For the most commonly used minicipal sewage secondary treatment process-activated sludge process (including various deformation processes), some of the pollutants in the incoming sewage are removed by conversion to sludge. Therefore, municipal sewage sludge contains a wide range of pollutants, including various heavy metals, trace amounts of highly toxic organic matter (PCBs, AOX, etc.), and a large number of various pathogenic microorganisms (pathogenic bacteria, virions), parasitic eggs, harmful insect eggs, etc., as well as general oxygen-consuming organic matter and plant nutrients (N, P, K).

The discharge of sewage from minicipal sewage treatment plants into the water body will allow the above-mentioned pollutants to enter the entire regional water system by means of diffusion, transmission and conversion. In fact, the costly sewage treatment project will lose its proper environmental protection function (more than 70% in the sewage treatment plant). The contaminants in the removed sewage are simply replaced by a form or location into the water environment). The so-called municipal sewage sludge directly used for agriculture, although it may cause a certain amount of plant nutrients in the municipal sewage sludge to be used by plants, other pollutants may enter the food chain to threaten human food safety and infiltrate the ecology. The groundwater body of the system causes uncontrolled pollution transmission problems. The centralized storage of sludge from minicipal sewage plants will not only seriously affect the environmental sanitation conditions (odors, harmful insects, air with high density of disease-causing organisms) in the vicinity of the dumping site, but also entrain and entrain the pollutants from surface runoff. The infiltration of underground runoff causes a greater range of water pollution problems. The onshore storage and water discharge of municipal sewage sludge will also cause encroachment on land space, resulting in environmental and ecological problems such as excessive (accelerated) siltation of water.

At present, the most suitable treatment method for municipal sewage sludge is sludge hydrolysis carbonization units, which can directly treat municipal sewage sludge by using sludge dry distillation rotary kiln.

 

Municipal sludge produced in municipal facilities and municipal activities related to operational and maintenance processes, municipal sludge has a distinctive municipal character. According to the characteristics of municipal sludge, municipal sludge can be divided into the following five types.

1. Municipal sewage sludge

There are innumerable water use links in the municipal logistics system, and most of the water after use is converted into sewage sludge containing different types and concentrations of pollutants. The sewage sludge generated by the city can be divided into two categories according to the source: 1. industrial sewage sludge: from the industrial sector of the city, the pollution characteristics are determined by the corresponding industrial technology and process; 2. municipal sewage sludge: residential areas from the city, commercial service areas, etc. In the industrial sector, the pollution characteristics are less related to specific sources (such as commercial and residential areas), that is, the commonality of municipal sewage sludge from different sources is its main aspect.

The purification of municipal sewage sludge is also arranged separately by source. The main treatment target of municipal sewage treatment plants is municipal sewage sludge. In cities or regions where municipal drainage is implemented, runoff drainage from rainfall in some cities is also treated in municipal sewage treatment plants; at the same time, industrial sewage from some cities is also treated in municipal sewage treatment plants, but there are The requirements for industrial wastewater pretreatment make the pollution characteristics of industrial sewage entering municipal sewage treatment plants close to municipal sewage sludge (for example, for heavy metal industrial wastewater, it should be pretreated to remove most of the heavy metal pollution before it can be remitted to municipal sewage treatment plant.)

In the treatment of sewage in municipal sewage treatment plants, part of the pollutants in the sewage are converted into sedimentable substances, and the discharged objects are municipal sewage sludge characterized by solid-liquid mixing.

2. Municipal water supply sludge

Most of the water used in modern cities is tap water supply in the form of pipe network distribution. At present, most of the city’s water supply sources (raw water) can only meet the water quality requirements of the water supply after necessary purification treatment. The purification of raw water is carried out in a special water treatment plant (waterworks). The main treatment process is coagulation and sedimentation (transformation of particulate matter, colloids and partially soluble impurities in raw water into particles or colloidal substances that can be settled or filtered. And filtration (to complete the final removal of the above particles and colloids together with the precipitation), the removed particles and colloids constitute the solid phase portion of the municipal feed water sludge for the removal of these solid phase from the sedimentation tank and the filter Water constitutes the liquid phase portion of the sludge.

3. Municipal water dredged sludge

Municipal water bodies refer to natural or artificial water bodies (rivers, lakes, ponds, etc.) where the main catchment area is a built-up area of ​​the city. In addition to the functions of landscape and shipping, the main function of municipal water bodies is the components of municipal drainage channels and storage capacity. Due to the characteristics of the catchment area, municipal water bodies may receive water flows including municipal surface runoff, municipal sewage and industrial sewage. The particles and colloids entrained in these streams become sediments of municipal water bodies under certain hydraulic and hydrological conditions, and the soluble substances in the above-mentioned water streams will also form sedimentable substances in certain biological and chemical processes, which will be converted into Water sediments. The accumulation of water sediments will threaten the maintenance of the normal function of municipal water bodies. Therefore, municipal water bodies have the need for continuous conservation (dredging), and the water sediments after the flooding are the municipal water bodies that are mixed with solid water (bottom) and mud.

Even if the accelerated impact of municipal sewage and industrial sewage into municipal waters on the formation of sediments is not considered, the surface of the municipal catchment area is different from that of agriculture or natural ecosystems, and the surface with low water impermeability and roughness is Mainly, the ground sediments are easily entrained by runoff, and the impermeability of the underlying surface amplifies the intensity of runoff. In addition, the runoff mainly flows into the water body by means of pipeline flow, and the lack of non-urban river channel vegetation zone removes particulate matter from runoff. Buffering, therefore, the rate of sediment formation in municipal water bodies is higher than that in agricultural or natural ecosystems. The demand for dredging and maintenance of municipal water bodies has obvious municipal characteristics, and its sludge becomes one of the components of municipal sludge.

4. Municipal drainage channel sludge

Modern municipal drainage methods are characterized by pipelines. According to the principle of drainage objects and drainage system (drainage system), municipal drainage channels can be divided into three types: sewage channel, rain channel and combined drainage channel. According to the different choices of water flow in the channel, the drainage channel can also be divided into two types: gravity type and pressure type. No matter what kind of municipal drainage objects, they can contain sedimentable particles and colloids to varying degrees. At the same time, some soluble substances in the drainage also have the possibility of generating sedimentable substances under the environmental conditions and biological action in the drainage channel. Under certain channel hydraulic conditions, it will deposit in the channel and become a factor affecting the normal drainage function of the channel. In order to maintain the normal function of the urban drainage channel, the channel system needs to be regularly maintained, and the channel sludge produced in this process also becomes one of the municipal sludges.

5. Municipal construction site mud
Municipal construction site mud is a type of municipal construction waste, mainly generated during the foundation construction of municipal construction projects (such as concrete pouring pile foundation construction) and building geological exploration (exploration well drilling). Although in a strict sense, construction activity is an industrial production activity, the regional distribution of urban construction activities (randomly appearing throughout the urban area) and the characteristics of waste discharge (the characteristics of waste generated by different construction sites are basically the same). ), all have more commonalities in the city. Therefore, municipal construction waste is generally used as a kind of municipal waste (solid waste). Of course, municipal construction site mud should also be a part of municipal sludge.

1. Design according to the product variety, quality and production requirements stipulated in the plan.

The output of the product specified in the plan letter book often has a certain range, and the design output within this range or slightly exceeds the range, should be considered appropriate; but if it is limited to equipment selection, the designed output will be slightly lower, then A report should be submitted to explain the reasons. After obtaining the consent of the superior, proceed with the design.

For product varieties, if the design considers that the provisions of the plan and work book are technically and economically inappropriate, it should also report, clarify the reasons, propose adjustments, and obtain the consent of the superior. For example, a large cement plant plan requires a small amount of special cement. The design unit has argued that the large kiln changes the production variety, which is technically and economically unreasonable. It is recommended to arrange a small amount of special cement for the production of a small and medium-sized cement plant. After approval by the superior, the required variety was changed.

The output of the kiln, grinding and other main engines, in addition to the reference equipment description and empirical formula calculation, should also be calibrated according to the domestic production data of the same type of mainframe and with reference to the host output of similar specifications at home and abroad. In the short period after the completion of the factory, the main engine should be able to achieve the calibrated output; at the same time, the calibrated mainframe output should meet the requirements of high quality, high output, low consumption and long-term safe operation of the equipment, not only to play the equipment capacity, but not excessively Pursue intensive operations.

2. Choose technologically advanced and economically rational processes and equipment.

After the process and main equipment designed by the cement plant are determined, the overall design of the cement plant can be described as the overall situation. After the factory is completed, it will be very difficult to change its process and main equipment. For example, it is difficult to change the wet process plant to a dry process plant; it is not easy to change the old dry process plant to a new dry process plant. For example, in order to use the waste heat of the kiln exhaust gas to dry the raw materials, the raw material grinding system has to be relocated, and the conveying equipment and the like have to be rebuilt. In such cases, it may not be feasible under certain conditions.

When selecting the production process and equipment, we should try to save energy and adopt more mature advanced experience and advanced technology. However, new technologies, new processes and new equipment must be qualified after production practice before they can be used in new plants. In the design.

The selection of process flow and equipment should be compared with the program to achieve advanced technology and economical rationality.

When selecting the specific equipment, you should pay attention to the following issues:

(1) Try to choose equipment with new structure, small size, light weight, high efficiency, low consumption, reliable operation, convenient maintenance, guaranteed supply or self-manufacturing.

(2) The model and specifications of various accessory equipment should be as uniform as possible to facilitate production management and reduce the types of equipment.

(3) Comprehensively solve the relationship between factory production, off-site transportation and various material reserves.

Since the rotary kiln requires long-term continuous operation, the crusher and the mill and other equipment require more time for planned maintenance; at the same time, the off-site transportation is intermittent and subject to various complicated conditions; therefore, various materials should be Have proper reserves. The capacity of various yards and storages should meet the requirements of the storage period of various materials. The storage period should be determined so that the production has certain mobility, which is conducive to the balanced production of the factory, but the storage period should not be too long. So as not to increase the amount of infrastructure construction and liquidity at the time of factory production.

(4) Pay attention to the possibility of production potential tapping after the completion of the factory and leave room for factory development. It takes several years for the factory to go from design to completion, and the production technology is moving forward. Therefore, the equipment capacity should be able to meet the production requirements and leave room for it. For example, each workshop host should have a certain reserve capacity for the kiln, and various auxiliary equipment should have certain reserve capacity for its main engine. In addition, combined with China’s current actual situation, cement production is far from meeting the needs of national economic development, so the possibility of expansion after the completion of the factory is very high. Therefore, the factory should have room for development.

The principle of considering the expansion of the factory is: it is necessary to facilitate the expansion in the future, so that the expansion of the factory should not affect the original production as much as possible, and the floor space and investment of the current plant should be increased as much as possible.

(5) Reasonably consider the level of mechanization and automation equipment.

The level of mechanization should be compatible with the size of the plant and the level of equipment, mainly to study the economic effects. In the continuous production process, the loading, unloading and unloading of bulk materials must be mechanized; the repair and lifting of major equipment, and the need to reduce heavy physical labor should also be mechanized as much as possible.

At present, the automation of the production process of the factory has its own characteristics. At present, it does not emphasize the high degree of total automation, but focuses on the local automation of practicality. Such as ensuring the automation of continuous production of large kiln; adjusting the automation of frequent and non-manpowered links.

(6) Pay attention to protecting the environment and reducing pollution.

Implement environmental protection, industrial hygiene and other regulations, and take active measures to reduce environmental pollution to protect the health of workers and extend the service life of equipment.

(7) Convenient construction and installation, convenient for production and maintenance.

The process layout should be smooth, compact and as simple as possible, and strive to shorten the transportation distance of materials, and fully consider the convenience of equipment installation, operation, maintenance and access; and his professional requirements for layout.

According to the basic construction procedures, after the site is approved, the design work can be fully carried out. Process design is generally divided into two stages: preliminary design and construction drawing design.

Raw material processing testing is one of the pre-design preparations and should be carried out during resource exploration and plant feasibility studies prior to design. The purpose of the batching calculation is to determine the type and mix ratio of the raw materials. Therefore, it is the main basis for determining the raw material requirements and material balance, host balance and reservoir calculation. In the design unit, raw material processing tests and batching calculations are done by raw materials.

In the preliminary design phase, process design calculations and process layouts are often interleaved. Start with the material balance calculation of the whole plant, and then carry out the calculation of the host balance, and then determine the storage period, storage amount, and main size of the storage materials of various materials, and then preliminary consideration of the contour size of each workshop, and draw the general plan outline of the production workshop. Initially solve the plane position relationship of each production workshop and prepare for the sub-workshop design. When designing the workshop, first start from the equipment selection calculation in the workshop, calculate the selected equipment, and then carry out the layout design of the workshop to draw the layout of the workshop. Taking such shallow and orderly steps is necessary to avoid rework of design work.

It must be pointed out that the considerations of process design calculation and process layout cannot be completely separated. In particular, when performing host balance calculation, the problems of the selected host in the process flow and design layout must be considered to avoid the design layout. Difficulties arise.

Plastic balance, main engine balance and reservoir calculations are based on the production capacity of the firing plant. The production capacity of the firing plant basically determines the production capacity of the plant. Therefore, in the material balance, main engine balance and storage calculation, first determine the production capacity of the firing plant and the production capacity of the plant.

The general plan profile of the factory production workshop mainly indicates the mutual position of each workshop, which is the main basis for the general plan professional design of the factory layout.

The layout of each workshop is drawn in the workshop, which indicates the main level and section of the workshop, and is designed for civil engineering and other related professionals. The flat and sectional drawings of the whole factory production workshop indicate the production process of the whole plant, the number of main and auxiliary equipment and positioning dimensions, the elevation of the factory floor, the ground level and the maintenance facilities, etc., which are the drawing parts of the preliminary design documents, and the equipment Together with the design specification, the form forms the preliminary design document.

The construction drawing design is divided into two steps: data drawing and finished drawing, and each workshop is designed separately. According to the preliminary design of each workshop’s process layout drawings and approval and revision opinions, the process design drawings are drawn for the professional use of the design. After the design of each professional, check, modify and supplement, and draw the finished drawings. The construction drawing includes the process layout drawing (plan view, sectional view), partial enlarged view, non-standard parts drawing and equipment basic drawing, etc. It is the document of the construction drawing design, as the basis for the installation of the process equipment.

In recent years, China’s economy has entered a period of rapid development, the pace of urban transformation is accelerating, and the way of collecting municipal solid waste is also changing. In different countries and regions, the collection methods of municipal solid waste are very different. The level of economy and the importance of sanitation have a great impact on the collection of municipal solid waste. In economically developed countries and cities, the collection methods of municipal solid waste are relatively more standardized, efficient and sanitary.
Classification of Domestic Waste Collection Ways
At present, there are two main ways to collect municipal solid waste: mixed collection and classified collection.
1) Mixed collection
Mixed Collection refers to the collection method of mixed municipal solid waste without any treatment. The advantages of this method are simple, easy to operate and low operating costs. However, due to the mixing of various garbage in the collection process, the purity and reuse value of useful substances in garbage are reduced. At the same time, the difficulty of municipal solid waste treatment is increased, and the total cost of municipal solid waste treatment is increased. This method is widely used and has a long history.

2) Classified collection
Classified Collection refers to the way of collecting municipal solid waste according to its components. This method can improve the purity and quantity of recycled materials, reduce the amount of garbage to be treated, and is conducive to the recycling and reduction of municipal solid waste.
Classified collection has many advantages. It is the premise of reducing waste treatment cost, simplifying treatment process and realizing comprehensive utilization of waste. However, the practice of classified collection of municipal garbage in various countries shows that this is a rather complicated and difficult work. Only by effective publicity and education, legislation and the provision of necessary conditions for classified collection of garbage, can urban residents be actively encouraged to take the initiative to classify and store garbage and carefully organize the work of classified collection, can the promotion of classified collection of garbage be promoted. Continue to develop.
At present, the most popular way of municipal solid waste treatment in China is pyrolysis and gasification of refuse. Using rotary retort equipment, the original ecological waste can be directly treated without sorting.

As the composition of municipal solid waste varies greatly, its calorific value fluctuates greatly, its moisture content is high and it contains certain non-combustible substances, it is undoubtedly unsatisfactory if it is directly used as solid fuel without treatment. In recent years, with the improvement of living standards and the continuous improvement of calorific value of municipal solid waste, more and more attention has been paid to the energy utilization of municipal solid waste. The municipal solid waste treatment method, which processes municipal solid waste into a new solid fuel with higher calorific value, more stable, easy transportation and storage, has been greatly developed and applied.
Refuse Derived Fuel (RDF) generally refers to the solid fuel produced by crushing and screening out the non-combustible waste from municipal solid waste, further crushing and drying the waste plastic, paper scraps and other combustible materials. This new type of fuel, which is processed from municipal solid waste, is called Refuse Derived Fuel (RDF).
Rubbish derived fuels (RDF) have the following advantages:
1) High calorific value and uniform combustion characteristics;
2) Energy reuse and comprehensive efficiency;
3) The content of heavy metals in flue gas is low, the cost of flue gas purification is low, and the ash content is low.

Waste derived fuels (RDF) are widely used in the following areas:
1) The application of refuse derived fuel (RDF) in small and medium-sized public places mainly refers to warm water swimming pool, gymnasium, hospital, public bathroom, welfare home for the elderly, snow melting and so on.
2) Application in drying engineering: burning refuse derived fuel (RDF) in a special boiler as a heat source in drying and thermal deodorization engineering;
3) Application in cement manufacturing: The combustion ash of refuse derived fuel (RDF) generally needs to be treated, which undoubtedly needs to increase operating costs. In order to develop a new RDF application field with low operating cost, the combustion ash of refuse derived fuel (RDF) can be used as raw material in cement manufacturing process, thus canceling the ash treatment process of refuse derived fuel (RDF) combustion and reducing operation cost.
4) Application of district heating project: In the area where the infrastructure of heating project is relatively complete, only a special RDF combustion boiler can be built to realize the heating of refuse derived fuel (RDF). However, because of the high cost, it is not economical to use refuse derived fuel (RDF) for heating in areas where the infrastructure of heating projects is relatively backward.
5) Application of power generation engineering: It is very economical to combine waste derived fuel (RDF) with coal for power generation in coal-fired thermal power plants, or to generate electricity on a small scale in a special waste derived fuel (RDF) combustion boiler.
6) Application as carbide: The waste derived fuel (RDF) is pyrolyzed and carbonized in the condition of air isolation, the combustible gas produced is burned as the heat source in drying engineering, and the pyrolysis residue is carbide which can be used as reducing agent instead of coke in ironmaking blast furnace.

At present, the core equipment for biomass gasification power generation is a gasifier. According to the different operation modes of the gasifier, it can be divided into three types: fixed bed, fluidized bed and rotary bed.

The gasifiers used in the current biomass gasification process in China are mainly fixed bed gasifiers and fluidized bed gasifiers. At present, in the practical application process of biomass gasification technology, fixed bed gasifier and fluidized bed gasifier generally have the situation that equipment cannot be continuously produced, in addition to easy coking and high temperature alkali metal element corrosion. problem. The revolutionary bed gasifier unique to our institute can not only solve many problems in the above fixed bed and fluidized bed gasifier, but also has unique technical advantages.

Current status of biomass gasification technology Fixed bed gasifier and fluidized bed gasifier have major problems Technical advantages of LCDRI revolutionary bed gasifier
The equipment can not achieve precise control of temperature, precision, etc.; low degree of automation, continuous production of equipment can not be achieved; in the actual application process, easy to coke and produce alkali metal corrosion; The original rotary bed technology has the advantages of uniform fuel heating, less coking, pyrolysis condition parameters (time/temperature), precise and automatic control, reliable system operation and high gasification efficiency.
When biomass is gasified, the slag and fly ash have higher carbon content and lower gasification efficiency;
High tar content in gas, affecting the stability of power generation equipment, and easy to produce coke-containing wastewater; Adopting the world’s only and world-leading gas purification and decoking technology, the gas meets domestic and international emission standards and the requirements of gas-fired power generation systems, and zero discharge of coke-containing wastewater;
The exhaust heat recovery effect of the gasification generator set is not good, resulting in low overall efficiency of the system; The residual heat of the system can be recovered by equipment such as circulating cooling system and waste heat boiler to realize the cascade utilization of energy. The comprehensive energy utilization rate is above 95%, and the system efficiency is high;

Biomass pellets are a new type of clean fuel. It is a kind of fuel with certain density and calorific value requirement by processing biomass with biomass wood pellet machine; using agricultural and forestry waste (such as straw, wood chips, bagasse, etc.) as raw material, after crushing and baking Processes such as drying, mixing, and extrusion are used to form a shaped particulate fuel.

What is the difference between biomass particles and other energy sources? Take 1 ton of water per hour from 10°C to 43°C (need to absorb the energy consumption of 33,112 kcal heat) as an example, comparing the heat value, utilization rate, and cost of use.

Energy source Energy consumption Energy unit price Heat value Utilization rate The cost Remarks
Electricity 39.7kw RMB1.0/kwh 860kcal 97% 39.7 Extremely expensive;
Light diesel oil 3.7kg RMB8.0/kg 10500kcal 85% 29.7 High cost;
Natural gas 4.9m3 RMB 3.5/m3 8000kcal 85% 17 High account opening fee; Restricted by geographical area;
Air source water heater 39.7kw RMB 1.0/kg 860kcal 97% 11.7 Expensive equipment; limited in winter, only electricity;
Traditional coal 8.8kg RMB 1.0/kg 5000kcal 70% 9.5 High pollution; Insufficient fuel;
Biomass particles 8.6kg RMB 1.0/kg 4300kcal 90% 8.6 Government support; no pollution,high utilization rate, low cost;

How can we use biomass pellets effectively? Biomass gasification power generation technology can use biomass pellets for gasification and power generation. The biomass gasification power generation technology can gasify the biomass particles through the rotary dry distillation furnace, extract the hydrocarbon materials, convert them into biomass gas, and after purifying and cooling, enter the gas generator set to generate electricity. The search for biomass gasification power generation can not only solve the effective use of renewable energy, but also solve the environmental pollution of various organic wastes. It is for these reasons that biomass gasification power generation technology has been increasingly researched and applied, and is becoming more and more perfect.From the above table, it can be concluded that biomass particle energy not only has high calorific value, high utilization rate, low cost of use, and environmental protection.

Before that, we introduced what is a smart park, and its development stages and composition. Next, we will analyze the benefits of the smart park, including improving energy efficiency, realizing low-carbon operation of the park; optimizing management process, realizing the whole process control of the park operation; strengthening statistical analysis, realizing the deep development of information resources in the park; High labor productivity, maximizing the value of the park, conforming to the development direction of smart cities, promoting the development of new strategic industries, etc.

1. Improving energy efficiency and realizing low-carbon operation of the park. According to the actual operation statistics of the park, the comprehensive energy-saving effect of the system is 30%. The energy-saving rate of the central air-conditioning terminal system of the main power consumption in the park can reach 25%. The energy-saving rate of the main system is 10%-15%. The energy-saving effect of the lighting system can reach 60% through intelligent control and the application of new energy and new materials. Energy saving can be achieved by 25%-30%.

2. To optimize the management process and realize the whole process control of the park operation. On the one hand, according to the data analysis of the software system, the seasonal and day-and-night operation mode of public equipment is formulated, which improves the quality of power operation, prolongs the service life of equipment and realizes the purpose of scientific dispatch. On the other hand, by sensing, collecting, receiving and receiving the operation nodes of the park, the operation efficiency and abnormal situation of the equipment and facilities are automatically transmitted to the background, which improves the safe operation quality of the park assets, realizes intelligent fault alarm and operation efficiency monitoring, and improves the response speed of dealing with the faults.

3. Strengthen the statistical analysis, realize the deep development of information resources in the park, solve the real-time collection, transmission, storage and operation of massive data through wireless sensor network and other information technology applications, and strengthen the auxiliary decision-making function. The system can more accurately and intuitively record and display the basic data of energy operation, energy load and power consumption of the park, and interconnect with other information systems such as customer management, electronic payment, intelligent parking, data sharing, and discover the intrinsic value of information resources.

4. To improve the productivity of staff and maximize the value of the park, the system has the functions of equipment monitoring, route arrangement, data recording and working status monitoring. It provides scientific management and assistant decision-making means for the management of the park, effectively reduces the duplicate working time of staff, and realizes the intellectualization, real-time and high-end of daily management, equipment operation and customer service. It improves the service quality and customer satisfaction of the park.

5. To conform to the development direction of smart city and promote the development of new strategic industries, smart city has become an inevitable trend of future urban development. As a characteristic functional block and an important component of smart city, smart park has broad market development space. The construction of smart Park involves the system application of Park card, intelligent transportation, intelligent security, intelligent air conditioning, intelligent lighting, energy management and environmental monitoring, and directly brings the development of new strategic industries such as animal flow network, cloud computing and new energy.

With the vigorous support of the state, the intelligent construction of parks is in full swing throughout the country. Different types of parks around the country have formulated their own development plans according to their own development orientation and market competition. In the future, urban development and management can be indexed by the construction of smart parks to further promote the construction of smart cities. Meanwhile, the management of smart parks can be integrated into the management system construction of smart cities to achieve a high degree of integration between market management of smart parks and market management of urbanization, and to create a “smart” urban management system with great regional influence.

Intelligent parks refer to the integration of new generation information and communication technologies, with the ability of rapid information collection, high-speed information transmission, highly centralized computing, intelligent transaction processing and ubiquitous service delivery, to realize timely, interactive and integrated information perception, transmission and processing in the parks, so as to improve the industrial agglomeration capacity, enterprise economic competitiveness and sustainable development of the parks. Advanced Park Development concept.

With the development of China’s economic transformation, traditional industrial parks are facing many challenges, such as incomplete industrial model, lack of sharing mechanism, serious imbalance of input and output, etc. In this regard, industrial parks need to take advantage of the new generation of information technology as an opportunity to rapidly improve their service level and quality, achieve transformation and development, acquire core competitiveness in the information environment, and meet the needs of rapid development of enterprises. Therefore, intelligent parks emerge as the times require.

The development of domestic smart parks has gone through the following three stages: 1. The pilot stage (1983-1988), the government-led smart parks, relying more on cheap land and tax policies, generally develop labor-intensive enterprises, but the relevance of each enterprise unit is weak; 2. The initial stage of development (1989-1999), this stage still needs to rely on the government-led to promote industrial agglomeration. 3. In the stable development stage (2000-present), after many years of development, the industrial chain tends to be perfect. According to the national policy requirements, green environmental protection enterprises have been strengthened, the competition for talents has become more intense, enterprises have entered the stage of rapid development, and technology-intensive enterprises have entered the stage of high-speed development. Industry has become more prominent, and enterprises have gradually embarked on the road of innovation and high-tech development.

Intelligent parks include industrial parks, industrial parks, logistics parks, Metropolitan Industrial parks, science and technology parks, creative parks and so on. They are based on the construction of three-dimensional database of the park as the core and the design criterion of three-dimensional database as the important basis, so as to realize timely, interactive and integrated information perception, transmission and processing in the park, so as to improve the industrial agglomeration capacity, economic competitiveness of enterprises. The sustainable development of the park is the goal of the advanced park, and scientific decision-making is made to improve the efficiency of Park management.

The industry chain of smart park is divided into three parts: the upstream includes land, infrastructure construction, electronic devices, cloud computing, big data, software, chips and intelligent manufacturing; the middle includes Park Property and service system, Park incubator operation and maintenance services, Park intelligent investment and intelligent management platform; and the downstream includes some enterprises and logistics.

By means of informationization, the integrative solution of smart parks is constructed with “park operation” as the center, and the model of smart parks is built from the aspects of brand, service quality and experience of enterprises. Improve the park’s public service system as the entity, industry cluster as the face, promote the participation of enterprises and organizations in the park, share resources, and establish a one-stop comprehensive public service system or system.

Sludge treatment refers to the process of reducing, stabilizing and harmless sludge concentration, quenching, dehydration, stabilization, drying or incineration. Sludge disposal refers to the sludge that has been treated, disposed of in the natural environment or reused, and can achieve long-term stability and no adverse effects on the ecological environment. The data shows that in 2018, China’s urban solid waste was 78.8 million tons, forming 36 million tons of sludge. At present, the environmental protection industry is increasingly aware of the necessity and urgency of sludge treatment and disposal, and the original ‘heavy water and light mud’ bias has been changed. As far as the conventional methods of sludge disposal are concerned, whether it is incineration or carbonization; whether it is landfill or composting, it will cause associated secondary pollution problems. Supercarbon materials can better solve the sludge treatment problem.

What is sludge-based supercarbon material (CTDD-2)?

Desulfurization and denitration special super-carbon is a kind of sludge + biomass-based activated carbon. It is selected from urban or industrial sludge and rice straw straw rich in organic matter. The production process is to dry the sludge and add straw stalk biomass particles. It is made of materials, active additives, suitable binder extrusion, carbonization and activation. Compared with ordinary activated carbon, it can be used to treat flue gas emitted from power plants, steel mills, petrochemicals, coking and other industries, and simultaneously remove SO2. And NOX, no need to spray ammonia, flue gas purification and use effect is better than traditional activated carbon.

What are the characteristics of biomass-based supercarbon materials?

Desulfurization and denitrification special sludge + biomass-based super carbon production is different from ordinary coal-based columnar activated carbon. Desulfurization and denitration special super-carbon has higher sulfur capacity, higher capacity, stronger strength, and resistance to extrusion, wear and impact. The characteristics are more prominent, the specific surface area is slightly lower than the traditional activated carbon, but the pores are particularly developed, the adsorption performance is stronger, the cycle number can be reduced, the equipment volume is reduced, the floor space is reduced, the system configuration can be optimized, the construction investment is reduced, and the material circulation times are small. The parsing segment has a lower workload, higher operational convenience, and lower operating and maintenance costs.

What is the application of biomass-based supercarbon materials?

Desulfurization and denitrification special sludge + biomass-based super carbon for non-ferrous metal smelting tail gas, sintering pellet tail gas, coal-fired power plant flue gas, heating furnace, gas generator, coke oven, municipal waste incineration flue gas and cement, ceramics, glass, In the chemical and petroleum industries, the removal of sulfur dioxide, nitrogen oxides and hydrogen sulfide in coal-fired flue gas, fuel flue gas and industrial exhaust gas is good, and it can also be used as a filter material for personal protective equipment to protect against sulfur dioxide and nitrogen oxides. Desulphurization and denitrification special sludge + biomass-based super carbon can be desulfurized and denitrated simultaneously from the initial simple desulfurization.

After undergoing a technological breakthrough, the “Desulfurization and Denitrification Special Sludge+Biomass-based Superchar” developed by Zhongjing Environmental Technology has carried out a series of technical improvements on this basis, eliminating the process of spraying ammonia, which is a qualitative Leap, the product that is removed for the acid needs can be selected to prepare sulfuric acid or sulfur. For customers who do not need acid demand, they can choose to use the filler or gelling agent for building materials directly after grinding into powder. It has established a material recycling system of “recycling resources”, which also increases the revenue of customers’ by-products while protecting the environment.