CN210457893U

CN210457893U - Sludge regeneration fuel production system

Info

Publication number: CN210457893U
Application number: CN201921228621.XU
Authority: CN
Inventors: 耿谊; 徐振宇; 靳晓杰; 谢光磊
Original assignee: Luoyang Zhong Xin Energy Renewable Energy Co Ltd
Current assignee: Luoyang Zhong Xin Energy Renewable Energy Co Ltd
Priority date: 2019-07-31
Filing date: 2019-07-31
Publication date: 2020-05-05
Anticipated expiration: 2029-07-31

Abstract

A production system of sludge regenerated fuel is provided, wherein a feeding stirring mechanism is arranged in a mixing area, a storage area is arranged on one side of the mixing area, a storage mechanism is arranged in the storage area, a production area is arranged on one side of the storage area, a batching stirring mechanism is arranged in the production area, a turning area is arranged on one side of the production area, a turning and collecting mechanism is arranged in the turning area, a finished product storage area is arranged on one side of the turning area, a mixed sludge conveying belt is arranged between the mixing area and the storage area, a dewatered sludge conveying belt is arranged between the storage area and the production area, a regenerated fuel conveying belt is arranged between the production area and the turning area, and a finished product conveying belt is arranged between the turning; the utility model discloses a turning over the sunning and further reducing the water content of product to 14-20%, very big improvement produce can and each item index such as burning, adopt control system control, save manual operation and intervention, very big improvement production efficiency.

Description

Sludge regeneration fuel production system

Technical Field

The utility model relates to an urban solid waste handles and deals with the comprehensive field of recycling, especially relates to a mud renewable fuel production system.

Background

With the increasing importance of the country on environmental protection, the country has come out a series of relevant environmental protection policies one after another, and the town sludge is a chronic disease which puzzles the urban environmental management for a long time. At present, the main treatment mode of the sludge in cities and towns in China is landfill treatment, the method has relatively less investment but needs to occupy land, meanwhile, a lot of harmful materials in the sludge are temporarily not eliminated, and a waterproof and impermeable landfill pit needs to be invested and constructed during direct landfill, otherwise, secondary pollution is caused to the environment and underground water sources, and the elimination of pollution sources is not realized; secondly, the town sludge is subjected to drying incineration, land composting utilization and anaerobic digestion, wherein the drying incineration equipment has higher investment and operation cost, and the dioxin in fly ash and smoke gas generated after direct incineration is difficult to treat, so that the popularization is difficult to develop in China; in the land composting utilization, sludge is fermented by microorganisms in an aerobic environment to obtain an organic fertilizer, and various heavy metals in the sludge cannot be converted and directly enter a plant growth link, so that the organic fertilizer has great harm to people; anaerobic digestion is a treatment mode of producing sludge into methane by biochemical reaction of bacteria and anaerobic bacteria, the mode has a longer conversion period and cannot be subjected to large-scale industrialized treatment, and simultaneously newly generated biogas residues are more difficult to treat and dispose due to pollutant aggregation;

the patent number is ZL 201310420832.4's an equipment and working process that changes sludge modification futilely into regenerative fuel, control system control is adopted in this patent, save manual operation and intervention, be sludge innoxious, the ideal mode of resourceful treatment processing, however, the water content of the product that this patent produced is big, if directly put into combustion apparatus, often because of moisture content is high itself, after evaporating moisture content with the help of external heat energy earlier usually, can burn again, not only fuel can not provide heat energy in earlier stage just caused, consume the phenomenon of heat energy on the contrary, often can appear the temperature and carry not high, still can reduce combustion temperature, can also cause the pressure fire in the serious time, flame-out phenomenon.

In view of the above, a sludge regeneration fuel production system has been developed.

SUMMERY OF THE UTILITY MODEL

The utility model aims at overcoming the not enough among the prior art, provide a mud regenerative fuel production system, further reduce the water content of product to 14-20% through turning over the sunning of throwing, very big improvement produce each item index such as property ability and burning, adopt control system control, save manual operation and intervention, very big improvement production efficiency.

The utility model discloses a realize above-mentioned purpose, adopt following technical scheme: a sludge regeneration fuel production system comprises: the device comprises a mixing area, a raw sludge feeding hopper, a demulsifier storage hopper, a sludge stirring mechanism, a storage area, a storage bin, a production area, a sludge buffer hopper, an auxiliary material buffer hopper, a stirring main station, a semi-finished product bin, an auxiliary material storage hopper, an auxiliary material conveying belt, an auxiliary material metering mechanism, an additive hopper, a turning and throwing area, a turning and throwing machine walking area, a turning and throwing machine, a finished product collecting conveying belt, a finished product storage area, a mixed sludge conveying belt, a dewatered sludge conveying belt, a regenerated fuel conveying belt, a finished product conveying belt, a demulsifier metering hopper, a sludge metering hopper, an additive metering hopper and a feeding screw; the production line comprises a mixing area, a production area, a turning and collecting mechanism, a finished product storage area, a mixed sludge conveying belt, a dehydrated sludge conveying belt, a regenerated fuel conveying belt and a finished product conveying belt, wherein a feeding and stirring mechanism is arranged in the mixing area, a storage area is arranged on one side of the mixing area, the storage mechanism is arranged in the storage area, a production area is arranged in the production area, the finished product storage area is arranged on one side of the turning area, the ingredient stirring mechanism is arranged in the production area, the turning area is arranged on one side of the production area, the turning and collecting mechanism is arranged in the turning area.

The structure of the feeding and stirring mechanism is as follows: the raw sludge feeding hopper is arranged above one side of the sludge stirring mechanism, the demulsifier storage hopper is arranged above the other side of the sludge stirring mechanism, the demulsifier metering hopper is arranged between the demulsifier storage hopper and the sludge stirring mechanism, the feeding screw is arranged between the discharging port of the demulsifier storage hopper and the feeding port of the demulsifier metering hopper, the feeding screw is arranged between the discharging port of the raw sludge feeding hopper, the discharging port of the demulsifier metering hopper and the feeding port of the sludge stirring mechanism, and the feeding end of the mixed sludge conveying belt is positioned below the discharging port of the sludge stirring mechanism.

The structure of the storage mechanism is as follows: set up at least one in the storage area and store the storehouse, the discharge end that mixes the sludge conveyer belt is located the top of storing the storehouse, and the rear end that mixes the sludge conveyer belt sets up feed mechanism, and the discharge gate below of storing the storehouse sets up the sludge metering hopper, and the discharge gate below of sludge metering hopper sets up the pay-off spiral, and the feed end of the sludge conveyer belt after the dehydration is located the below of pay-off spiral discharge end.

The structure of the batching and stirring mechanism is as follows: sludge buffer fills one side and sets up auxiliary material buffer fill, the discharge end of the sludge conveyer belt after the dehydration is located the top that sludge buffer held the fill, auxiliary material buffer held one side and sets up the auxiliary material and store the fill, auxiliary material stores the discharge gate below of fighting and sets up auxiliary material metering mechanism, set up the auxiliary material conveyer belt between auxiliary material metering mechanism's below and the feed inlet of auxiliary material storage fill, sludge buffer held fill top one side and sets up the admixture fill, admixture fill below sets up the admixture weighing hopper, set up the pay-off spiral between the discharge gate of admixture hopper and the feed inlet of admixture weighing hopper, sludge buffer held fill below sets up the stirring main website, the feed inlet and the sludge buffer hold of stirring main website are fought, set up the pipeline between the discharge gate of auxiliary material buffer held and admixture weighing hopper, the discharge gate below of stirring main website sets up semi-finished product storehouse.

The turning and collecting mechanism is structurally characterized in that: the turning and throwing device comprises a turning and throwing area, a finished product collecting and conveying belt, a regenerated fuel conveying belt, a finished product conveying belt and a finished product collecting and conveying belt, wherein at least one turning and throwing machine walking area is arranged in the turning and throwing area, the turning and throwing machine is arranged in the turning and throwing machine walking area, the finished product collecting and conveying belt is arranged on one side of the turning and throwing machine walking area, the discharge end of the regenerated fuel conveying belt is located at the front end of the turning and throwing machine walking area, the front end of the finished product conveying belt is located.

The working principle is as follows: the method comprises the steps that raw sludge and demulsifier are conveyed into a raw sludge feeding hopper and a demulsifier storage hopper through a loading mechanism respectively, when a raw sludge and demulsifier feeding system is started, the system collects the weight of the raw sludge through a metering mechanism in the raw sludge feeding hopper, the required amount of the demulsifier is calculated according to the set ratio of the raw sludge and the demulsifier, the demulsifier in the demulsifier storage hopper is conveyed into a demulsifier metering hopper through a feeding screw of the demulsifier storage hopper for metering, when the set value is reached, the feeding screw of the demulsifier storage hopper is closed, the feeding screw of the raw sludge feeding hopper and the feeding screw of the demulsifier metering hopper are started, the raw sludge and the demulsifier are simultaneously fed into a sludge stirring mechanism, and after the raw sludge in the raw sludge feeding hopper and the demulsifier in the demulsifier metering hopper are fed, the feeding screw of the raw sludge feeding hopper and the feeding screw of the demulsifier are closed through the system, starting a sludge stirring mechanism, stirring and mixing original sludge and a demulsifier in a stirring container by a helical blade of the sludge stirring mechanism to fully mix and react the original sludge and the demulsifier, releasing biological intracellular water of the sludge, changing the intracellular water into extracellular water, conveying the stirred sludge into a storage bin through a mixed sludge conveying belt, standing the mixture in the storage bin for 24 hours to fully perform a physical and chemical reaction on the sludge, and removing water in the sludge;

according to the proportion and the dosage of the sludge, the auxiliary materials and the admixture set by the system, when the sludge production is started, the batching process is firstly executed through the system:

opening a valve at the bottom of the storage bin, feeding sludge in the storage bin into a sludge metering hopper below the storage bin for metering, closing the valve of the storage bin when a set value is reached, and metering and throwing the sludge in the sludge metering hopper to a sludge cache hopper for temporary storage through a feeding screw of the sludge metering hopper and a dewatered sludge conveying belt; opening a valve at the bottom of the auxiliary material storage hopper, metering the auxiliary material in the auxiliary material storage hopper through an auxiliary material metering mechanism below the auxiliary material storage hopper, closing the valve of the auxiliary material storage hopper when a set value is reached, and conveying the auxiliary material in the auxiliary material metering mechanism to an auxiliary material cache hopper through an auxiliary material conveying belt for temporary storage; opening a valve at the bottom of the additive hopper, feeding the additive in the additive hopper into the additive metering hopper through a feeding screw of the additive hopper for metering, and closing the valve of the additive hopper when a set value is reached;

after the batching is finished, starting a stirring main station, opening valves at the bottoms of a sludge buffer hopper, an auxiliary material buffer hopper and an additive metering hopper, putting the batched materials into the stirring main station for stirring and mixing, and after the stirring is finished, allowing the stirred semi-finished sludge in the stirring main station to enter a semi-finished product bin to finish the sludge modification into the renewable fuel, wherein the water content of the renewable fuel at the moment is 40-60%;

opening a valve at the bottom of the semi-finished product bin, conveying the regenerated fuel in the semi-finished product bin to a turner through a regenerated fuel conveying belt, sequentially spreading the regenerated fuel on the turner into a spreading area below the running of the turner, conveying the regenerated fuel in the spreading area to a finished product conveying belt through the turner and a finished product collecting conveying belt after turning, throwing and airing, and conveying the regenerated fuel to a finished product storage area through the finished product conveying belt, wherein the water content of the regenerated fuel at the moment is 14-20%.

The utility model has the advantages that: the utility model discloses a turning over the sunning and further reducing the water content of product to 14-20%, very big improvement produce each item index such as property ability and burning, adopt control system control, save manual operation and intervention, the utility model discloses the investment is little, and the running cost is low, and production efficiency is high, realizes the new mode of mud innocent treatment.

Drawings

The present invention will be further explained with reference to the accompanying drawings:

FIG. 1 is a schematic view of the assembly structure;

FIG. 2 is a schematic diagram of a mixing zone configuration;

FIG. 3 is a schematic diagram of a storage region structure;

FIG. 4 is a schematic view of a production zone configuration;

FIG. 5 is a schematic view of the structure of the turning zone;

in fig. 1, 2, 3, 4, 5: the device comprises a mixing area 1, a raw sludge feed hopper 1.1, a demulsifier storage hopper 1.2, a sludge stirring mechanism 1.3, a storage area 2, a storage bin 2.1, a production area 3, a sludge buffer bin 3.1, an auxiliary material buffer bin 3.2, a stirring main station 3.3, a semi-finished product bin 3.4, an auxiliary material storage hopper 3.5, an auxiliary material conveying belt 3.6, an auxiliary material metering mechanism 3.7, an additive hopper 3.8, a turning and throwing area 4, a turning and throwing machine walking area 4.1, a turning and throwing machine 4.2, a finished product collecting and conveying belt 4.3, a finished product storage area 5, a mixed sludge conveying belt 6, a dewatered sludge conveying belt 7, a regenerated fuel conveying belt 8, a finished product conveying belt 9, a demulsifier metering hopper 10, a sludge metering hopper 10.1, an additive metering hopper 10.2 and a feeding screw 11.

Detailed Description

The present invention will be described in further detail with reference to the following detailed description and accompanying drawings:

the production line comprises a mixing area 1, a material feeding and stirring mechanism, a storage area 2, a storage mechanism, a production area 3, a material mixing and stirring mechanism, a turning and throwing area 4, a turning and throwing collecting mechanism, a finished product storage area 5, a mixed sludge conveying belt 6, a dewatered sludge conveying belt 7, a regenerated fuel conveying belt 8 and a finished product conveying belt 9, wherein the material feeding and stirring mechanism is arranged in the mixing area 1, the storage area 2 is arranged on one side of the mixing area 1, the production area 3 is arranged on one side of the production area 3, the turning and throwing collecting mechanism is arranged in the turning and throwing area 4, the finished product storage area 5 is arranged on one side of the turning and throwing area 4, the mixed sludge conveying belt 6 is arranged between the mixing area 1 and the storage area 2.

The structure of the feeding and stirring mechanism is as follows: the former state sludge feeding hopper 1.1 is arranged above one side of the sludge stirring mechanism 1.3, the demulsifier storage hopper 1.2 is arranged above the other side of the sludge stirring mechanism 1.3, the demulsifier weighing hopper 10 is arranged between the demulsifier storage hopper 1.2 and the sludge stirring mechanism 1.3, the feeding screw 11 is arranged between the discharge port of the demulsifier storage hopper 1.2 and the feed port of the demulsifier weighing hopper 10, the discharge port of the former state sludge feeding hopper 1.1, the feeding screw 11 is arranged between the discharge port of the demulsifier weighing hopper 10 and the feed port of the sludge stirring mechanism 1.3, and the feed end of the mixed sludge conveying belt 6 is positioned below the discharge port of the sludge stirring mechanism 1.3.

The structure of the storage mechanism is as follows: set up at least one in the storage area 2 and store storehouse 2.1, the discharge end that mixes sludge conveyer belt 6 is located the top of storing storehouse 2.1, and the rear end that mixes sludge conveyer belt 6 sets up feed mechanism, and the discharge gate below of storing storehouse 2.1 sets up the mud weighing hopper 10.1, and the discharge gate below of mud weighing hopper 10.1 sets up pay-off spiral 11, and the feed end of the sludge conveyer belt 7 after the dehydration is located the below of the 11 discharge ends of pay-off spiral.

The structure of the batching and stirring mechanism is as follows: an auxiliary material buffer storage hopper 3.2 is arranged at one side of a sludge buffer storage hopper 3.1, the discharge end of a dewatered sludge conveying belt 7 is positioned above the sludge buffer storage hopper 3.1, an auxiliary material storage hopper 3.5 is arranged at one side of the auxiliary material buffer storage hopper 3.2, an auxiliary material metering mechanism 3.7 is arranged below the discharge port of the auxiliary material storage hopper 3.5, an auxiliary material conveying belt 3.6 is arranged between the lower part of the auxiliary material metering mechanism 3.7 and the feed inlet of the auxiliary material storage hopper 3.5, an additive hopper 3.8 is arranged at one side above the sludge buffer storage hopper 3.1, an additive metering hopper 10.2 is arranged below the additive hopper 3.8, a feeding screw 11 is arranged between the discharge port of the additive hopper 3.8 and the feed inlet of the additive metering hopper 10.2, a stirring main station 3.3 is arranged below the sludge buffer storage hopper 3.1, a pipeline is arranged between the feed inlet of the stirring main station 3.3.3 and the sludge buffer storage hopper 3.1, a pipeline is arranged between the auxiliary material buffer storage hopper 3.2 and the, the feeding end of the regenerated fuel conveying belt 8 is positioned below the discharging port of the semi-finished product bin 3.4.

The turning and collecting mechanism is structurally characterized in that: at least one turner walking area 4.1 is arranged in the turner area 4, a turner 4.2 is arranged in the turner walking area 4.1, a finished product collecting and conveying belt 4.3 is arranged on one side of the turner walking area 4.1, the discharge end of the regenerated fuel conveying belt 8 is positioned at the front end of the turner walking area 4.1, the front end of the finished product conveying belt 9 is positioned at the rear end of the turner walking area 4.1, and the discharge end of the finished product collecting and conveying belt 4.3 is positioned above the feed end of the finished product conveying belt 9.

Claims

1. A sludge regeneration fuel production system comprises: a mixing area (1), a raw sludge feed hopper (1.1), a demulsifier storage hopper (1.2), a sludge stirring mechanism (1.3), a storage area (2), a storage bin (2.1), a production area (3), a sludge buffer hopper (3.1), an auxiliary material buffer hopper (3.2), a stirring master station (3.3), a semi-finished product bin (3.4), an auxiliary material storage hopper (3.5), an auxiliary material conveyer belt (3.6) and an auxiliary material metering mechanism (3.7), the device comprises an additive hopper (3.8), a turning region (4), a turning machine walking region (4.1), a turning machine (4.2), a finished product collecting and conveying belt (4.3), a finished product storage region (5), a mixed sludge conveying belt (6), a dewatered sludge conveying belt (7), a regenerated fuel conveying belt (8), a finished product conveying belt (9), a demulsifier measuring hopper (10), a sludge measuring hopper (10.1), an additive measuring hopper (10.2) and a feeding screw (11); the method is characterized in that: the device is characterized in that a feeding and stirring mechanism is arranged in a mixing area (1), a storage area (2) is arranged on one side of the mixing area (1), a storage mechanism is arranged in the storage area (2), a production area (3) is arranged on one side of the storage area (2), a batching and stirring mechanism is arranged in the production area (3), a turning and throwing area (4) is arranged on one side of the production area (3), a turning and throwing collecting mechanism is arranged in the turning and throwing area (4), a finished product storage area (5) is arranged on one side of the turning and throwing area (4), a mixed sludge conveying belt (6) is arranged between the mixing area (1) and the storage area (2), a dewatered sludge conveying belt (7) is arranged between the storage area (2) and the production area (3), a regenerated fuel conveying belt (8) is arranged between the production area (3) and the turning and throwing area (4), and a finished product conveying belt (9).

2. The system for producing sludge regeneration fuel according to claim 1, wherein: the structure of the feeding and stirring mechanism is as follows: the sludge stirring mechanism (1.3) one side top sets up original state sludge feeding hopper (1.1), sludge stirring mechanism (1.3) opposite side top sets up demulsifier and stores fill (1.2), set up demulsifier weighing hopper (10) between demulsifier storage fill (1.2) and sludge stirring mechanism (1.3), set up pay-off spiral (11) between the discharge gate of demulsifier storage fill (1.2) and the feed inlet of demulsifier weighing hopper (10), the discharge gate of original state sludge feeding hopper (1.1), all set up pay-off spiral (11) between the discharge gate of demulsifier weighing hopper (10) and the feed inlet of sludge stirring mechanism (1.3), the feed end that mixes sludge conveyer belt (6) is located the below of the discharge gate of sludge stirring mechanism (1.3).

3. The system for producing sludge regeneration fuel according to claim 1, wherein: the structure of the storage mechanism is as follows: set up at least one in storage area (2) and store storehouse (2.1), the discharge end that mixes sludge conveyer belt (6) is located the top of storing storehouse (2.1), the rear end that mixes sludge conveyer belt (6) sets up feed mechanism, the discharge gate below of storing storehouse (2.1) sets up mud batch hopper (10.1), the discharge gate below of mud batch hopper (10.1) sets up pay-off spiral (11), the feed end of sludge conveyer belt (7) after the dehydration is located the below of pay-off spiral (11) discharge end.

4. The system for producing sludge regeneration fuel according to claim 1, wherein: the structure of the batching and stirring mechanism is as follows: sludge buffer storage hopper (3.1) one side sets up auxiliary material buffer storage hopper (3.2), the discharge end of sludge conveyer belt (7) after the dehydration is located the top of sludge buffer storage hopper (3.1), auxiliary material buffer storage hopper (3.2) one side sets up auxiliary material storage hopper (3.5), the discharge gate below of auxiliary material storage hopper (3.5) sets up auxiliary material metering mechanism (3.7), set up auxiliary material conveyer belt (3.6) between the below of auxiliary material metering mechanism (3.7) and the feed inlet of auxiliary material storage hopper (3.5), sludge buffer storage hopper (3.1) top one side sets up admixture hopper (3.8), admixture hopper (3.8) below sets up admixture metering hopper (10.2), set up pay-off spiral (11) between the discharge gate of admixture hopper (3.8) and the main website feed inlet of admixture metering hopper (10.2), sludge buffer storage hopper (3.1) below sets up stirring main website (3.3), the feed inlet and sludge buffer storage hopper (3.1) of stirring main website (3.3.3), A pipeline is arranged between the discharge ports of the auxiliary material buffer hopper (3.2) and the additive metering hopper (10.2), a semi-finished product bin (3.4) is arranged below the discharge port of the stirring main station (3.3), and the feed end of the regenerated fuel conveying belt (8) is positioned below the discharge port of the semi-finished product bin (3.4).

5. The system for producing sludge regeneration fuel according to claim 1, wherein: the turning and collecting mechanism is structurally characterized in that: at least one turner walking area (4.1) is arranged in the turner area (4), a turner (4.2) is arranged in the turner walking area (4.1), a finished product collecting conveyer belt (4.3) is arranged on one side of the turner walking area (4.1), the discharge end of the regenerated fuel conveyer belt (8) is positioned at the front end of the turner walking area (4.1), the front end of the finished product conveyer belt (9) is positioned at the rear end of the turner walking area (4.1), and the discharge end of the finished product collecting conveyer belt (4.3) is positioned above the feed end of the finished product conveyer belt (9).