CN213272625U - Cement kiln handles solid conveyor that gives up - Google Patents

Abstract

For solving the problem that prior art exists, the utility model provides a cement kiln deals with solid useless conveyor, include: the cement rotary kiln comprises a cement rotary kiln body, a high-temperature ceramic channel, a power system and a feeding buffer. One end of the high-temperature ceramic channel extends to the inside of the cement rotary kiln from the air blast channel of the cement rotary kiln, the other end of the high-temperature ceramic channel is positioned outside the cement rotary kiln, and a ceramic conveying device is arranged in the high-temperature ceramic channel. The ceramic transport device comprises: the conveyer belt is composed of high-temperature ceramic plates, a driven high-temperature ceramic wheel and a driving high-temperature ceramic wheel. The driven high-temperature ceramic wheel is positioned at one end close to the cement rotary kiln, and the driving high-temperature ceramic wheel is positioned at one end far away from the cement rotary kiln. The power system drives the driving high-temperature ceramic wheel to rotate. The charging buffer is positioned above or on the side of the driving high-temperature ceramic wheel and is communicated with the top end surface or the side end surface of the high-temperature ceramic channel. The utility model discloses not only overcome the restriction in place, removed the plastic bag packing moreover from.

Description

Cement kiln handles solid conveyor that gives up

Technical Field

The utility model relates to a refuse treatment technical field specifically is a cement kiln deals with solid useless conveyor.

Background

The cement kiln co-treatment is a new waste treatment method proposed by the cement industry, and means that solid waste meeting or meeting the kiln entering requirement after pretreatment is put into a cement kiln, and the harmless treatment process of the solid waste is realized while cement clinker production is carried out.

In the prior art, solid wastes are generally slid into a cement kiln through a sliding conveying track. But this technique has limited the mode of transportation of material on the one hand, and the smooth track must take the downward sloping situation from top to low end to increase the installation site requirement of cement kiln co-processing system. Meanwhile, the solid waste is required to slide into the cement kiln by the aid of the solid waste self, the solid waste is required to be packaged by plastic bags, on one hand, the solid waste is prevented from being dispersed all around when the waste falls off, on the other hand, sliding friction force is reduced, on the other hand, the solid waste, particularly the solid waste with certain viscosity, is prevented from being stuck in a sliding conveying track to cause track blockage, and once the track is blocked, the solid waste cannot be fed into the cement rotary kiln, production stop overhaul needs to be carried out, and treatment efficiency is seriously influenced. In addition, the plastic bag packaging has the problem that the plastic bag is worn and broken when sliding, and the cost of solid waste treatment is increased, such as the need of installing a plastic packaging machine, the need of using a large amount of sealing bags, the generation of additional tail gas after the sealing bags are treated, and the like.

SUMMERY OF THE UTILITY MODEL

The utility model discloses problem to prior art exists provides a cement kiln deals with solid useless conveyor, include: the cement rotary kiln comprises a cement rotary kiln body, a high-temperature ceramic channel, a power system and a feeding buffer. One end of the high-temperature ceramic channel extends to the inside of the cement rotary kiln from the air blowing channel of the cement rotary kiln, and an opening is formed in the bottom surface of the inside of the cement rotary kiln. The other end of the high-temperature ceramic channel is positioned outside the cement rotary kiln and is a closed hollow channel, and a ceramic conveying device is arranged in the high-temperature ceramic channel. The ceramic transport device comprises: the conveyer belt is composed of high-temperature ceramic plates, a driven high-temperature ceramic wheel for supporting and adjusting the direction of the conveyer belt, and a driving high-temperature ceramic wheel for driving the conveyer belt to rotate. The driven high-temperature ceramic wheel is positioned at one end close to the cement rotary kiln, and the driving high-temperature ceramic wheel is positioned at one end far away from the cement rotary kiln. The power system drives the driving high-temperature ceramic wheel to rotate. The charging buffer is positioned above or on the side of the driving high-temperature ceramic wheel and is communicated with the top end surface or the side end surface of the high-temperature ceramic channel.

Furthermore, a downward inclined plane is arranged on the ground of the cement rotary kiln from the high-temperature ceramic channel to the opposite side of the high-temperature ceramic channel.

Furthermore, the high-temperature ceramic sheet is a cubic high-temperature ceramic sheet, and a sealing baffle is arranged on the top surface of one end of the high-temperature ceramic sheet. The bottom surface of the cubic high-temperature ceramic plate below the sealing baffle is provided with a first support. The first support is fixed with the first rotating disc. And a second support which is symmetrically arranged with the first support is arranged on the bottom surface of the cubic high-temperature ceramic plate on the opposite side of the sealing baffle. The second support is fixed with the second turntable. The first rotating disc is rotatably connected with the second rotating disc.

Furthermore, an arc convex surface is arranged at the joint of the sealing baffle and the cubic high-temperature ceramic plate.

Furthermore, a toothed belt is arranged on one surface of the high-temperature ceramic piece, which is in contact with the driven high-temperature ceramic wheel and the driving high-temperature ceramic wheel.

Further, the driven high-temperature ceramic wheel includes: a first high temperature ceramic gear in toothed engagement with the toothed belt. And a first high-temperature ceramic rotating shaft is fixed at the middle shaft of the first high-temperature ceramic gear. And two ends of the first high-temperature ceramic rotating shaft are rotatably connected with the high-temperature ceramic channel through a first high-temperature ceramic bearing.

Further, the active high temperature ceramic wheel comprises: and the second high-temperature ceramic gear is in toothed connection with the toothed belt. And a second high-temperature ceramic rotating shaft is fixed at the middle shaft of the second high-temperature ceramic gear. And two ends of the second high-temperature ceramic rotating shaft are rotatably connected with the high-temperature ceramic channel through second high-temperature ceramic bearings. And a first high-temperature ceramic driving gear is fixed on the part of the second high-temperature ceramic rotating shaft, which is positioned outside the high-temperature ceramic channel.

Further, the power system comprises: a hard outer shell. And a driving device, an electric control gearbox and a speed reducer which are connected in sequence are arranged in the hard shell. And the output end of the speed reducer is fixed with the high-temperature ceramic driving rotating shaft. The driving rotating shaft is arranged side by side with the first high-temperature ceramic bearing and the second high-temperature ceramic rotating shaft, and the two ends of the driving rotating shaft are provided with second high-temperature ceramic driving gears at positions corresponding to the first high-temperature ceramic driving gears. The first high-temperature ceramic driving gear and the second high-temperature ceramic driving gear are connected through a high-temperature ceramic chain. One end of the hard shell is sleeved outside the first high-temperature ceramic driving gear.

Further, the charge buffer comprises: a buffer chamber. The top of the buffer cavity is provided with a charging hole and is communicated with the blast pipe. The bottom of the buffer cavity is communicated with the top end of the high-temperature ceramic channel through a high-temperature ceramic charging pipe or is communicated with the side end of the high-temperature ceramic channel through the high-temperature ceramic charging pipe and a conveying belt in sequence, and an electric control gate is arranged at a position close to the buffer cavity.

Furthermore, a heat exchange cooler is sleeved outside the high-temperature ceramic charging pipe.

The utility model discloses one of following advantage has at least:

1. the utility model discloses a transport belt of particular structure is useless admittedly to cement rotary kiln supply, has not only effectively overcome the restriction in place, has removed the problem that needs plastic bag packing useless admittedly moreover from.

2. The utility model discloses can solve solid waste material to a certain extent and pile up in the feed inlet below, lead to the limited problem of feedrate.

Drawings

Fig. 1 is the structure schematic diagram of the solid waste conveying device for cement kiln disposal.

Fig. 2 is a schematic structural diagram of the high-temperature ceramic wafer of the present invention.

Fig. 3 is a schematic structural view of the conveyor belt of the present invention.

Fig. 4 is a schematic structural view of the driven high-temperature ceramic wheel of the present invention.

Fig. 5 is a schematic structural view of the active high-temperature ceramic wheel of the present invention.

Fig. 6 is a schematic structural diagram of the power system of the present invention.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

Example 1

A cement kiln solid waste disposal conveying device is shown in figure 1 and comprises: the device comprises a cement rotary kiln 1, a high-temperature ceramic channel 2, a power system 5 and a feeding buffer 6. One end of the high-temperature ceramic channel 2 extends to the inside of the cement rotary kiln 1 from the air blowing channel of the cement rotary kiln 1, and an opening is formed in the bottom surface of the inside of the cement rotary kiln 1. The other end of the high-temperature ceramic channel 2 is positioned outside the cement rotary kiln 1 and is a closed hollow channel, and a ceramic conveying device 3 is arranged in the high-temperature ceramic channel. The ceramic transport device 3 comprises: a conveyer belt 301 formed by combining the high-temperature ceramic plates 4, a driven high-temperature ceramic wheel 302 for supporting and adjusting the direction of the conveyer belt 301, and a driving high-temperature ceramic wheel 303 for driving the conveyer belt 301 to rotate. The driven high-temperature ceramic wheel 302 is positioned at one end close to the cement rotary kiln 1, and the driving high-temperature ceramic wheel 303 is positioned at one end far away from the cement rotary kiln 1. The power system 5 drives the driving high-temperature ceramic wheel 303 to rotate. The feeding buffer 6 is positioned above or on the side of the driving high-temperature ceramic wheel 303 and is communicated with the top end surface or the side end surface of the high-temperature ceramic channel 2.

When solid waste needs to be added into the cement rotary kiln 1, the sorted and pre-dried solid waste is firstly added into the feeding buffer 6, and then the power system 5 is started. The power system 5 drives the driving high-temperature ceramic wheel 303 to rotate, so as to drive the conveying belt 301 and the driven high-temperature ceramic wheel 302 to rotate. Then the feeding buffer 6 is conveyed or slid onto the conveying surface of the conveying belt 301, and the conveying belt 301 conveys the solid waste into the cement rotary kiln 1 from the blast channel of the cement rotary kiln 1. High temperature ceramic passageway 2 is used for keeping warm, avoids the inside high hot gas flow of cement rotary kiln 1 to outside diffusion, can preheat the useless admittedly that transport belt 301 injures in the high temperature ceramic passageway 2 simultaneously. Because the feeding is carried out by adopting the mode of the conveyer belt 301, the feeding end of the conveyer belt 301 can be horizontal and inclined upwards or downwards within a certain range, thereby greatly expanding the installation position range of the equipment. The use limit of the equipment to the field is reduced. Meanwhile, materials do not need to slide into the cement rotary kiln 1, so that plastic bag packaging is not needed for solid wastes. Even if the high-viscosity solid waste is transported, the transportation channel cannot be blocked even if part of the high-viscosity solid waste is adhered on the transportation belt in the continuous operation process of the transportation belt, and meanwhile, the high-viscosity solid waste adhered on the transportation belt can be gradually decomposed and disappear in a high-temperature environment for a certain time because the transportation belt is in the high-temperature environment.

Example 2

Based on the cement kiln solid waste disposal conveying device in embodiment 1, as shown in fig. 1, a downward inclined plane 101 is arranged on the ground of the cement rotary kiln 1 from the high-temperature ceramic channel 2 to the opposite side of the high-temperature ceramic channel 2.

This setting can say to a certain extent that carry solid useless to the charging end offside landing in the mud rotary kiln 1 of intaking, avoids solid waste material to pile up in high temperature ceramic passageway 2 below, influences the treatment effeciency and the handling capacity of solid waste material.

Example 3

Based on the solid waste conveying device for cement kiln disposal described in embodiment 1, as shown in fig. 2, the high-temperature ceramic sheet 4 is a cubic high-temperature ceramic sheet, and a sealing baffle 401 is disposed on a top surface of one end of the cubic high-temperature ceramic sheet. The bottom surface of the cubic high-temperature ceramic plate below the sealing baffle 401 is provided with a first support 405. The first holder 405 is fixed to the first turntable 406. The bottom surface of the cubic high-temperature ceramic plate on the opposite side of the sealing baffle 401 is provided with a second support 403 which is symmetrically arranged with the first support 405. The second support 403 is fixed to the second turntable 404. The first turntable 406 is rotatably coupled to the second turntable 404. Because the conveyer belt that high temperature potsherd 4 constitutes is located high temperature ceramic passageway 2, often is in 900 and supplyes 1400 ℃ of high temperature in its operational environment, adopts rubber belt and general strap often can not satisfy the needs, consequently the utility model discloses a conveyer belt is spliced into to high temperature potsherd 4 of particular structure. The added sealing baffle 401 can prevent fine solid waste particles from falling from the splicing gap of the adjacent high-temperature ceramic plates 4 to influence the operation of the device.

And an arc convex surface is arranged at the joint of the sealing baffle 401 and the cubic high-temperature ceramic plate. If a vertical plane structure is adopted, solid wastes can be accumulated on the back surface of the sealing baffle 401, and the adoption of the arc convex surface can effectively avoid the occurrence of doubtful situations.

Example 4

Based on the solid waste conveying device for cement kiln disposal described in embodiment 1, as shown in fig. 3, a toothed belt 407 is disposed on one surface of the high-temperature ceramic sheet 4 contacting the driven high-temperature ceramic wheel 302 and the driving high-temperature ceramic wheel 303.

As shown in fig. 4, the driven high-temperature ceramic wheel 302 includes: a first high temperature ceramic gear 3021 in toothed engagement with the toothed belt 407. A first high-temperature ceramic rotating shaft 3022 is fixed at the central axis of the first high-temperature ceramic gear 3021. And two ends of the first high-temperature ceramic rotating shaft 3022 are rotatably connected with the high-temperature ceramic channel 2 through a first high-temperature ceramic bearing 3023.

As shown in fig. 5, the active high temperature ceramic wheel 303 includes: and a second high temperature ceramic gear 3031 in toothed engagement with the toothed belt 407. A second high-temperature ceramic rotating shaft 3032 is fixed at the middle shaft of the second high-temperature ceramic gear 3031. And two ends of the second high-temperature ceramic rotating shaft 3032 are rotatably connected with the high-temperature ceramic channel 2 through a second high-temperature ceramic bearing 3033. A first high-temperature ceramic driving gear 3034 is fixed on the part of the second high-temperature ceramic rotating shaft 3032, which is positioned outside the high-temperature ceramic channel 2.

The driven high-temperature ceramic wheel 302, the driving high-temperature ceramic wheel 303 and the high-temperature ceramic plates 4 adopt a tooth joint mode, so that the problem of slippage during heavy solid waste transportation can be effectively avoided. Meanwhile, because the surface friction of the high-temperature ceramic is generally not large, if the high-temperature ceramic is driven to operate by the friction force, a large pressure needs to be applied, and the driven high-temperature ceramic wheel 302, the first high-temperature ceramic rotating shaft 3022, the driving high-temperature ceramic wheel 303, the second high-temperature ceramic rotating shaft 3032, and the high-temperature ceramic sheet 4 may be damaged due to the excessive force.

Example 5

Based on the cement kiln solid waste disposal conveying device in embodiment 1, as shown in fig. 6, the power system 5 includes: a rigid outer shell 501. A driving device 502, an electric control gearbox 503 and a speed reducer 504 which are connected in sequence are arranged in the hard shell 501. The output end of the speed reducer 504 is fixed with a high-temperature ceramic driving rotating shaft 505. The high-temperature ceramic driving rotating shaft 505 is arranged side by side with the first high-temperature ceramic bearing 3023 and the second high-temperature ceramic rotating shaft 3032, and the second high-temperature ceramic driving gear 506 is arranged at the position corresponding to the first high-temperature ceramic driving gear 3034 at the two ends thereof. The first high-temperature ceramic driving gear 3034 and the second high-temperature ceramic driving gear 506 are connected through a high-temperature ceramic chain 507. One end of the hard shell 501 is sleeved outside the first high-temperature ceramic driving gear 3034. The driving device 502 may be an electric motor, a diesel engine, a gasoline engine, a steam turbine, or the like that can provide rotational driving force.

At this time, the driving device 502 provides a rated rotational driving force, the electrically controlled transmission 503 is controlled to perform variable speed output as required, and the speed reducer 504 drives the high-temperature ceramic driving shaft 505 to rotate, so as to drive the second high-temperature ceramic driving gear 506 to rotate. The second high temperature ceramic driving gear 506 drives the first high temperature ceramic driving gear 3034 to rotate through the high temperature ceramic chain 507, and further drives the conveyer belt 301 to move.

Example 6

Based on the cement kiln solid waste disposal conveying device in the embodiment 1, as shown in fig. 1, the charging buffer 6 comprises: the buffer chamber 601. The top of the buffer chamber 601 is provided with a charging opening 602 and is communicated with the blast pipe 8. The bottom of the buffer cavity 601 is communicated with the top end of the high-temperature ceramic channel 2 through a high-temperature ceramic feeding pipe 603, or is communicated with the side end of the high-temperature ceramic channel 2 through the high-temperature ceramic feeding pipe 603 and a conveying belt in sequence, and an electric control gate 7 is arranged at a position close to the buffer cavity 601. The outside cover of high temperature ceramic filling tube 603 is equipped with the heat exchange cooler.

At this time, when the air blowing operation is not provided for the cement rotary kiln 1, the electric control gate 7 is closed, and simultaneously the feed inlet 602 is opened, and the solid waste material to be treated is added into the buffer chamber 601. When the air blowing operation needs to be provided for the cement rotary kiln 1, the charging opening 602 is closed, the air blowing device is started, and the electronic control gate 7 is opened. The blown air firstly flows into the buffer cavity 601 from the blast pipe 8, blows the motor materials from the electric control gate 7 into the high-temperature ceramic feeding pipe 603 and then enters the conveying surface of the conveying belt 301 of the high-temperature ceramic passage 2. Adopt the device can feed in raw material in the blast air, avoid the material to pile up in cushion 601 on the one hand, on the other hand avoids the high temperature hot air of high temperature ceramic passageway 2 excessive when reinforced. The heat exchange cooler that high temperature ceramic filling tube 603 outside cover was established can play the effect of cooling high temperature ceramic filling tube 603, avoids the interior high temperature of cushion 601, causes latent reinforced safety risk.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (8)

1. Cement kiln handles useless conveyor admittedly, its characterized in that includes: the device comprises a cement rotary kiln (1), a high-temperature ceramic channel (2), a power system (5) and a feeding buffer (6); one end of the high-temperature ceramic channel (2) extends into the cement rotary kiln (1) from the blast channel of the cement rotary kiln (1), and an opening is arranged on the bottom surface in the cement rotary kiln (1); the other end of the high-temperature ceramic channel (2) is positioned outside the cement rotary kiln (1) and is a closed hollow channel, and a ceramic conveying device (3) is arranged in the high-temperature ceramic channel; the ceramic transport device (3) comprises: a conveyer belt (301) formed by combining high-temperature ceramic plates (4), a driven high-temperature ceramic wheel (302) for supporting and adjusting the direction of the conveyer belt (301), and a driving high-temperature ceramic wheel (303) for driving the conveyer belt (301) to rotate; the driven high-temperature ceramic wheel (302) is positioned at one end close to the cement rotary kiln (1), and the driving high-temperature ceramic wheel (303) is positioned at one end far away from the cement rotary kiln (1); the power system (5) drives the driving high-temperature ceramic wheel (303) to rotate; the feeding buffer (6) is positioned above or on the side of the driving high-temperature ceramic wheel (303) and is communicated with the top end surface or the side end surface of the high-temperature ceramic channel (2).

2. The cement kiln solid waste disposal and conveying device as claimed in claim 1, wherein the cement rotary kiln (1) is provided with a downward inclined surface (101) on the ground from the high temperature ceramic channel (2) to the opposite side of the high temperature ceramic channel (2).

3. The cement kiln treatment solid waste conveying device as claimed in claim 1, wherein the high-temperature ceramic plate (4) is a cubic high-temperature ceramic plate, and a sealing baffle plate (401) is arranged on the top surface of one end of the cubic high-temperature ceramic plate; a first support (405) is arranged on the bottom surface of the cubic high-temperature ceramic plate below the sealing baffle (401); the first support (405) is fixed with a first rotating disc (406); the bottom surface of the cubic high-temperature ceramic plate on the opposite side of the sealing baffle (401) is provided with a second support (403) which is symmetrical to the first support (405); the second support (403) is fixed with a second turntable (404); the first turntable (406) is rotatably connected to the second turntable (404).

4. The cement kiln solid waste disposal and conveying device as claimed in claim 3, wherein the joint of the sealing baffle (401) and the cubic high-temperature ceramic plate is provided with a circular arc convex surface.

5. The cement kiln treatment solid waste conveying device as claimed in claim 1, wherein a toothed belt (407) is arranged on one surface of the high-temperature ceramic plate (4) which is in contact with the driven high-temperature ceramic wheel (302) and the driving high-temperature ceramic wheel (303);

the driven high-temperature ceramic wheel (302) comprises: a first high-temperature ceramic gear (3021) that is in toothed engagement with the toothed belt (407); a first high-temperature ceramic rotating shaft (3022) is fixed at the middle shaft of the first high-temperature ceramic gear (3021); two ends of the first high-temperature ceramic rotating shaft (3022) are rotatably connected with the high-temperature ceramic channel (2) through a first high-temperature ceramic bearing (3023);

the active high temperature ceramic wheel (303) comprises: a second high-temperature ceramic gear (3031) in toothed engagement with the toothed belt (407); a second high-temperature ceramic rotating shaft (3032) is fixed at the middle shaft of the second high-temperature ceramic gear (3031); two ends of the second high-temperature ceramic rotating shaft (3032) are rotatably connected with the high-temperature ceramic channel (2) through a second high-temperature ceramic bearing (3033); and a first high-temperature ceramic driving gear (3034) is fixed on the part of the second high-temperature ceramic rotating shaft (3032) positioned outside the high-temperature ceramic channel (2).

6. The cement kiln disposed solid waste conveyor device according to claim 5, wherein the power system (5) comprises: a hard outer shell (501); a driving device (502), an electric control gearbox (503) and a speed reducer (504) which are connected in sequence are arranged in the hard shell (501); the output end of the speed reducer (504) is fixed with the high-temperature ceramic driving rotating shaft (505); the high-temperature ceramic driving rotating shaft (505) is arranged side by side with the first high-temperature ceramic bearing (3023) and the second high-temperature ceramic rotating shaft (3032), and the two ends of the high-temperature ceramic driving rotating shaft are provided with second high-temperature ceramic driving gears (506) at positions corresponding to the first high-temperature ceramic driving gears (3034); the first high-temperature ceramic driving gear (3034) and the second high-temperature ceramic driving gear (506) are connected through a high-temperature ceramic chain (507); one end of the hard shell (501) is sleeved outside the first high-temperature ceramic driving gear (3034).

7. The cement kiln disposed solid waste conveyor device according to claim 1, wherein the feed buffer (6) comprises: a buffer chamber (601); the top of the buffer cavity (601) is provided with a feed inlet (602) and is communicated with the blast pipe (8); the bottom of the buffer cavity (601) is communicated with the top end of the high-temperature ceramic channel (2) through a high-temperature ceramic feeding pipe (603), or is communicated with the side end of the high-temperature ceramic channel (2) through the high-temperature ceramic feeding pipe (603) and a conveying belt in sequence, and an electric control gate (7) is arranged at a position close to the buffer cavity (601).

8. The cement kiln solid waste disposal and conveying device as claimed in claim 7, wherein a heat exchange cooler is sleeved outside the high temperature ceramic feeding pipe (603).

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