Steam Jet Heat Pump DN10-500 High-Efficiency Thermal Energy Recovery

I. Principle

A steam jet heat pump involves the mixing of two fluids at different pressures, where energy exchange occurs to form a mixed fluid at an intermediate pressure. The mixed fluid may be in the gas (steam) phase, liquid phase, or a mixture of gas (steam), liquid, and solid. The medium with higher pressure before entering the device is called the working medium. The flow of the working medium is referred to as the working fluid. The working fluid exits the nozzle at high speed, enters the receiving chamber, and draws in the medium at a lower pressure in front of the ejector. The drawn fluid is called the entrained fluid. Typically, in the ejector, the potential or thermal energy of the working fluid is first converted into kinetic energy. Part of the kinetic energy of the working fluid is transferred to the entrained fluid. As the mixed fluid flows along the ejector, its velocity gradually equalizes, and the kinetic energy of the mixed fluid is then converted back into potential energy.

II. Working Process

III. Scope of Application

1) In power plants: fuel combustion equipment (gas jet burners); feedwater systems for steam boilers (anti-cavitation water ejectors); regulation systems of steam turbines (oil ejectors); to increase the extraction pressure of steam turbines (steam jet compressors); to remove air from condensers (steam or water ejectors); alternating current heating systems (ejector heaters); for conveying ash and slag (hydraulic ash removers); air cooling systems for generators (ejector cooling devices).

2) In waste steam heat recovery heating systems: as mixers at the inlet of heating users (water ejector mixers); to increase the pressure of waste steam from production equipment (steam jet compressors); in systems for recovering condensate and for draining accumulated water from trenches and inspection wells of underground heating pipelines (steam and water ejectors); when repairing underground heating pipelines, for conveying insulation materials to trenches (pneumatic conveying ejectors).

3) In refrigeration technology: as primary and auxiliary equipment in refrigeration units.

4) In industrial thermal technology: fuel delivery, air supply, and combustion systems for industrial furnaces; oil supply systems for many modern machines and test bench setups for experimental engines.

5) In ventilation systems: used to create a continuous airflow through ducts and rooms.

6) In water supply systems: used to lift water from deep wells and boreholes.

7) For conveying solid granular materials and liquids.

8) For natural gas pressure boosting.

IV. Performance Characteristics

1. High Efficiency and Energy Saving: Utilizes advanced heating technology and high-efficiency insulation materials to reduce thermal energy loss, achieving high efficiency and energy savings.
2. Safe and Reliable: Equipped with multiple safety protection devices, such as leakage protection and overheat protection, ensuring safety during use.
3. Easy Operation: Features an intelligent control system with one-touch operation, making it user-friendly.
4. Durable: Made from high-quality materials and precision craftsmanship to ensure stability and longevity.

V. Technical Parameters

1. Material: Uses food-grade stainless steel or high-quality plastic to ensure water safety.
2. Heating Power: Customizable according to requirements to meet various heating needs.
3. Dimensions: Available in multiple specifications to fit different installation spaces.

VI. Instructions for Use

1. Usage Locations: Suitable for places requiring hot water, such as homes, schools, hospitals, and factories.
2. Working Principle: Heats raw water to the set temperature via electric or thermal energy driving the heating element.
3. Product Structure: Simple and clear, easy to maintain and service.
4. Safety Instructions: Follow the product manual for proper installation and use; avoid unauthorized disassembly or repair.

VII. Purchasing Notes

1. Delivery Time: Based on order volume and production schedule, delivery will be made within the agreed timeframe.
2. Shipping Methods: Multiple shipping options are available to ensure safe and timely delivery.
3. After-Sales Service: Comprehensive after-sales support, including installation guidance, maintenance, and repairs, ensuring a worry-free experience.

VIII. Ejector Coefficient

Through optimized design and layout, the steam jet heat pump enhances thermal energy transfer efficiency, thereby increasing the ejector coefficient. Additionally, an advanced control system enables precise temperature control, further improving heating performance.

IX. Heat Exchange Efficiency

To improve heat exchange efficiency, the steam ejector employs a large heat exchange surface area to increase thermal energy transfer. Furthermore, high-efficiency insulation materials are used to minimize thermal loss, ensuring heat is fully transferred to the water.

X. Detailed Energy Saving Analysis

The steam jet heat pump excels in energy saving. Firstly, its temperature control system prevents energy waste. Secondly, efficient heating elements and insulation materials reduce thermal loss, enhancing energy utilization. Additionally, the intelligent control system adjusts heating power based on actual needs, enabling energy-efficient operation.

XI. Market Competitiveness

With its high efficiency, energy savings, and ease of operation, the steam jet heat pump holds strong competitiveness in the market. Moreover, our focus on product quality and service has earned the trust and positive feedback from numerous users.

XII. Applicable Fields

We have successfully provided steam ejector solutions to many enterprises, receiving favorable evaluations from clients. These success cases fully demonstrate the product's reliability and broad applicability.

XIII. Success Cases

The steam jet heat pump is widely used in various industrial sectors, including chemical, pharmaceutical, food, and textile industries, offering effective solutions for thermal energy recovery and energy-saving upgrades.

XIV. Design Features:
In terms of design, we utilize advanced Computational Fluid Dynamics (CFD) Fluent technology for fluid analysis to optimize product design. Additionally, CAD technology is employed for modeling and simulation analysis, ensuring rational and efficient product structure.