support wheel 702 are provided on the lower portion of the annular revolving stage 7. Further, a rotary table side catch wheel 703 and a rotary table side catch rail 704 are provided on the side of the annular rotary table 7. The support wheels 702 include power wheels and driven wheels. The support wheels 702 are mounted on the brackets 702a and the support frame 702b of the support frame 13.

Further, as the driving device 3, a friction wheel driving device may be adopted. The friction wheel driving device is arranged at the outer side or the inner side of the box body of the annular groove type cooling bin 2, or the friction wheel driving device is arranged at the outer side and the inner side simultaneously. Such friction wheel drives are known from the prior art.

Further, a magnetic lifting device may be used for the driving device 3. Such magnetic lifting devices are known in the art.

In the present invention, a hot air hood bracket 401 is provided at the lower part of the hot air hood 4, and a hot air collecting pipe bracket 501 is provided at the lower part of the hot air collecting pipe 5.

In the invention, the hot air collecting pipe 5 is communicated to a waste heat utilization device, such as a waste heat power generation device.

An air inlet cap is arranged at the middle lower part of the inner space of the annular groove-shaped cooling bin 2 and above the ore discharge hopper 9. The air inlet of the air inlet cap is communicated with the inside of the air passing beam 8.

According to a second embodiment provided by the present invention, there is provided a method for cooling sintered ore, the method including: 1) loading the high-temperature sintered ore unloaded from the sintering machine into an annular groove-shaped cooling bin 2 of a movable tank type cooler 1 through a feed hopper 17; 2) the cooling air duct 11 sends cooling air of the cooling fan 10 to the cooling air duct 6; 3) the cooling air communicating pipe 12 introduces the cooling air in the cooling air duct 6 into the hollow air passing beam 8 of the annular rotary table frame 7, and the air passing beam 8 introduces the cooling air into the annular groove-shaped cooling bin 2; 4) the annular groove-shaped cooling bin 2 and the cooling air duct moving seat 601 perform rotary motion along with the annular rotary table frame 7, and introduced cooling air performs gas-solid heat exchange with the hot sintering ore; 5) after gas-solid heat exchange is completed, hot ore is changed into cold ore, cooling air is changed into hot air, wherein the cold ore is discharged from the first ore discharging device 15 through the ore discharging hopper 9, and the hot air is sent to a waste heat utilization device, such as a waste heat power generation device, through the hot air collecting pipe 5.

In the present invention, the operation state of the first ore discharging device 15 is specifically as follows: when the cold ore is not discharged, the first discharging door 1505 is tightly attached to the nozzle of the ore discharging pipe 14 under the action of the first counterweight 1504, and the cold ore in the ore discharging pipe 14 is blocked and cannot be discharged; after the first discharge gate 1505 enters the discharge section along the ore discharge pipe 14, the first control wheel 1502 installed at the middle part of the first discharge gate 1505 contacts with the discharge track 1503, rolls along the discharge track 1503 and gradually lifts up the first discharge gate 1505, when the opening between the ore discharge pipe 14 and the first discharge gate 1505 is large enough, the cold ore in the ore discharge pipe 14 is discharged from the opening and falls into the receiving belt, and the purpose of discharging the cold ore is achieved.

According to a third embodiment provided by the present invention, there is provided a method for cooling sintered ore, the method including: 1) loading the high-temperature sintered ore unloaded from the sintering machine into an annular groove-shaped cooling bin 2 of a movable tank type cooler 1 through a feed hopper 17; 2) the cooling air duct 11 sends cooling air of the cooling fan 10 to the cooling air duct 6; 3) the cooling air communicating pipe 12 introduces the cooling air in the cooling air duct 6 into the hollow air passing beam 8 of the annular rotary table frame 7, and the air passing beam 8 introduces the cooling air into the annular groove-shaped cooling bin 2; 4) the annular groove-shaped cooling bin 2 and the cooling air duct moving seat 601 perform rotary motion along with the annular rotary table frame 7, and introduced cooling air performs gas-solid heat exchange with the hot sintering ore; 5) after the gas-solid heat exchange is finished, the hot ore is changed into cold ore, the cooling air is changed into hot air, wherein the cold ore is discharged from the second ore discharging device 16 through the ore discharging hopper 9, and the hot air is sent to a waste heat utilization device, such as a waste heat power generation device, through the hot air collecting pipe 5.

The operation state of the second ore discharging device 16 is specifically: when the discharging is not performed, the second discharging door 1607 is hung on the hanging seat 1601 through the hanging sleeve 1602 arranged on the second discharging door 1607, and the hanging seat 1601 supports the weight of the second discharging door 1607 through the hanging sleeve 1602, so that the second discharging door 1607 is in a closed state; after the second discharge door 1607 enters the discharge section, the collision block at the inlet of the discharge section firstly contacts with the hanging seat 1601 and collides the hanging seat 1601, the second discharge door 1607 loses the support of the hanging seat 1601, slides downwards under the action of a second counterweight 1606 arranged on the second discharge door 1607, the second discharge door 1607 is opened, and enters a discharge state; the second discharge door 1607 continues to move along with the ore discharge pipe 14, when leaving the discharge area, the second control wheel 1603 arranged on the second discharge door 1607 contacts with the lifting rail 1605 at the outlet of the discharge area, the second control wheel 1603 rolls along the lifting rail 1605, and the second discharge door 1607 is gradually lifted up, after the second discharge door 1607 is lifted to a certain height, the hanging seat 1601 arranged on the second discharge door 1607 is ejected to the hanging seat 1601 arranged on the ore discharge pipe 14 by the hanging seat 1601 and the hanging seat 1602 are automatically locked in an engaged mode, the second discharge door 1607 enters a closed state, and the operation is repeated in this way.

Example 1

Referring to fig. 2, 3 and 4, a mobile can cooler 1 includes: an annular groove-shaped cooling bin 2 for accumulating the sinter from a sintering machine from the upper part, wherein the upper part of the annular groove-shaped cooling bin 2 is provided with a feed hopper 17, the upper part inside the annular groove-shaped cooling bin 2 is provided with a feeding chute 18, and the feed hopper 17 is communicated with the feeding chute 18; the driving device 3 is used for driving the annular groove-shaped cooling bin to do rotary motion in the horizontal direction; an annular hot air cover 4 is arranged on the annular cooling bin and covers the upper part of the annular cooling bin, and a hot air cover sealing device 19 is arranged between the annular cooling bin 2 and the hot air cover 4; 4 hot air collecting pipes 5 connected with the top of the hot air cover 4, wherein the hot air collecting pipes 5 are connected with a waste heat power generation device; the cooling air duct 6 is arranged on the inner side of the annular groove-shaped cooling bin 2, wherein the cooling air duct 6 comprises a cooling air duct moving seat 601 arranged at the lower part and a cooling air duct fixing cover 602 covering the upper part of the cooling air duct moving seat 601; the annular rotary table frame 7 is equidistantly arranged at the bottoms of the annular groove-shaped cooling bin 2 and the cooling air duct 6, the annular groove-shaped cooling bin 2 is supported on the annular rotary table frame 7, the cooling air duct moving seat 601 is fixed on the annular rotary table frame 7, and the annular rotary table frame 7 is provided with a hollow air passing beam 8; the ore discharge hoppers 9 are equidistantly arranged at the lower part of the annular groove-shaped cooling bin, and the ore discharge pipes 14 are arranged below the ore discharge hoppers 9 and are communicated with the ore discharge hoppers 9; the air outlets of the cooling fans 10 are communicated to the cooling air duct 6 through the corresponding cooling air pipes 11 respectively; and a cooling air communicating pipe 12 arranged between the cooling air duct moving seat 601 and the annular rotary table frame 7, wherein the cooling air duct 6 is communicated with a hollow air passing beam 8 arranged in the annular rotary table frame 7 through the cooling air communicating pipe 12, and the air passing beam 8 is internally communicated with the bottom of the annular groove-shaped cooling bin 2. The hot air cover 4 is fixedly arranged on the supporting frame 13, the cooling air duct fixing cover 602 is suspended on the supporting frame 13, and the annular groove-shaped cooling bin 2 rotates together with the cooling air duct moving seat 601 and the annular rotating table frame 7. A cooling air duct liquid seal groove 603 is arranged between the cooling air duct moving base 601 and the cooling air duct fixing cover 602.

As shown in fig. 7, the cooling machine further includes a first mine drainage device 15 provided at the end of the mine drainage pipe 14. The first ore discharging device 15 comprises a hinge 1501, a first control wheel 1502, a discharging track 1503, a first counterweight 1504 and a first discharging door 1505, wherein the discharging track 1503 is installed above a discharging section and a receiving belt, the first discharging door 1505 is installed on the ore discharging pipe 14 through the hinge 1501, the first control wheel 1502 is installed in the middle of the first discharging door 1505, and the first counterweight 1504 is arranged at the lower part of the first discharging door 1505.

Example 2

As shown in fig. 5 and 6, embodiment 1 is repeated except that the cooling air duct 6 is disposed outside the loop-shaped cooling compartment 2.

Example 3

Example 1 was repeated except that the first mine drainage arrangement 15 was replaced with the second mine drainage arrangement 16. As shown in fig. 8, the second ore discharging device 16 includes a hanging seat 1601, a hanging sleeve 1602, a second control wheel 1603, an anti-blocking slot 1604, a lifting rail 1605, a second counterweight 1606 and a second discharging door 1607, wherein the lifting rail 1605 is disposed at an outlet of a discharging section, a collision block is disposed at an inlet of the discharging section, the second discharging door 1607 is vertically disposed at a lower edge of a nozzle of the ore discharging pipe 14, the hanging seat is mounted at an upper edge of the nozzle of the ore discharging pipe 14, the hanging sleeve 1602 is disposed at an upper portion of the second discharging door 1607, the second control wheel 1603 is mounted at a middle portion of the second discharging door 1607, the second counterweight 1606 is disposed at a lower portion of the second discharging door 1607, and the anti-blocking slot 1604 is disposed on the ore discharging pipe 14 and located at a front end of the hanging seat 1601.

Example 4

A method for cooling sintered ore using the apparatus of example 1, comprising: 1) loading the high-temperature sintered ore unloaded from the sintering machine into an annular groove-shaped cooling bin 2 of a movable tank type cooler 1 through a feed hopper 17; 2) the cooling air duct 11 sends cooling air of the cooling fan 10 to the cooling air duct 6; 3) the cooling air communicating pipe 12 introduces the cooling air in the cooling air duct 6 into the hollow air passing beam 8 of the annular rotary table frame 7, and the air passing beam 8 introduces the cooling air into the annular groove-shaped cooling bin 2; 4) the annular groove-shaped cooling bin 2 and the cooling air duct moving seat 601 perform rotary motion along with the annular rotary table frame 7, and introduced cooling air performs gas-solid heat exchange with the hot sintering ore; 5) after gas-solid heat exchange is completed, hot ore is changed into cold ore, cooling air is changed into hot air, wherein the cold ore is discharged from the first ore discharging device 15 through an ore discharging hopper 9, and the hot air is sent to the waste heat power generation device through a hot air collecting pipe 5. The operation state of the first ore discharging device 15 is specifically as follows: when the cold ore is not discharged, the first discharging door 1505 is tightly attached to the nozzle of the ore discharging pipe 14 under the action of the first counterweight 1504, and the cold ore in the ore discharging pipe 14 is blocked and cannot be discharged; after the first discharge gate 1505 enters the discharge section along the ore discharge pipe 14, the first control wheel 1502 installed at the middle part of the first discharge gate 1505 contacts with the discharge track 1503, rolls along the discharge track 1503 and gradually lifts up the first discharge gate 1505, when the opening between the ore discharge pipe 14 and the first discharge gate 1505 is large enough, the cold ore in the ore discharge pipe 14 is discharged from the opening and falls into the receiving belt, and the purpose of discharging the cold ore is achieved.

Example 5

A method for cooling sintered ore using the apparatus of example 1, comprising: 1) loading the high-temperature sintered ore unloaded from the sintering machine into an annular groove-shaped cooling bin 2 of a movable tank type cooler 1 through a feed hopper 17; 2) the cooling air duct 11 sends cooling air of the cooling fan 10 to the cooling air duct 6; 3) the cooling air communicating pipe 12 introduces the cooling air in the cooling air duct 6 into the hollow air passing beam 8 of the annular rotary table frame 7, and the air passing beam 8 introduces the cooling air into the annular groove-shaped cooling bin 2; 4) the annular groove-shaped cooling bin 2 and the cooling air duct moving seat 601 perform rotary motion along with the annular rotary table frame 7, and introduced cooling air performs gas-solid heat exchange with the hot sintering ore; 5) after gas-solid heat exchange is completed, hot ore is changed into cold ore, cooling air is changed into hot air, wherein the cold ore is discharged from the second ore discharging device 16 through the ore discharging hopper 9, and the hot air is sent to the waste heat power generation device through the hot air collecting pipe 5. The operation state of the second ore discharging device 16 is specifically as follows: when the discharging is not performed, the second discharging door 1607 is hung on the hanging seat 1601 through the hanging sleeve 1602 arranged on the second discharging door 1607, and the hanging seat 1601 supports the weight of the second discharging door 1607 through the hanging sleeve 1602, so that the second discharging door 1607 is in a closed state; after the second discharge door 1607 enters the discharge section, the collision block at the inlet of the discharge section firstly contacts with the hanging seat 1601 and collides the hanging seat 1601, the second discharge door 1607 loses the support of the hanging seat 1601, slides downwards under the action of a second counterweight 1606 arranged on the second discharge door 1607, the second discharge door 1607 is opened, and enters a discharge state; the second discharge door 1607 continues to move along with the ore discharge pipe 14, when leaving the discharge area, the second control wheel 1603 arranged on the second discharge door 1607 contacts with the lifting rail 1605 at the outlet of the discharge area, the second control wheel 1603 rolls along the lifting rail 1605, and the second discharge door 1607 is gradually lifted up, after the second discharge door 1607 is lifted to a certain height, the hanging seat 1601 arranged on the second discharge door 1607 is ejected to the hanging seat 1601 arranged on the ore discharge pipe 14 by the hanging seat 1601 and the hanging seat 1602 are automatically locked in an engaged mode, the second discharge door 1607 enters a closed state, and the operation is repeated in this way.

Claims (21)

1. A mobile can cooler (1) comprising:

1) an annular groove-shaped cooling bin (2) for accumulating sintered ore from a sintering machine from above;

2) the driving device (3) is used for driving the annular groove-shaped cooling bin (2) to do rotary motion in the horizontal direction or the horizontal plane;

3) an annular hot air cover (4) which is arranged on the annular groove-shaped cooling bin (2) and covers the upper part of the annular groove-shaped cooling bin;

4) 1-10 hot air collecting pipes (5) connected with the top or the side of the hot air cover (4);

5) the cooling air duct (6) is arranged on the outer side of the annular groove-shaped cooling bin (2), wherein the cooling air duct (6) comprises a cooling air duct moving seat (601) arranged at the lower part and a cooling air duct fixing cover (602) covering the upper part of the cooling air duct moving seat (601);

6) the cooling device comprises an annular rotary table frame (7) arranged at the bottoms of an annular groove-shaped cooling bin (2) and a cooling air channel (6), wherein the annular groove-shaped cooling bin (2) is supported on the annular rotary table frame (7), a cooling air channel moving seat (601) is fixed on the annular rotary table frame (7), and the annular rotary table frame (7) is provided with a hollow air passing beam (8);

7) a ore discharge hopper (9) arranged at the lower part of the annular groove-shaped cooling bin (2);

8) the air outlets of the cooling fans (10) are communicated to the cooling air duct (6) through the corresponding cooling air pipes (11);

9) a cooling air communicating pipe (12) arranged between the cooling air channel moving seat (601) and the annular rotary table frame (7), wherein the cooling air channel (6) is communicated with a hollow air passing beam (8) arranged in the annular rotary table frame (7) through the cooling air communicating pipe (12), and the interior of the air passing beam (8) is communicated with the bottom of the annular groove-shaped cooling bin (2);

10) the ore discharging device comprises an ore discharging pipe (14) arranged below the ore discharging hopper (9) and communicated with the ore discharging hopper (9), and a second ore discharging device (16) arranged at the tail end of the ore discharging pipe (14); second ore discharging device (16) are including hanging seat (1601), hang cover (1602), second control wheel (1603), prevent stifled groove (1604), lifting track (1605), second counter weight (1606) and second discharge door (1607), wherein lifting track (1605) set up in the exit of the district section of unloading, the entrance of the district section of unloading is provided with bumps, the vertical setting of second discharge door (1607) is at the orificial lower limb of ore discharge pipe (14), hang seat (1601) and install at the orificial last border of ore discharge pipe (14), hang cover (1602) and set up on second discharge door (1607) upper portion, second control wheel (1603) is installed in the middle part of second discharge door (1607), second counter weight (1606) set up in the orificial lower part of second discharge door (1607), groove (1604) set up on ore discharge pipe (14), be located the front end of hanging seat (1601).

2. The mobile can cooler of claim 1, wherein: the hot air cover (4) is fixedly arranged on the supporting frame (13), the cooling air duct fixing cover (602) is suspended on the supporting frame (13), the annular groove-shaped cooling bin (2) performs rotary motion together with the cooling air duct moving seat (601) and the annular rotary table frame (7) and/or,

and cooling air duct liquid seal grooves (603) are respectively arranged at two sides of the cooling air duct moving seat (601), wherein two side walls of the cooling air duct fixing cover (602) are inserted into the cooling air duct liquid seal grooves (603).

3. The mobile can cooler of claim 1 or 2, wherein 2-6 hot air collecting pipes (5) are connected to the top or side of the hot air hood (4).

4. The mobile can cooler of claim 3, wherein 3-4 hot air collecting pipes (5) are connected to the top or side of the hot air hood (4).

5. The mobile can cooler of any one of claims 1-2, 4, further comprising: a feed hopper (17) arranged at the upper part of the ring-groove-shaped cooling bin (2), and a feeding chute (18) arranged above the inner part of the ring-groove-shaped cooling bin (2), wherein the feed hopper (17) is communicated with the feeding chute (18).

6. The mobile can cooler of claim 3, further comprising: a feed hopper (17) arranged at the upper part of the ring-groove-shaped cooling bin (2), and a feeding chute (18) arranged above the inner part of the ring-groove-shaped cooling bin (2), wherein the feed hopper (17) is communicated with the feeding chute (18).

7. The mobile can cooler of any one of claims 1-2, 4, 6, further comprising: a hot air cover sealing device (19) arranged between the annular groove-shaped cooling bin (2) and the hot air cover (4).

8. The mobile can cooler of claim 3, further comprising: a hot air cover sealing device (19) arranged between the annular groove-shaped cooling bin (2) and the hot air cover (4).

9. The mobile can cooler of claim 5, further comprising: a hot air cover sealing device (19) arranged between the annular groove-shaped cooling bin (2) and the hot air cover (4).

10. The mobile can cooler of any one of claims 1-2, 4, 6, 8-9, wherein the lower part of the annular rotary table frame (7) is provided with a rotary table frame supporting rail (701) and a rotary table frame supporting wheel (702), and the side part of the annular rotary table frame (7) is provided with a rotary table frame side blocking wheel (703) and a rotary table frame side blocking rail (704); and/or

The lower part of the hot air cover (4) is provided with a hot air cover bracket (401), and the lower part of the hot air collecting pipe (5) is provided with a hot air collecting pipe bracket (501).

11. The mobile can cooler of claim 3, wherein a rotary table support rail (701) and a rotary table support wheel (702) are arranged at the lower part of the annular rotary table frame (7), and a rotary table side catch wheel (703) and a rotary table side catch rail (704) are arranged at the side part of the annular rotary table frame (7); and/or

The lower part of the hot air cover (4) is provided with a hot air cover bracket (401), and the lower part of the hot air collecting pipe (5) is provided with a hot air collecting pipe bracket (501).

12. The mobile can cooler of claim 5, wherein a rotary table support rail (701) and a rotary table support wheel (702) are arranged at the lower part of the annular rotary table frame (7), and a rotary table side catch wheel (703) and a rotary table side catch rail (704) are arranged at the side part of the annular rotary table frame (7); and/or

The lower part of the hot air cover (4) is provided with a hot air cover bracket (401), and the lower part of the hot air collecting pipe (5) is provided with a hot air collecting pipe bracket (501).

13. The mobile can cooler of claim 7, wherein a rotary table support rail (701) and a rotary table support wheel (702) are arranged at the lower part of the annular rotary table frame (7), and a rotary table side catch wheel (703) and a rotary table side catch rail (704) are arranged at the side part of the annular rotary table frame (7); and/or

The lower part of the hot air cover (4) is provided with a hot air cover bracket (401), and the lower part of the hot air collecting pipe (5) is provided with a hot air collecting pipe bracket (501).

14. The mobile can cooler according to any one of claims 1-2, 4, 6, 8-9, 11-13, the hot air collection pipe (5) being connected to a waste heat utilization device.

15. The mobile can cooler of claim 3, the hot air collection pipe (5) being connected to a waste heat utilization device.

16. The mobile can cooler of claim 5, the hot air collection pipe (5) being connected to a waste heat utilization device.

17. The mobile can cooler of claim 7, the hot air collection pipe (5) being connected to a waste heat utilization device.

18. The mobile can cooler of claim 10, the hot air collection pipe (5) being connected to a waste heat utilization device.

19. The mobile can cooler of claim 14, the hot air collection pipe (5) being connected to a cogeneration unit.

20. The mobile can cooler according to any one of claims 15-18, the hot blast collection pipe (5) being connected to a cogeneration unit.

21. A method of cooling sinter using the mobile can cooler of any one of claims 1 to 20, the method comprising: 1) high-temperature sintered ore unloaded from the sintering machine is loaded into an annular groove-shaped cooling bin (2) of a movable tank type cooler (1) through a feed hopper (17); 2) the cooling air pipe (11) sends cooling air of the cooling fan (10) to the cooling air duct (6); 3) the cooling air communicating pipe (12) leads the cooling air in the cooling air duct (6) into a hollow air passing beam (8) of the annular rotary table frame (7), and the air passing beam (8) leads the cooling air into the annular groove-shaped cooling bin (2); 4) the annular groove-shaped cooling bin (2) and the cooling air channel moving seat (601) rotate along with the annular rotating table frame (7), and introduced cooling air and the sintered hot ore perform gas-solid heat exchange; 5) after gas-solid heat exchange is finished, hot ore is changed into cold ore, cooling air is changed into hot air, wherein the cold ore is discharged from a second ore discharging device (16) through an ore discharging hopper (9), and the hot air is sent to a waste heat utilization device through a hot air collecting pipe (5);

wherein: and 5), discharging the cold ore from a second ore discharging device (16), wherein the operation state of the second ore discharging device (16) is as follows: when the material is not discharged, the second discharging door (1607) is hung on the hanging seat (1601) through a hanging sleeve (1602) arranged on the second discharging door (1607), and the hanging seat (1601) supports the weight of the second discharging door (1607) through the hanging sleeve (1602), so that the second discharging door (1607) is in a closed state; after the second discharging door (1607) enters the discharging section, the collision block at the inlet of the discharging section firstly contacts with the hanging seat (1601) and collides the hanging seat (1601) to be opened, the second discharging door (1607) loses the support of the hanging seat (1601), slides downwards to the lower part under the action of a second counterweight (1606) arranged on the second discharging door (1607), and the second discharging door (1607) is opened to enter a discharging state; the second discharging door (1607) continuously operates along with the ore discharging pipe (14), when the second discharging door (1607) leaves a discharging area, a second control wheel (1603) arranged on the second discharging door (1607) is in contact with a lifting track (1605) at an outlet of a discharging section, the second control wheel (1603) rolls along the lifting track (1605), the second discharging door (1607) is gradually lifted, after the second discharging door (1607) is lifted to a certain height, a hanging seat (1601) arranged on the ore discharging pipe (14) is ejected by a hanging sleeve (1602) arranged on the second discharging door (1607), the hanging seat (1601) and the hanging sleeve (1602) are automatically occluded and locked, and the second discharging door (1607) enters a closed state and reciprocates in the same way.

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