Dongling MonitoringIntegrated Testing / Sensing / Monitoring
Haiyang Energy Facility, China

Industrial Equipment Vibration and Temperature Monitoring

A power generation monitoring architecture for pipeline vibration, valve system vibration, turbine pipeline health, condenser pipeline condition, and high-temperature sensor deployment.

Project Type

Industrial Equipment Monitoring

System Scale

heating extraction steam valves, high-pressure exhaust pipelines, heat-exchange extraction pipelines, turbine pipelines, condenser pipelines, and distributed temperature and vibration points

Data Output

pipeline vibration, valve vibration, turbine pipeline vibration, condenser pipeline vibration, pipeline temperature, scheduled status data

Engineering Value

How the system supported engineering decisions

The case converts power generation valve, pipeline, turbine, and condenser monitoring into one public DL-SHM workflow.

High-temperature DL-SEN vibration and temperature points are mapped to DL-DAQ acquisition and DL-SHM alarm management.

The monitoring scope supports early abnormal-condition detection for heating and turbine pipeline equipment.

Monitoring Content

Monitoring scope and field constraints addressed by the deployment

High-temperature valve and steam pipeline zones required stable vibration capture without exposing sensors to thermal interference.

Permanent turbine and condenser pipeline monitoring required long-term synchronized acquisition and health alarm management.

Pipeline temperature and vibration points required periodic remote acquisition and transmission to a monitoring center.

System Configuration

Configured system architecture and data path

Field Devices

DL-SEN high-temperature acceleration, temperature, and industrial vibration sensors installed on valves, steam pipelines, turbine pipelines, condenser pipelines, and heating pipeline sections

Communication Layer

Synchronized wired acquisition and remote scheduled transmission from field points to DL-DAQ systems

Central Platform

DL-SHM monitoring systems for vibration trend display, pipeline status review, alarm management, data storage, and engineering reporting

Sensor Deployment

Sensor layout and measurement purpose

Heating extraction steam valves and high-pressure exhaust pipelines

DL-SEN high-temperature acceleration sensors

Capture valve and pipeline vibration to identify abnormal operating response

Turbine and condenser pipeline sections

DL-SEN high-temperature and low-temperature vibration sensors

Monitor turbine load influence on pipeline vibration under permanent health monitoring conditions

Distributed heating pipeline points

DL-SEN temperature and piezoelectric acceleration sensors

Collect pipeline temperature and vibration records at multiple locations

Monitoring center

DL-DAQ systems and DL-SHM monitoring systems

Provide scheduled acquisition, data transmission, real-time trend review, intelligent alarms, and engineering reports

DL-SEN field sensors to DL-DAQ synchronized acquisition, acquisition to DL-SHM monitoring, platform to alarm workflow and industrial equipment review

Data Analysis Results

Monitoring indicators and interpretation

Trend output

Pipeline and valve vibration

high-temperature vibration records

Operators could observe vibration behavior around steam valves and key pipeline sections.

Turbine pipeline health

permanent vibration monitoring dataset

Turbine load influence on pipeline condition could be reviewed through long-term data.

Remote pipeline status

scheduled temperature and vibration acquisition

Distributed monitoring points supported remote status review from the monitoring center.

Engineering Credibility

Reliability, topology, and project validation

99.98%

target data availability

IP67/68

field protection classes

4G/Fiber

site transmission options

RFQ

project-based configuration

Measurement planning

Monitoring object, measurement range, sampling rate, and signal type guide project configuration.

Communication options

DL systems support project configurations using wired, wireless, GNSS, and gateway-based communication methods.

Documentation support

Datasheets and technical selection information are available upon request for RFQ preparation.

Product selection should be confirmed against site conditions, measurement points, installation environment, and expected data output.

Structured RFQ Path

Request path for Industrial Equipment Monitoring Project

Step 1

Define Data Nodes

Sensor, wireless node, GNSS station, seismic unit, or DAQ field layer.

Step 2

Configure Network

Civil infrastructure, industrial equipment, heritage, seismic, or research monitoring chain.

Step 3

Build RFQ Scope

Asset type, measurement points, channels, sampling rate, communication, environment, and duration.

Step 4

Review Proposal

Receive system architecture, product configuration, data output, and engineering review structure.

Project Overview

Engineering context and monitoring scope

Haiyang power generation projects required vibration monitoring on Unit 1 heating supply pipelines and valves, permanent health monitoring for turbine and condenser pipelines, and online monitoring of heating pipeline temperature and vibration. The source deck describes high-temperature acceleration sensors installed on heating extraction steam regulating valves, high-pressure exhaust pipelines, heat-exchange extraction pipelines, turbine pipelines, and distributed pipeline locations.

Client type

Power generation turbine island and heating pipeline operation teams

System scale

heating extraction steam valves, high-pressure exhaust pipelines, heat-exchange extraction pipelines, turbine pipelines, condenser pipelines, and distributed temperature and vibration points

Project type

Industrial Equipment Monitoring