Name: HZ-DTS-1000 Series: Distributed Temperature Sensing (DTS) System
Brand: HERTZINNO
SKU: HZ0701001
Availability: InStock
Rating: 5 (1 reviews)

HZ-DTS is HERTZINNO’s distributed fiber optic temperature sensing system for real-time, online and continuous thermal monitoring. Using Raman scattering and optical time-domain sensing technology, the system converts optical fiber into a distributed temperature sensor, enabling precise temperature detection, hotspot identification and accurate event localization along long-distance assets.

Model

HZ-DTS-1004 / 1008 / 1016

Monitoring Range

Up to 13 km

Temperature Resolution

0.1°C

Temperature Accuracy

±0.5°C

Spatial Resolution

1 m

Sampling Interval

0.4 m / 0.8 m

Measurement Temperature Range

-40°C to 500°C

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Product Summary

HZ-DTS is a distributed temperature sensing system designed for long-distance thermal monitoring of critical infrastructure. Unlike point temperature sensors, DTS uses optical fiber as a continuous sensing line, providing temperature information along the entire fiber route with accurate location data. It helps operators identify cable overheating, fire risks, pipeline thermal anomalies and data center power route temperature changes before they develop into failures.

13 km / 20 km

Up to 13 km for multimode DTS and up to 20 km for single-mode DTS configuration.

0.1°C

Temperature resolution for precise thermal trend monitoring.

±0.5°C

Temperature accuracy for reliable condition monitoring and alarm logic.

4 / 8 / 16 Channels

Flexible channel options for multi-route monitoring.

Raman DTS Principle

How fiber scattering becomes a temperature profile

Inside the sensing fiber, the laser pulse generates Raman backscattering. The Stokes signal is relatively stable and used as a reference, while the Anti-Stokes signal increases as temperature rises. HZ-DTS calculates temperature from the Anti-Stokes / Stokes ratio and uses OTDR return time to locate the event along the fiber.

Temperature changes the Anti-Stokes signal.

When the local fiber temperature rises, molecular vibration increases. This strengthens the Anti-Stokes Raman backscatter, while the Stokes signal remains comparatively stable. The ratio between the two signals is converted into temperature.

Temperature relation Temperature ∝ Anti-Stokes / Stokes intensity ratio. OTDR timing determines where that ratio change happens.

0 m

0.4 m

0.8 m

1.2 m

1.6 m

2.0 m

2.4 m

2.8 m

3.2 m

3.6 m

4.0 m

0.4 m sampling space
DTS records temperature data point-by-point along the sensing fiber.

Signal ratio Anti-Stokes rises with temperature. Stokes is used as the reference.

OTDR location The optical return time identifies distance, so each temperature value is mapped to a position along the fiber.

Laser Pulse

The DTS analyzer sends short optical pulses into the sensing fiber.

Raman Scattering

Stokes and Anti-Stokes Raman signals return from each point of the fiber.

Temperature Ratio

A stronger Anti-Stokes signal indicates higher local fiber temperature.

OTDR Mapping

Return time maps the temperature result to an accurate distance location.

Applications

Where HZ-DTS is used

HZ-DTS is designed for continuous fiber optic temperature monitoring along power cables, data centers, pipelines, tunnels and critical infrastructure routes where operators need early hotspot detection and accurate event localization.

Power Cable

Power Cable Temperature Monitoring

Monitor underground cables, cable tunnels, joints and cable routes to detect overheating, insulation risks and abnormal thermal events.

Data Center

Data Center Thermal Monitoring

Track temperature changes along power cable routes, busduct areas, battery rooms and critical power infrastructure in data centers.

Pipeline

Pipeline Temperature Monitoring

Detect thermal anomalies along pipeline routes and support leak-related temperature monitoring for oil, gas and industrial pipelines.

Substation

Substation Cable Route Monitoring

Monitor cable exits, cable trays, transformer cable routes and power distribution areas for abnormal temperature rise.

Tunnel

Tunnel & Utility Corridor Fire Detection

Use passive sensing fiber for early fire detection and hotspot localization in tunnels, utility corridors and underground spaces.

Product Family

Distributed Fiber Optic Sensing

Compare HZ-DTS with distributed acoustic sensing and intelligent fiber optic monitoring systems for long-distance asset protection.

Technical Specifications

Core HZ-DTS specifications

Essential parameters for distributed fiber optic temperature sensing, power cable monitoring, data center thermal monitoring, pipeline temperature monitoring and long-distance hotspot localization.

Product Type

Distributed temperature sensing system

Sensing Principle

Raman scattering and optical time-domain sensing

Models

HZ-DTS-1004 / 1008 / 1016

Operating Distance

Up to 13 km

Temperature Resolution

0.1°C

Temperature Accuracy

±0.5°C

Sampling Space

0.4 / 0.8 m

Spatial Resolution

1 m

Temperature Range

-40°C to 500°C

Response Time

2 s for 2 km; less than 10 s for 13 km

Built-in Channels

4 / 8 / 16 channels

Sensor Configuration

4 / 8 / 16 ports

Sensing Fiber

Multimode fiber 50/125 or 62.5/125 optional

Transmission Port

RJ45 TCP

Data Port

USB-A 3.0

I/O Output

16 channels optional

Internal Storage

120 GB

Power Supply

220 VAC

Chassis

2U rackmount

Working Temperature

-20°C to 70°C

Typical Applications

Power cables, data centers, pipelines, tunnels and utility corridors

Note: Monitoring distance, channel number, sensing fiber type, relay output and alarm strategy should be configured according to the asset route and project requirements. For single-mode long-distance projects, HZ-DTS-1004S can support up to 20 km monitoring distance.

HZ-DTS Distributed Temperature Sensing FAQ

Common questions about fiber optic temperature monitoring, power cable thermal monitoring, data center temperature monitoring and distributed fire detection.

What is HZ-DTS used for?

HZ-DTS is used for distributed temperature monitoring along power cables, data centers, pipelines, tunnels, utility corridors and critical infrastructure routes.

What is the difference between DTS and point temperature sensors?

Point sensors measure temperature only at fixed locations. DTS uses optical fiber as a continuous temperature sensor, providing temperature data along the full fiber route with location information.

Can HZ-DTS monitor power cables?

Yes. HZ-DTS is suitable for underground cable monitoring, cable tunnel monitoring, substation cable route monitoring and hotspot detection along power cable systems.

Can HZ-DTS be used in data centers?

Yes. HZ-DTS can monitor cable routes, busduct areas, power distribution paths and other critical thermal zones in data center power infrastructure.

Does the sensing cable need power?

No. The sensing fiber is passive and requires no electrical power in the field, which makes it suitable for electrical, underground and harsh environments.

Which model should I choose?

Choose HZ-DTS-1004 for smaller multi-route systems, HZ-DTS-1008 for medium multi-zone monitoring, HZ-DTS-1016 for large-scale monitoring, and HZ-DTS-1004S when longer single-mode monitoring distance is required.

Plan your distributed temperature monitoring system.

Tell us your asset type, monitoring distance, fiber route, temperature range, channel requirements and integration needs. HERTZINNO will help you choose the right HZ-DTS configuration.

Request DTS Solution

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PRODUCTS: Acoustic Imaging Cameras; Acoustic Fingerprint Solutions; Transmission Line Monitoring; Optic Fiber Sensing

Contact Us: Greenland Mtown, No. 515, Huanke Road, Pudong District, Shanghai, China; info@hertzinno.com

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