CN211170408U - Sludge mixing drying pure combustion power generation system - Google Patents
Sludge mixing drying pure combustion power generation system Download PDFInfo
- Publication number
- CN211170408U CN211170408U CN201921571409.3U CN201921571409U CN211170408U CN 211170408 U CN211170408 U CN 211170408U CN 201921571409 U CN201921571409 U CN 201921571409U CN 211170408 U CN211170408 U CN 211170408U
- Authority
- CN
- China
- Prior art keywords
- sludge
- dust collector
- outlet
- inlet
- pipeline
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Active
Links
Images
Abstract
The utility model provides a pure power generation system that burns of mixed mummification of mud, the energy consumption is low, the mummification is efficient, the mummification is with low costs, need not to mix any auxiliary fuel of burning. The concentrated sewage tank is connected with the plate-and-frame filter press through a pipeline, and a sludge screw pump is arranged on the pipeline; the plate-and-frame filter press is connected with a sludge crusher through a belt conveyor; the sludge crusher is connected with the semi-dry sludge bin; the half-dry sludge bin is connected with a steam dryer through a first screw conveyor; the steam dryer is connected with the dry sludge storage bin through a second screw conveyor; the dry sludge storage bin is connected with the fluidized bed furnace incineration system through a weighing feeder; a flue gas outlet of the fluidized bed furnace incineration system is connected with an electrostatic dust collector; the electrostatic dust collector is connected with the bag-type dust collector through a pipeline, and the pipeline is connected with a limestone conveying system and an active carbon conveying system; the bag-type dust collector is connected with the wet desulphurization tower through an induced draft fan; the wet desulphurization tower is connected with the wet electric dust collector; the wet electric dust collector is connected with the chimney.
Description
Technical Field
The utility model relates to a pure electricity generation system that burns of mixed mummification of mud mainly is applicable to the mummification of municipal sludge in city and industrial sludge and burns the electricity generation.
Background
With the increasing world population, the rapid development of urbanization and the gradual increase of sewage collection rate, the increasing of urban sludge yield, the treatment and disposal of sludge become a sensitive global environmental problem. In order to effectively, harmlessly, reduce and recycle municipal sludge in time, sludge drying and incineration are important methods for harmlessly treating the sludge. The sludge drying incineration can reduce the volume of the sludge to the minimum (the sludge is reduced by more than 90 percent); the energy can be recovered and used for drying the sludge or generating electricity and supplying heat; can completely carbonize organic matters, kill pathogens and make sludge thoroughly harmless.
At present, the domestic mainstream sludge drying and incinerating power generation technology has the defects of high energy consumption, high drying cost, need of blending auxiliary fuel (coal or natural gas), consumption of national energy and the like. Now, a few domestic mainstream technologies and the defects thereof are simply introduced:
1. mechanical deep dehydration and fluidized bed incineration power generation technology.
1.1, brief introduction of the process:
conveying sludge generated in the sewage treatment process into a sludge treatment tank through a pump, adding conditioners (such as a stabilizer, a filter aid, a modifier and the like) (such as a medicament PAM (polyacrylamide), a flocculating agent, lime sawdust and the like), stirring, fully reacting the sludge with the medicament, conditioning the water content of the sludge to 95-97%, conveying the sludge into a sludge diaphragm filter press through the pump, filtering and squeezing, drying the sludge to form dry sludge with the water content of about 55%, and burning and generating power through a circulating fluidized bed boiler.
1.2, technical disadvantages:
the main disadvantages of this technique are: 1) in the sludge drying process, a plurality of conditioning agents such as a stabilizer, a filter aid, a modifier and the like are required to be added; 2) the dryness of the dried sludge is not enough, the water content is about 55 percent, and the pure combustion requirement cannot be met; 3) about 15% of the coal needs to be co-burned for mixed combustion, and national resources are consumed.
2. Steam drying dehydration and fluidized bed incineration power generation technology.
2.1, brief introduction of the process:
sludge produced in the sewage treatment process is conveyed into a sludge treatment tank through a pump, sludge with the water content of 80 percent obtained by primary dehydration in a sewage treatment plant is conveyed to a wet sludge storage bin through a plunger pump, the sludge is conveyed into a steam dryer by a screw conveyor, 0.5MPa (absolute pressure) is adopted, superheated steam with the temperature of 200 ℃ serves as drying heat media, a steam pipeline enters the dryer from a hollow shaft steam inlet of the dryer and a body C-shaped annular part steam inlet respectively to carry out indirect heat exchange drying on the sludge, the sludge with the water content of 45 percent can be dried (controllable), and dry sludge mixed coal is incinerated and generated through a circulating fluidized bed boiler.
2.2, technical disadvantages:
the main disadvantages of this technique are: 1) a large amount of latent heat of vaporization is consumed in the drying process; 2) about 0.75t of steam is consumed when 80% of moisture in each ton of wet sludge is dried to about 45%, and the drying cost is high; 3) about 15% of the fire coal needs to be mixed and burned, so that national resources are consumed; 4) the treatment cost of single ton of wet sludge with 80 percent of water is higher, which is about 200 yuan.
3. Drying tower and rotary kiln incineration technology.
3.1, brief introduction of the process:
the method comprises the steps of conveying 80% water content sludge subjected to primary dehydration in a sewage treatment plant into a sludge storage tank through a screw pump, conveying the sludge into a high-level sludge tank through a plunger pump, lifting the sludge through the screw pump, conveying the sludge into a spray drying tower, atomizing the sludge through a tower top nozzle, and then carrying out downstream contact with high-temperature flue gas discharged from a secondary combustion chamber for drying. The temperature of inlet high-temperature flue gas is 600-700 ℃ in the drying process, and the temperature of exhaust gas is about-110 ℃; and (3) reducing the water content of the dried sludge from 80% to 20%, and then directly entering a rotary kiln incinerator for incineration.
3.2, technical disadvantages:
the main disadvantages of this technique are: 1) a large amount of latent heat of vaporization is consumed in the drying process; 2) the sludge is not recycled after being burnt; 3) about 15% of fire coal or natural gas needs to be co-combusted for mixed combustion, so that national resources are consumed; 4) the treatment cost of single ton of wet sludge with 80 percent of water is higher, about 220 yuan.
From the above, the domestic mainstream sludge drying incineration power generation technology has the characteristics that the mechanical filter pressing dehydration and drying effect is common, the steam drying cost is higher, and a certain amount of auxiliary fuel such as coal or natural gas needs to be mixed and combusted during incineration.
SUMMERY OF THE UTILITY MODEL
An object of the utility model is to overcome the above-mentioned not enough that exists among the prior art, and provide a sludge mixing mummification pure combustion power generation system that structural design is reasonable, the energy consumption is low, the mummification is efficient, the mummification is with low costs, need not to mix any auxiliary fuel of burning.
The utility model provides a technical scheme that above-mentioned problem adopted is: the utility model provides a pure power generation system that burns of mud mixed mummification which characterized in that: the system comprises a concentrated sewage pool, a sludge screw pump, a plate-and-frame filter press, a belt conveyor, a sludge crusher, a semi-dry sludge bin, a screw conveyor I, a steam dryer, a screw conveyor II, a dry sludge storage bin, a weighing feeder, a fluidized bed furnace incineration system, an electrostatic dust collector, a limestone conveying system, an active carbon conveying system, a bag-type dust collector, an induced draft fan, a wet desulfurization tower, a wet electric dust collector and a chimney; the outlet of the concentrated sewage tank is connected with the inlet of the plate-and-frame filter press through a pipeline, and a sludge screw pump is arranged on the pipeline; the outlet of the plate-and-frame filter press is connected with the inlet of the sludge crusher through a belt conveyor; the outlet of the sludge crusher is connected with the inlet of the semi-dry sludge bin; an outlet of the half-dry sludge bin is connected with an inlet of the steam dryer through a first screw conveyor; the outlet of the steam dryer is connected with the inlet of the dry sludge storage bin through a second screw conveyor; the outlet of the dry sludge storage bin is connected with the inlet of the fluidized bed furnace incineration system through a weighing feeder; the flue gas outlet of the fluidized bed furnace incineration system is connected with the inlet of the electrostatic dust collector; the outlet of the electrostatic dust collector is connected with the inlet of the bag-type dust collector through a pipeline, and the pipeline is connected with a limestone conveying system and an active carbon conveying system; the outlet of the bag-type dust collector is connected with the inlet of the wet desulphurization tower through a draught fan; the outlet of the wet desulphurization tower is connected with the inlet of the wet electric dust collector; the outlet of the wet electric dust collector is connected with a chimney.
The chimney of the utility model is a sleeve type chimney.
The second screw conveyer is a shaftless screw conveyer.
The steam drier of the utility model is a disc type drier.
The fluidized bed furnace incineration system is also connected with the steam dryer.
Compared with the prior art, the utility model, have following advantage and effect:
1. the sludge drying process is advanced.
2. The sludge drying energy consumption loss is small, and the drying energy consumption is low.
3. Does not mix any auxiliary fuel such as coal, natural gas and the like.
4. The single ton sludge treatment cost is low.
Drawings
Fig. 1 is a schematic structural diagram of an embodiment of the present invention.
Detailed Description
The present invention will be described in further detail by way of examples with reference to the accompanying drawings, which are illustrative of the present invention and are not intended to limit the present invention.
Referring to fig. 1, the embodiment of the utility model provides a include concentrated effluent water sump 1, mud screw pump 2, plate and frame filter press 3, band conveyer 4, sludge crusher 5, half-dry sludge warehouse 6, screw conveyer 7, steam dryer 8, screw conveyer two 9, dry sludge storage 10, batcher of weighing 11, fluidized bed furnace system of burning 12, electrostatic precipitator 13, lime stone conveying system 14, active carbon conveying system 15, sack cleaner 16, draught fan 17, wet flue gas desulfurization tower 18, wet electrostatic precipitator 19 and chimney 20.
The outlet of the concentrated sewage tank 1 is connected with the inlet of a plate-and-frame filter press 3 through a pipeline, and a sludge screw pump 2 is arranged on the pipeline; the outlet of the plate-and-frame filter press 3 is connected with the inlet of a sludge crusher 5 through a belt conveyor 4; the outlet of the sludge crusher 5 is connected with the inlet of the semi-dry sludge bin 6; an outlet of the semi-dry sludge bin 6 is connected with an inlet of a steam dryer 8 through a first screw conveyor 7; an outlet of the steam dryer 8 is connected with an inlet of a dry sludge storage bin 10 through a second screw conveyor 9; the outlet of the dry sludge storage bin 10 is connected with the inlet of a fluidized bed furnace incineration system 12 through a weighing feeder 11.
The flue gas outlet of the fluidized bed furnace incineration system 12 is connected with the inlet of the electrostatic dust collector 13; the outlet of the electrostatic dust collector 13 is connected with the inlet of a bag-type dust collector 16 through a pipeline, and the pipeline is connected with a limestone conveying system 14 and an active carbon conveying system 15; an outlet of the bag-type dust collector 16 is connected with an inlet of the wet desulphurization tower 18 through an induced draft fan 17; the outlet of the wet desulphurization tower 18 is connected with the inlet of a wet electric dust collector 19; the outlet of the wet electro precipitator 19 is connected to a stack 20.
The boiler incineration system 12 is also connected to the steam dryer 8 for providing steam to the steam dryer 8.
The chimney 20 is a sleeve type chimney.
The second screw conveyor 9 adopts a shaftless screw conveyor.
The steam dryer 8 adopts a disc type dryer, and the disc type dryer is characterized by comprising the following components in parts by weight:
because the single-shaft disc combined hollow shaft is adopted for heat transfer, a can manufacturing process is introduced during the body manufacturing, the reliability of the body is improved, and the manufacturing cost is reduced.
(1) An air supply port is arranged, so that the tail gas emission is smoother, and the system load is reduced;
(2) the reliability is high, the continuous operation is good, the operation can be performed day and night, and the method is suitable for drying materials with large treatment capacity for a long time;
(3) the oxygen content, the temperature and the dust amount are low during operation, and the safety is good;
(4) the left surface and the right surface of each vertical disc transfer heat, so that the heat transfer area is large, the structure is compact, and the overall dimension is small;
(5) the auxiliary equipment is less, and the system is simple;
(6) the material in the drier has high water content, and in order to prevent the material from being bonded on the turnplate, a fixed longer scraper is arranged on the inner wall of the shell and extends into a gap between the turnplates to play roles in stirring and cleaning the turnplate surface;
(7) the low-temperature heat source is adopted for heating, so that the sludge on the disc cannot be overheated when the disc is stopped;
(8) the required auxiliary air is less, and tail gas treatment equipment is small;
(9) can be applied to a semi-drying process and a full-drying process;
(10) the cover on the upper part of the machine body can be completely opened, so that the maintenance is convenient;
(11) the maintenance is less, the continuous operation is good, the operation can be performed day and night, and the operation in 8000 hours every year is ensured;
(12) the emergency starting can be realized in a power failure state, and the operation is stable;
(13) the structure is firm and durable.
A working method of a sludge mixing drying pure combustion power generation system comprises the following steps:
(1) and conveying the sludge solution with the water content of 95-97% in the sewage treatment plant to a concentrated sewage tank 1 by a sludge pump for storage, and only adding a medicament PAM for tempering, wherein the absolute dry mass ratio of the addition amount is about 1 per mill.
(2) And (3) conveying the sludge with the water content of 95-97% in the concentrated sewage pool 1 to a plate-and-frame filter press 3 through a sludge screw pump 2 for press filtration and dehydration, outputting the sludge to a sludge crusher 5 for crushing through a belt conveyor 4 after the sludge is dehydrated to the water content of 65%, and temporarily storing the crushed sludge in a semi-dry sludge bin 6.
Chemical pretreatment is carried out on the sludge to break cell walls in the chemical tempering process of the chemical tempering, so that the internal moisture in the sludge is easy to separate out, the specific resistance of the sludge is reduced, and the sludge is easy to dehydrate. The common methods are as follows: lime treatment, acid treatment, alkali treatment, polymeric flocculant treatment and the like. The utility model discloses a polymer PAM (polyacrylamide), the effect is showing, and PAM is a water-soluble polymer, belongs to polyelectrolyte. The operation effect of the filter press is improved by adding the chemicals, and the reason is that after the chemicals are added and modified, sludge forms larger floc and free water is easier to remove. Under the condition that other conditions are not changed, the proportion of the water removed by gravity in the sludge is increased, the solid content of the dewatered sludge cake is obviously increased, and the sludge can be efficiently dewatered to the sludge cake with the water content of about 65 percent.
(3) And conveying the sludge into a steam dryer 8 for drying from an outlet of the semi-dry sludge bin 6 by adopting a first screw conveyor 7 until the water content is below 45%, wherein the dried sludge has a basic low calorific value of 1000kcal/kg, and the pure sludge burning condition of a fluidized bed furnace incineration system is met.
The steam dryer 8 adopts superheated steam of 0.5MPa (absolute pressure) and 200 ℃ as drying heating media, the steam enters the dryer from a steam inlet of a hollow shaft of the dryer and a steam inlet of an annular part of a body respectively to carry out indirect heat exchange drying on sludge, the minimum steam consumption of each ton of wet sludge (the moisture content is dried from 65% to 45%) of the steam dryer 8 is about 0.42t, and the minimum steam consumption is about 0.24t, which is equivalent to the drying steam consumption of each ton of 80% moisture sludge. In order to prevent the water vapor evaporated in the drying process from dewing and improve the drying speed, air is used as carrier gas to reduce the partial pressure of the water vapor in the dryer and bring the water vapor out of the dryer in time. And tail gas (water vapor and air) generated in the sludge drying process is discharged out of the dryer through the induced draft fan, and the micro-negative pressure operation of the system is maintained. The extracted tail gas is subjected to two-stage treatment of dust removal and condensation, and the tail gas condensate enters a wastewater tank and is collected and then sent to a sewage treatment plant. Non-condensable gas (mainly air and a small amount of malodorous gas) is fed into the incinerator as primary air to be incinerated. The steam condensate water after heat exchange is collected in a concentrated mode through a condensate water tank and then conveyed to a deaerator through a drainage pump for recycling. The temperature of the dried sludge is about 90 ℃, and the dried sludge is cooled to be lower than 50 ℃ and then is conveyed to a boiler for combustion. And cooling the tail gas, the dry mud and the steam condensed water by using the cooling tower to recycle the cooling water.
(4) The sludge dried by the steam dryer 8 is conveyed to a dry sludge storage bin 10 for storage through a second screw conveyor 9, and the dry sludge in the dry sludge storage bin 10 is conveyed to a fluidized bed furnace incineration system 12 for incineration through a weighing feeder 11.
The combustion air of the fluidized bed combustion system 12 is divided into primary air and secondary air. The secondary fan is used for air suction and deodorization from the sludge storage. After being heated to 290 ℃ by an air preheater, primary air enters a combustion chamber from an air chamber at the bottom of a hearth to participate in combustion. After the secondary air is heated to 308 ℃ by an air preheater, the secondary air is divided into an upper layer and a lower layer by bilateral symmetry from the side wall of the hearth, and the upper layer and the lower layer are sent into the furnace for combustion in a grading way. In order to ensure that the fluidized bed can better adapt to the change of various working conditions, the front air duct of the secondary air inlet chamber is respectively provided with an adjusting valve so as to adapt to the air volume and the air pressure requirements of various working conditions.
High-temperature flue gas generated by sludge combustion carries a large amount of bed materials to be turned through the top of the furnace, and gas-solid separation is carried out through a high-temperature cyclone separator. Meanwhile, because the temperature of the region is about 850 ℃, the flue gas is better mixed, and the concentration of NOx can be reduced to 50mg/Nm by arranging the SNCR ammonia water injection point to inject ammonia water3The following. The separated flue gas containing a small amount of fly ash enters a horizontal flue and a vertical shaft behind the furnace, heat is released to a high-temperature superheater, a low-temperature superheater, an economizer and an air preheater which are arranged in the horizontal flue and the vertical shaft, the temperature of the flue gas is reduced to about 161 ℃, most of acid gas, heavy metal, dioxin and fine particles in the flue gas are removed by a flue gas purification device (a dust removal device, a desulfurization device and the like), and the flue gas is sent to a chimney by a draught fan and is discharged into the atmosphere.
(5) The flue gas of the fluidized bed furnace incineration system 12 is dedusted by an electrostatic precipitator 13, and then is subjected to acid and odor removal by spraying limestone and activated carbon and then enters a bag-type deduster 16 for further dedusting. The flue gas enters a wet desulphurization tower 18 through a draught fan 17 for desulphurization, a wet electric dust collector 19 arranged at the outlet of the wet desulphurization tower 18 further reduces dust in the flue gas, so that most of acid gas, heavy metal, dioxin and fine particles in the flue gas are removed, and the treated clean flue gas is discharged through a chimney 20.
The initial dust concentration at the outlet of the boiler is 51g/Nm3Left and right, the flue gas dust removal considers primary static electricity, cloth bag and humidityThe three-stage dust removal mode of the electric dust remover. The system ensures that about 80 percent of ash is removed by the electrostatic dust collector 13, and the dust concentration of the bag-type dust collector 16 is 20mg/Nm3The dust concentration at the outlet 13 of the wet electric dust collector is 5mg/Nm3The following. The dry ash collected in the ash storehouse under the electrostatic precipitator 13 is conveyed in two ways: one path is directly conveyed into an ash tank car by a scraper conveyor for outward transportation, and the other path can be conveyed to an ash warehouse for temporary storage by a pneumatic ash conveying system. The dry ash collected by the bag-type dust collector 16 is intensively conveyed to an ash storehouse for temporary storage by a pneumatic ash conveying system.
By adopting limestone-gypsum wet desulphurization and soda alkali liquor desulphurization processes, SO at the outlet of the chimney can be ensured2The content is 35mg/Nm3The following.
As can be seen from the above, the utility model has the following advantages and effects:
1. the sludge drying process is advanced. The utility model discloses machinery and steam combination mummification + fluidized bed furnace incineration power generation technology, make full use of machinery filter-pressing dehydration initial stage is effectual, the controllable advantage of steam mummification mud dryness fraction, look for the process design balance point, can carry out mechanical filter-pressing dehydration to moisture content about 65% with wet mud, the mud further mummification that the heat energy steam that recycles the mud incineration production about with moisture content 65% falls to below 45% to the moisture content, make wet mud decrement about 37% of former volume, dehydration dry mud (45% moisture content) calorific value is about 1000kcal/kg (initial mud absolute dry calorific value is according to 2300kcal/kg as the example), satisfy the pure mud condition of burning of fluidized bed combustion boiler and go into the stove.
2. The sludge drying energy consumption loss is small, and the drying energy consumption is low. In the initial stage of sludge dehydration, namely the stage of dehydrating sewage with 95-97% of moisture to sludge with 65% of moisture, a mechanical filter pressing mode is adopted, latent heat of vaporization is not consumed, and heat consumption is low; in the deep sludge dewatering stage, namely the sludge stage of drying the sludge with 65% of water content to below 45% of water content, a steam drying mode is adopted, the steam consumption of single ton of sludge with 80% of water content for drying is only about 0.24t, the energy consumption is greatly saved, and the drying cost is reduced.
3. Does not mix any auxiliary fuel such as coal, natural gas and the like. When the absolute dry low-grade calorific value of the sludge reaches 2300kcal/kg, the wet sludge is dried to 65 percent of moisture content through a machine and is dried to the moisture content of below 45 percent through a steam dryer, the sludge can be purely burned through a fluidized bed furnace to completely maintain the self-balance of sludge burning energy, no auxiliary fuel is required to be co-burned, and national resources are saved.
4. The single ton sludge treatment cost is low. The operation cost of single ton of 80% moisture sludge treatment can be as low as 63.05 yuan/ton, which is far lower than the operation cost of domestic current mainstream sludge drying and incinerating sludge treatment of 200 yuan/ton.
The utility model discloses use the wet mud of 2000t/d of daily processing (80% moisture content), mud absolute dry heat value 2300kcal/kg as the example, main technical and economic index is as follows:
in addition, it should be noted that the specific embodiments described in the present specification may be different in the components, the shapes of the components, the names of the components, and the like, and the above description is only an example of the structure of the present invention. All the equivalent changes or simple changes made according to the structure, characteristics and principle of the utility model are included in the protection scope of the utility model. Various modifications, additions and substitutions may be made by those skilled in the art without departing from the scope of the invention as defined in the accompanying claims.
Claims (5)
1. The utility model provides a pure power generation system that burns of mud mixed mummification which characterized in that: the system comprises a concentrated sewage pool, a sludge screw pump, a plate-and-frame filter press, a belt conveyor, a sludge crusher, a semi-dry sludge bin, a screw conveyor I, a steam dryer, a screw conveyor II, a dry sludge storage bin, a weighing feeder, a fluidized bed furnace incineration system, an electrostatic dust collector, a limestone conveying system, an active carbon conveying system, a bag-type dust collector, an induced draft fan, a wet desulfurization tower, a wet electric dust collector and a chimney; the outlet of the concentrated sewage tank is connected with the inlet of the plate-and-frame filter press through a pipeline, and a sludge screw pump is arranged on the pipeline; the outlet of the plate-and-frame filter press is connected with the inlet of the sludge crusher through a belt conveyor; the outlet of the sludge crusher is connected with the inlet of the semi-dry sludge bin; an outlet of the half-dry sludge bin is connected with an inlet of the steam dryer through a first screw conveyor; the outlet of the steam dryer is connected with the inlet of the dry sludge storage bin through a second screw conveyor; the outlet of the dry sludge storage bin is connected with the inlet of the fluidized bed furnace incineration system through a weighing feeder; the flue gas outlet of the fluidized bed furnace incineration system is connected with the inlet of the electrostatic dust collector; the outlet of the electrostatic dust collector is connected with the inlet of the bag-type dust collector through a pipeline, and the pipeline is connected with a limestone conveying system and an active carbon conveying system; the outlet of the bag-type dust collector is connected with the inlet of the wet desulphurization tower through a draught fan; the outlet of the wet desulphurization tower is connected with the inlet of the wet electric dust collector; the outlet of the wet electric dust collector is connected with a chimney.
2. The sludge mixed drying pure combustion power generation system as claimed in claim 1, wherein: the chimney is a sleeve chimney.
3. The sludge mixed drying pure combustion power generation system as claimed in claim 1, wherein: and the second spiral conveyor is a shaftless spiral conveyor.
4. The sludge mixed drying pure combustion power generation system as claimed in claim 1, wherein: the steam dryer is a disc dryer.
5. The sludge mixed drying pure combustion power generation system as claimed in claim 1, wherein: the fluidized bed furnace incineration system is also connected with a steam dryer.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201921571409.3U CN211170408U (en) | 2019-09-20 | 2019-09-20 | Sludge mixing drying pure combustion power generation system |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201921571409.3U CN211170408U (en) | 2019-09-20 | 2019-09-20 | Sludge mixing drying pure combustion power generation system |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CN211170408U true CN211170408U (en) | 2020-08-04 |
Family
ID=71794114
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN201921571409.3U Active CN211170408U (en) | 2019-09-20 | 2019-09-20 | Sludge mixing drying pure combustion power generation system |
Country Status (1)
| Country | Link |
|---|---|
| CN (1) | CN211170408U (en) |
Cited By (3)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN110606648A (en) * | 2019-09-20 | 2019-12-24 | 中国联合工程有限公司 | Sludge mixing drying pure combustion power generation system and working method thereof |
| CN112128778A (en) * | 2020-08-14 | 2020-12-25 | 安吉临港热电有限公司 | Dust-free sludge incineration device and incineration process thereof |
| CN114893780A (en) * | 2022-06-14 | 2022-08-12 | 上海市政工程设计研究总院(集团)有限公司 | Combined feeding system for sludge incineration and sludge incineration method |
-
2019
- 2019-09-20 CN CN201921571409.3U patent/CN211170408U/en active Active
Cited By (3)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN110606648A (en) * | 2019-09-20 | 2019-12-24 | 中国联合工程有限公司 | Sludge mixing drying pure combustion power generation system and working method thereof |
| CN112128778A (en) * | 2020-08-14 | 2020-12-25 | 安吉临港热电有限公司 | Dust-free sludge incineration device and incineration process thereof |
| CN114893780A (en) * | 2022-06-14 | 2022-08-12 | 上海市政工程设计研究总院(集团)有限公司 | Combined feeding system for sludge incineration and sludge incineration method |
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| CN211170408U (en) | Sludge mixing drying pure combustion power generation system | |
| CN105948459A (en) | Method using drying and incineration to treat sludge | |
| CN105439404A (en) | Sludge dewatering, drying and incinerating system and method | |
| CN103090396A (en) | Two-stage drying and incineration method for sludge | |
| CN109231781A (en) | A kind of sludge drying coupling coal generating system and method | |
| CN104628237B (en) | Sludge drying incineration system based on thermal power plant | |
| CN205313341U (en) | Sludge dewatering drying combustion system | |
| CN101216244A (en) | Spiral and rotary type sludge drying shaping apparatus | |
| CN111288463A (en) | Sludge drying and incinerating system and drying and incinerating method | |
| CN105202549B (en) | Coal sludge mixture burning control system based on two medium flue gas dryings and Geldart-D particle | |
| CN110606648A (en) | Sludge mixing drying pure combustion power generation system and working method thereof | |
| CN108083607A (en) | A kind of sludge drying coupling coal generating system and method | |
| CN111425866A (en) | Power station boiler low NO for coupling semicoke and sludge mixed burningxMixed combustion system | |
| CN104692603A (en) | Integral treatment system for sludge | |
| CN109899802A (en) | Drying particles sludge cooperates with power generation by waste combustion system and method with rubbish in grate furnace | |
| CN109824238A (en) | A kind of coal-fired coupling sludge heating system and method | |
| CN207659297U (en) | Sludge drying couples coal generating system | |
| CN113121082A (en) | Device and method for resource utilization and harmless treatment of oily sludge | |
| CN215886751U (en) | Sludge two-stage drying pyrolysis disposal system | |
| CN111807671A (en) | Sludge incineration and carbonization cooperative treatment system | |
| CN112111302A (en) | Low-order material gasification combustion and flue gas pollutant control integrated process and device and application | |
| CN111810961A (en) | Sludge incineration and carbonization cooperative treatment method | |
| CN112628736A (en) | Sludge coupling coal-fired generator set recycling treatment system, process and application | |
| CN201670798U (en) | Sludge drying incineration system | |
| CN113929276B (en) | Treatment method of coal gasification sludge and coal gasification production method |
Legal Events
| Date | Code | Title | Description |
|---|---|---|---|
| GR01 | Patent grant | ||
| GR01 | Patent grant |