Hebei Chengde 14th Five-Year Plan: vigorously promote biomass and other clean heating technologies


On June 15, the 14th Five-Year Plan for the National Economic and Social Development of Chengde City and the Outline of the 2035 Long-Term Goals were released. The following contents are related to biomass:

The fourth chapter energetically develops the leading industry to construct the modern industrial system with distinctive characteristics

Section two: cultivating and expanding the three supporting industries

Clean energy.
Based on its advantages in resource enrichment, China will actively promote the development and utilization of wind power, photovoltaic power generation, pumped storage, nuclear power, biomass, geothermal energy, oil shale and other forms of clean energy.
We will accelerate the construction of three ten-million-kilowatt clean energy power generation bases, expand and expand clean energy industries such as equipment manufacturing, vanadium energy storage technology, green hydrogen, and operation and maintenance services, promote innovative and integrated development of clean energy, and form a pattern of development of the whole industrial chain of clean energy.
We will build a clean energy transmission base in the Beijing-Tianjin-Hebei region and a national clean energy industrial base.
We will increase the scale of clean energy generation.
We will actively develop and utilize wind and solar energy resources, and strive to increase the installed capacity of wind power and photovoltaic power generation to 20 million kilowatts.
The Fengning Pumped Storage Power Station was completed and put into operation, and the Luanping, Longhua and Shuangluan Pumped Storage Power Station projects were accelerated.
We will actively promote nuclear power and biomass power generation projects to ensure the energy security of the city and help ensure people's livelihood and social and economic development.
We will promote innovative and integrated development.
Relying on enterprises such as Vision Energy, TBEA, Goldwind Electric Control, etc., we will improve the manufacturing capacity of series products such as fan machine, SVG, inverter, etc., and promote the development of clean energy supporting equipment manufacturing industry such as wind power and photovoltaic power generation.
Relying on Jianlong National Clean Energy Steel Base, the company focuses on developing steel manufacturing and processing for clean energy equipment such as wind power and natural gas.
We will explore a development model that integrates "clean energy, vanadium energy storage, big data and micro-grid", and build a number of demonstration projects for innovative and integrated development.
We will work hard to build an informationized, interconnected and intelligent clean energy system.
Strengthen the hydrogen strategy research and layout, energetically develop renewable energy hydrogen production technology, advanced propulsion hydrogen production and scenery store coupling project, strive to build a batch in beijing-tianjin-hebei urban agglomeration has the technology advantage, scale advantage of hydrogen production project, promote hydrogen production, hydrogen storage, hydrogen, hydrogen with four one, formed based on resource advantage, technology advantage of clean energy industry development pattern.
We will increase the supply of clean energy electricity.
We will promote the construction of ultra-high voltage projects and 500 kV power transmission and transformation projects, and strive to become an important transmission pole for green power consumption in Beijing and Tianjin.
We will comprehensively improve the city's power grid delivery capacity and the scale of clean energy development.
By 2025, the operating income of the clean energy industry will reach more than 30 billion yuan.

Chapter Six: Optimizing Territorial Spatial Layout and Promoting Integration of Urban and Rural Development

Section 3 Improving Modernized Urban Infrastructure

We will comprehensively promote clean heating and increase the area of central heating.
In addition to the coverage of central heating in urban built-up areas, we will promote clean heating technologies such as natural gas, heat pumps, middle and deep geothermal, biomass and solar energy in light of local conditions and complement each other with multiple energy sources. By 2025, the rate of clean heating in urban built-up areas will reach 100 percent.
We will strengthen the development of heat sources, improve the central urban and county heating capacity, launch the second phase of the thermal and power plant project in the southern district and other heating projects in the county and urban areas, and increase the area of central heating each year.
By 2025, the city will increase the central heating area by 10 million square meters in five years.

Chapter 9 Accelerate infrastructure construction, consolidate development and guarantee the level of supporting capacity

Section 3: Building a Modern Energy Supply Network with a Full Chain

We will make power facilities more capable and smart.
To fully implement the clean energy delivery project, speed up the construction of Chengde's first 1000kV UHV substation, and synchronously construct the 500kV substation project to form the clean energy delivery grid of "Three Stations and One Delivery Base", and strive to improve the consumption and delivery capacity of clean energy.
We will actively promote the construction of urban distribution network projects, strive to build 19 new 220 kV and 110 kV substations, and increase the power transmission and transformation capacity by more than 1,300 MV A, so as to continuously consolidate the reliability of urban power supply.
We will comprehensively improve the network structure of rural power grids, strengthen the layout and construction of substations and power lines of 35 kv, 10 kv and below, speed up the transformation and upgrading of power distribution stations, strive to increase the capacity of rural power grids by more than 170 MV A during the 14th Five-Year Plan period, continuously improve the level of rural electrification, and boost the development of rural industries and economy.
We will accelerate the development of demonstration projects for smart grids and microgrids.
We will promote the construction of demonstration projects for smart grids with distributed power sources, and improve the reliability of power supply and the ability to interact with users in both directions.
Relying on industrial parks, big data centers, large public facilities and key energy-using enterprises, we will build smart microgrid projects that provide diversified forms of energy supply, such as distributed wind power, distributed photovoltaic power generation, biomass, and nuclear small reactors, and strive to foster new forms of energy Internet business.

LAST NEWS


The generator set control module adopts the microprocessor-based

The generation principle of biomass synthesis gas: biomass raw materials enter the reactor of the gasification furnace, after being heated and dried, and then as the temperature rises, its volatile matter is precipitated and pyrolyzed (cracked) at high temperature. The pyrolyzed gas and production The substance undergoes a combustion reaction with the supplied air in the oxidation zone to produce CO2 and water vapor. The heat generated by combustion is used to maintain drying, pyrolysis and endothermic reactions in the lower reduction zone. The gas produced after combustion passes down the reduction zone and reacts with the high-temperature carbon layer (C+CO2=2CO, C+HO2=H2+CO) to generate biomass synthesis gas containing CO, H2, CH4, CmHn, etc. It is drawn from the bottom, and is sent out for use after the purification system removes impurities such as tar. The ash is discharged from the lower part of the gasifier. The generator set control module adopts the microprocessor-based generator set control technology, which has many functions such as automatic data recording, automatic operation, automatic control, automatic protection, etc., and has good reliability and stable performance. The operating parameters of the unit are displayed by a large-screen LCD, which displays large and accurate data.


which is convenient for transportation and installation

Biomass gasifier is composed of furnace body system, dust removal system, cooling system, tar purification system, tar separation system, Roots blower, electrical control system, etc. The syngas generator set is mainly composed of a gas engine, a three-phase AC synchronous engine, a control cabinet, a common chassis and a gas source link part. The KX series biomass synthesis gas power generation system adopts modular design, which is convenient for transportation and installation. The KX series biomass gasifier is a downdraft, fluidized bed biomass gasifier independently designed and developed for the needs of biomass synthesis gas power generation. This series of biomass gasifier uses PLC intelligent system control The system fully realizes long-term fully automatic work. And the dry purification technology used in the gasifier avoids secondary water pollution to the natural environment. Moreover, the raw materials are highly adaptable, requiring the size of the biomass raw materials to be ≤30mm and the moisture content ≤20%. Pass various biomass raw materials through the gasifier for drying, cracking, oxidation and reduction to produce biomass synthesis gas, and then the biomass synthesis gas is cooled, dusted, and cooled to remove tar and impurities in the gas, and the processed high-quality , The pure biomass synthesis gas is transported to the synthesis gas generator set for power generation. In this way, while realizing the conversion of low-value biomass energy from solid to gaseous, it greatly improves the utilization efficiency of solid biomass energy. Biomass gasification is the process of converting solid biomass (wood chips, branches, organic household waste, agricultural and forestry waste, etc.) into combustible biomass synthesis gas. By controlling the reaction process, carbon, hydrogen, and oxygen are chemically reacted. It is synthesized into combustible components such as carbon monoxide, hydrogen and methane, and most of the energy in biomass raw materials is transferred to biomass synthesis gas. This is the gasification process of biomass gasifier. The generation principle of biomass synthesis gas: biomass raw materials enter the reactor of the gasification furnace, after being heated and dried, and then as the temperature rises, its volatile matter is precipitated and pyrolyzed (cracked) at high temperature. The pyrolyzed gas and production The substance undergoes a combustion reaction with the supplied air in the oxidation zone to produce CO2 and water vapor. The heat generated by combustion is used to maintain drying, pyrolysis and endothermic reactions in the lower reduction zone. The gas produced after combustion passes down the reduction zone and reacts with the high-temperature carbon layer (C+CO2=2CO, C+HO2=H2+CO) to generate biomass synthesis gas containing CO, H2, CH4, CmHn, etc. It is drawn from the bottom, and is sent out for use after the purification system removes impurities such as tar. The ash is discharged from the lower part of the gasifier.    The generator set control module adopts the microprocessor-based generator set control technology, which has many functions such as automatic data recording, automatic operation, automatic control, automatic protection, etc., and has good reliability and stable performance. The operating parameters of the unit are displayed by a large-screen LCD, which displays large and accurate data.


Biomass gasification is the process of converting solid biomass

Biomass gasification is the process of converting solid biomass (wood chips, branches, organic household waste, agricultural and forestry waste, etc.) into combustible biomass synthesis gas. By controlling the reaction process, carbon, hydrogen, and oxygen are chemically reacted. It is synthesized into combustible components such as carbon monoxide, hydrogen and methane, and most of the energy in biomass raw materials is transferred to biomass synthesis gas. This is the gasification process of biomass gasifier. The generation principle of biomass synthesis gas: biomass raw materials enter the reactor of the gasification furnace, after being heated and dried, and then as the temperature rises, its volatile matter is precipitated and pyrolyzed (cracked) at high temperature. The pyrolyzed gas and production The substance undergoes a combustion reaction with the supplied air in the oxidation zone to produce CO2 and water vapor. The heat generated by combustion is used to maintain drying, pyrolysis and endothermic reactions in the lower reduction zone. The gas produced after combustion passes down the reduction zone and reacts with the high-temperature carbon layer (C+CO2=2CO, C+HO2=H2+CO) to generate biomass synthesis gas containing CO, H2, CH4, CmHn, etc. It is drawn from the bottom, and is sent out for use after the purification system removes impurities such as tar. The ash is discharged from the lower part of the gasifier.    The generator set control module adopts the microprocessor-based generator set control technology, which has many functions such as automatic data recording, automatic operation, automatic control, automatic protection, etc., and has good reliability and stable performance. The operating parameters of the unit are displayed by a large-screen LCD, which displays large and accurate data.