| Quantity: | |
|---|---|
JONENG
steam trap are available in threaded and flanged types, with various sizes and pressure ratings. They are high-temperature and corrosion-resistant, offer sensitive opening and closing, and provide stable drainage, making them suitable for steam systems.
The steam trap operates based on buoyancy and liquid level changes. When condensate enters the valve body, the rising liquid level pushes the float to open the valve seat, allowing for continuous and stable condensate discharge. When steam enters and the liquid level drops, the float falls back to close the valve, preventing steam leakage. The clamp-on wireless monitoring device uses sensors to collect real-time data on temperature, vibration, and drainage status, transmitting the data wirelessly for online monitoring, fault warnings, and maintenance optimization, improving system efficiency and reliability.
| Body Material | SS304 / SS316L Stainless Steel |
| Connection Type | Clamp / Threaded / Welded |
| Nominal Size | DN15 – DN50 (1/2" – 2") |
| Design Pressure | PN16 / PN25 / PN40 |
| Working Pressure | 16 – 40 bar |
| Working Temperature | 220 – 400°C |
| Applicable Media | Saturated Steam, Condensate |
| Surface Finish | Ra ≤ 0.8 μm |
| Standards | DIN / SMS / ISO / 3A |
Manufactured from stainless steel 317, providing superior corrosion resistance in superheated water and high-temperature steam conditions.
Thermodynamic disc operating principle ensures fast response, reliable condensate discharge, and effective prevention of live steam loss.
Compact and robust valve structure supports stable performance under fluctuating pressure and temperature test environments.
Suitable for superheated water testing systems, handling rapid temperature changes without distortion or sealing failure.
Simple internal design reduces maintenance frequency and ensures long service life in demanding industrial applications
The steam trap is widely used in chemical, power, oil refining, textile, and district heating systems. For example, in steam tracing pipelines of chemical plants, it continuously drains condensate to prevent water accumulation and water hammer; in power plant steam transmission systems, it ensures long-term stable equipment operation and reduces energy consumption.
Working Principles
The steam trap operates based on buoyancy and liquid level changes. When condensate enters the valve body, the rising liquid level pushes the float to open the valve seat, allowing for continuous and stable condensate discharge. When steam enters and the liquid level drops, the float falls back to close the valve, preventing steam leakage. The clamp-on wireless monitoring device uses sensors to collect real-time data on temperature, vibration, and drainage status, transmitting the data wirelessly for online monitoring, fault warnings, and maintenance optimization, improving system efficiency and reliability.
Feature and Specification
| Body Material | SS304 / SS316L Stainless Steel |
| Connection Type | Clamp / Threaded / Welded |
| Nominal Size | DN15 – DN50 (1/2" – 2") |
| Design Pressure | PN16 / PN25 / PN40 |
| Working Pressure | 16 – 40 bar |
| Working Temperature | 220 – 400°C |
| Applicable Media | Saturated Steam, Condensate |
| Surface Finish | Ra ≤ 0.8 μm |
| Standards | DIN / SMS / ISO / 3A |
Features
Manufactured from stainless steel 317, providing superior corrosion resistance in superheated water and high-temperature steam conditions.
Thermodynamic disc operating principle ensures fast response, reliable condensate discharge, and effective prevention of live steam loss.
Compact and robust valve structure supports stable performance under fluctuating pressure and temperature test environments.
Suitable for superheated water testing systems, handling rapid temperature changes without distortion or sealing failure.
Simple internal design reduces maintenance frequency and ensures long service life in demanding industrial applications
Application
The steam trap is widely used in chemical, power, oil refining, textile, and district heating systems. For example, in steam tracing pipelines of chemical plants, it continuously drains condensate to prevent water accumulation and water hammer; in power plant steam transmission systems, it ensures long-term stable equipment operation and reduces energy consumption.
