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Company Profile

Why Choose Us

Our factory

The company currently has 30 employees, covers an area of 8,000 square meters, has a standardized production workshop of 2,000 square meters and an office building of 1,000 square meters, and has a relatively complete quality control system and complete processing capabilities.

Our product

The leading products are casting, automotive leaf springs, automotive coil springs, automotive stabilizers and other special production equipment for medium and low temperature heat treatment and industrial furnaces for other industries.

Our team

Equipped with a professional team with high and intermediate technical titles and an advanced mechanical drawing system, it is a technology-based enterprise integrating design, development, production and sales.

Our service

We try and respond to all concerns within 24 hours and our teams are always at your disposal in case of any emergencies.

Other Equipments Includes

Storing Heat To Burn Exhaust Gas Furnace

What Is Storing Heat To Burn Exhaust Gas Furnace

Storing heat heating furnaces are essential in various industries, including the crystallization and processing sectors, where precise temperature control is critical. These furnaces convert different forms of energy into heat and transfer it to materials using thermal radiation and convection. The control of temperature during processes like crystal growth and surface deposition directly impacts product quality.

Advantages of Storing Heat To Burn Exhaust Gas Furnace

Lower energy bills

One of the main benefits high-efficiency furnaces offer is cheaper energy bills. The high-efficiency rating means these heating systems use less fuel to heat your home, potentially saving thousands on utility costs in the long run.

Improved comfort

A high-efficiency gas furnace is created to provide comfortable heat during all types of weather and in very cold climates. The most efficient gas furnaces usually will have two heat exchangers, a sealed combustion chamber and a variable-speed blower. Instead of turning on high constantly, the furnace can operate at a lower speed when needed and deliver more usable heat at more consistent temperatures. This also means it will consume less natural gas.

Healthier air quality indoors

High-efficiency gas furnaces are made with high levels of air filtration to catch pollutants before they can contaminate your air, which is particularly beneficial for those who live in areas that have high concentrations of dust and other impurities.

Better for the environment

High-efficiency furnaces are an environmentally friendly solution for heating your home. They have a higher energy efficiency rating that saves on natural gas fuel costs while decreasing greenhouse gas emissions.

Working Principle of the Storing Heat to Burn Exhaust Gas Furnace

The working principle of the storing heat waste gas incinerator mainly includes three stages: Preheating, combustion and cooling.

Preheating stage
The waste gas enters the storing heat system through the induced draft fan and is preheated by the heat exchanger to raise the waste gas temperature to the ignition temperature required for catalytic oxidation. In this process, part of the waste gas is recovered by the preheater and sent back to the furnace, which improves the thermal efficiency.

‌Combustion stage‌
When the waste gas reaches the set temperature, the control system will automatically switch to the combustion mode. At this time, the high-temperature combustion gas in the oxidation chamber is mixed with oxygen for oxidation reaction. In this process, organic matter is oxidized and decomposed into harmless carbon dioxide and water vapor.
At the same time, the ceramic heat storage body in the furnace absorbs and stores a large amount of heat for preheating the subsequent organic waste gas. This process is the "heat release" process of the ceramic heat storage body, thereby saving fuel consumption in the waste gas heating process.

‌Cooling stage‌
The oxidized waste gas is heat exchanged through the heat exchanger, and the heat is transferred to the fresh organic waste gas to reach the ignition temperature required for catalytic oxidation. Then, the waste gas enters the chimney for discharge. In this process, the ceramic heat storage body releases the stored heat, realizing the recycling of energy.
The storing heat waste gas incinerator not only reduces energy consumption but also reduces the emission of harmful gases through this efficient heat recovery mechanism. It is an environmentally friendly and efficient waste gas treatment technology.

How Can You Ensure Your storing heat to burn exhaust gas furnace Combustion Gases Properly?

No matter what kind of furnace you have, it’s important to ensure that combustion gases are vented properly out of your home. If combustion gases like carbon monoxide were to get into your home’s airflow, they could make your family sick and could even be deadly.

The best way to ensure your furnace vents combustion gases properly is to schedule a furnace tune-up every year. During a tune-up, we’ll check for heat exchanger cracks, clogs in the flue pipes and other common problems that can hinder your furnace’s venting process. We’ll fix any venting problems that we find in order to ensure your heating system vents combustion gases safely all winter long.

Things You Should Know about Storing Heat To Burn Exhaust Gas Furnace Systems

Thermal processes generate various particulates and gases which may be harmful to technicians in the working environment. Furnace exhaust systems are used to vent these by-products from the heating chamber to the outside air. Typically, this is done continuously while the furnace is operational to maintain an optimal working atmosphere, and throughout any programmed cooling periods to maximise toxic fume prevention.
Generally, industrial furnace exhausts follow the same basic principles as any other furnace exhaust system. A chimney or a series of contiguous metal gas pipes provide a pathway for emissions to be drawn from the heating chamber via natural draft or by using a fan to induce higher efficiency circulation.

Furnace exhaust systems come in various shapes and sizes

Heat treating equipment varies from benchtop muffle furnaces through to full-scale tunnel kilns. So, naturally, there is enormous variation in furnace exhaust systems. Most benchtop furnaces are equipped with an exhaust air outlet in the rear wall or roof, which can be connected to local ventilation directly, or be positioned beneath a fan-assisted inlet like a fume hood. These configurations enable the upstream direction of exhaust gases into the local ventilation where it is directed outside of the facility.

Some exhaust systems treat as well as vent emissions

Just as some exhaust flues are equipped with fans to increase ventilation efficiency, others are equipped with catalytic converters which catalytically scrub exhaust fumes and break down organic components into carbon dioxide and water vapour. This can help with environmental regulations and in eliminating irritating odours. Some furnace exhaust systems are also equipped with a torch to burn-off excess flammable gases.

Exhaust systems can assist with process control and safety

Process control systems can be integrated into furnace exhaust systems to continuously or periodically monitor key exhaust gas parameters like composition/temperature. Variations can be fed back to central control systems where automated alarms can be triggered in the event of hazardous conditions. Additionally, custom human machine interface (HMI) systems can be developed to allow remote access and control plus event logging, so that the furnace exhaust system functions as part of a detailed feedback loop useful for quality assurance and safety management.

Gas Control System

What Is Gas Control System

Used to treat volatile organic compounds (VOCs) emitted during industrial production. Catalytic combustion furnace achieves efficient purification of exhaust gas and recovery of heat energy through catalytic combustion and heat storage and heat exchange technology.

Advantages of Gas Control System

Energy savings

Energy usage is reduced and becomes efficient, as plant machineries are now equipped with instruments and electrical devices to become the eyes, ears and hands of the control systems. With the help of these components, machinery operation becomes precised with less energy usage.

Improves safety

There are plant processes that use machineries that are considered to be a high safety risk to human health and life. Thus, it is safer to use robots to work in this process lines to keep humans away from any harm.

Consistent product quality

With plant machineries now equipped with a sophisticated system, human errors are eliminated and, thus, improve the quality of the products. In addition, the system would not change the machine performance even when working 24/7.

Lower manufacturing cost

The system is able to anticipate problems before a machinery totally fails. The system is able to give equipment data about the performance of the equipment. Deterioration of specific equipment components is detected as well, alarming the system to properly stop the equipment in a safe manner.

Introduction to the Basic Knowledge of Gas Control System

The Gas Control Systems employ the A365 Gas Controller in regulating the solenoid valve and controlling the content of gases such as CO2, O2, CH4, and H2O vapour inside a chamber, for example, a plant growth chamber or animal cabinet. This system can be applied to control CO2 and 13CO2 levels inside a chamber or to maintain elevated or reduced O2 levels. Precise control of water vapour in the growth cabinet is also possible with this system.

The gas control system is composed of the Gas Controller A365, the Solenoid valve, the gas analyzer (CO2, O2 H2, CH4, water vapour analyzer), a gas pump for sampling from the chamber and delivery to the gas analyzer for measurement.

A laboratory proton gas system typically consists of a gas supply source, gas handling components, and proton generation equipment.

The gas supply source provides the gas that is used to generate the protons. The gas can be sourced from cylinders, bulk gas tanks, or on-site gas generators. The gas handling components include pressure regulators, flow meters, valves, and filters. These components are used to control the flow and pressure of the gas and ensure its purity and quality.

The proton generation equipment typically consists of a proton source, an ion source, and an accelerator. The proton source generates the protons by ionizing the gas using various methods such as electron impact ionization or photoionization. The ion source then selects and extracts the desired protons from the ionized gas. The extracted protons are then accelerated using an accelerator to achieve the desired energy level.

The proton gas system may also include various diagnostic and monitoring instruments, such as beam current monitors and beam position monitors, to measure the properties of the proton beam.

Laboratory proton gas systems are commonly used in various scientific and industrial applications, including materials science, nuclear physics, medical research, and proton therapy for cancer treatment.

The Working Principle Of The Gas Control System

Exhaust gas pretreatment
The exhaust gas first passes through the pretreatment system to remove large particles of dust, moisture and other impurities that may damage the catalyst. The pretreatment method includes steps such as filtering and drying to ensure that the exhaust gas entering the catalytic combustion chamber is pure.

Air inlet heating
The pretreated exhaust gas enters the air inlet section of the equipment. The high-temperature medium in the heat accumulator is used to heat exchange the exhaust gas, and the exhaust gas temperature is quickly raised to the active temperature range of the catalyst.

Catalytic combustion

The high-temperature exhaust gas enters the reaction chamber equipped with the catalyst. Under the action of the catalyst, the organic matter in the exhaust gas undergoes an oxidation reaction and is converted into harmless carbon dioxide and water vapor, while releasing a large amount of heat energy.

Heat recovery

The high-temperature gas generated after catalytic combustion is recovered through the heat accumulator. The recovered heat is used to preheat the exhaust gas entering the system, realize the recycling of energy, and improve the overall energy efficiency.

Emission

The clean gas after catalytic combustion and heat recovery meets the emission standards and is safely discharged through the discharge port.

Gas Control System Regulates Mass Flows in Fuel Cell Systems

Whether on the road or rail, in the air, or as part of stationary applications, hydrogen-based fuel cell systems are used in various ways. In addition to the fuel cell stack itself, a whole system such as this consists of further components – the so-called “Balance of Plant” components. The Gas Control Valve (GCV) is the first product for fuel cell applications. The component is designed for use in all segments – take fuel cell-powered passenger cars, commercial vehicles, trains, mobile power generators, or off-highway vehicles, for example.

Hydrogen-based fuel cell systems need to deliver high efficiency and durability in all applications. In this way, it ensures the fuel cell is operated in a safe and efficient manner. The component offers several functional variants: As a bypass valve, it partially or completely directs the airflow past system components and guides fresh air from the intake to the exhaust. As a throttle valve, it regulates the total pressure within the system. Continuously adjustable valve positions contribute to the versatile nature of the Gas Control Valve. The two-piece cover opens quickly and has a high flow cross-section of up to 65 millimeters, ensuring low-pressure losses at a high mass flow rate. If required, even larger cross-sections can be implemented. This allows fuel cell systems to be operated efficiently and safely.

Our factory

Zibo Jimeng Environmental Protection Equipment Co., Ltd. is located in Huantai County, which is known as the hometown of architecture and the county of tons of grain. It is close to the former residence of Wang Yuyang, a historical and cultural celebrity. The company currently has 30 employees, covers an area of 8,000 square meters, has a standardized production workshop of 2,000 square meters and an office building of 1,000 square meters, and has a relatively complete quality control system and complete processing capabilities. Equipped with a professional team with high and intermediate technical titles and an advanced mechanical drawing system, it is a technology-based enterprise integrating design, development, production and sales. The leading products are casting, automotive leaf springs, automotive coil springs, automotive stabilizers and other special production equipment for medium and low temperature heat treatment and industrial furnaces for other industries.

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Our Certificate

FAQ

Q: What is a heat storage system in an exhaust gas furnace?

A: A heat storage system captures and retains thermal energy from exhaust gases, allowing it to be reused for heating purposes, improving overall efficiency.

Q: How does an exhaust gas furnace operate?

A: An exhaust gas furnace burns fuel to generate heat, which is then used to heat materials or spaces, while exhaust gases are produced as a byproduct.

Q: What is the purpose of heat storage in this context?

A: Heat storage helps to utilize excess heat generated during combustion, reducing energy waste and improving the furnace's efficiency.

Q: What types of materials are used for heat storage?

A: Common materials include water, concrete, ceramic bricks, and specialized phase change materials that can absorb and release heat effectively.

Q: How is heat stored in these systems?

A: Heat is stored by transferring thermal energy from exhaust gases to the storage medium, which retains the heat for later use.

Q: What are the benefits of using heat storage in exhaust gas furnaces?

A: Benefits include increased energy efficiency, reduced fuel consumption, lower operational costs, and minimized environmental impact.

Q: How does heat storage improve energy efficiency?

A: By capturing and reusing heat that would otherwise be lost, heat storage systems reduce the need for additional fuel to maintain desired temperatures.

Q: What industries commonly use exhaust gas furnaces with heat storage?

A: Industries such as metal processing, ceramics, glass manufacturing, and waste incineration often utilize these systems.

Q: How is the heat released from the storage medium?

A: Heat is released through conduction, convection, or radiation, depending on the design of the system and the type of storage medium used.

Q: What is the typical temperature range for heat storage systems?

A: The temperature range can vary widely, typically from 100°C to 600°C (212°F to 1112°F), depending on the application and materials involved.

Q: What role does insulation play in heat storage systems?

A: Insulation minimizes heat loss from the storage medium, ensuring that stored heat remains available for longer periods.

Q: What is a gas control system?

A: A gas control system is a mechanism used to regulate the flow, pressure, and temperature of gas in various applications, ensuring safe and efficient operation.

Q: What are the main components of a gas control system?

A: Key components include gas valves, pressure regulators, flow meters, sensors, and control panels.

Q: How does a gas control system work?

A: The system monitors gas flow and pressure using sensors, adjusts valves and regulators accordingly, and provides feedback to maintain desired operating conditions.

Q: What industries use gas control systems?

A: Industries such as manufacturing, energy, food processing, and HVAC (heating, ventilation, and air conditioning) commonly utilize gas control systems.

Q: What is the purpose of a gas valve in the system?

A: Gas valves control the flow of gas, allowing for precise regulation of gas supply to equipment or processes.

Q: What role do pressure regulators play?

A: Pressure regulators maintain a consistent output pressure, ensuring that downstream equipment receives gas at the correct pressure level.

Q: What safety features are included in gas control systems?

A: Safety features may include emergency shut-off valves, pressure relief valves, and leak detection systems to prevent accidents.

Q: How do sensors contribute to gas control systems?

A: Sensors monitor parameters such as pressure, temperature, and flow rate, providing real-time data for system adjustments.

Q: What is the importance of calibration in gas control systems?

A: Calibration ensures that sensors and instruments provide accurate readings, which is crucial for safe and efficient operation.

Other Equipments - Zibo Jimeng Environmental Protection Equipment Co.. Ltd. Gas Control System, other equipments, Plasma Solid Waste Furnace