gnss settlement sensors
The JMCJ-1003/1005 magnetic ring settlement water level gauge gives Kingmach gnss settlement sensors a manual borehole method for layered ground. It measures underground settlement by electromagnetic induction between the probe and magnetic rings, and it measures water level by conductivity when the probe contacts groundwater. The instrument uses a probe, reel, tape, battery, audible or visual indication, and magnetic rings placed at known depths. Published depth options include 30 m, 50 m, and 100 m, with plus or minus 1 mm accuracy, 9V battery power, maximum current of 50 mA, a probe about 17 cm long and 3 cm in diameter, and -20 degrees Celsius to 60 degrees Celsius operating environment. This product is useful where the engineer needs to know which soil layer compressed, not just how much the surface moved. A careful log should keep borehole number, ring depth, water depth, reference mark, operator, weather, and construction activity together for each visit.

Application of gnss settlement sensors
In foundation pit projects, gnss settlement sensors are used during staged excavation to track base uplift, nearby pavement settlement, groundwater response, and vertical movement around retaining systems. The timing of each value matters because deformation may change after dewatering, support installation, soil removal, rainfall, or backfilling. Kingmach JMDL-47XXAT can be embedded to follow base uplift or local settlement, while JMCJ-1003/1005 can read magnetic ring depth and groundwater level in boreholes. Hydrostatic instruments may be added where several elevations around the pit need comparison against a reference. The site team should record excavation depth, support level, water pumping condition, adjacent road or building observations, and first stable baseline beside the settlement curve. If movement grows quickly, the response should include checking the sensor and reference first, then comparing support force, wall displacement, groundwater, and visual inspection before deciding whether excavation can continue. This keeps settlement review tied to the actual construction sequence, which is essential because a pit may behave differently at each excavation depth and support stage. A clear record also helps distinguish base rebound from surrounding ground loss or reference disturbance. The review file should also include reference condition, recent site work, nearby sensor behavior, and inspection notes so later teams can interpret the curve clearly.

The future of gnss settlement sensors
Future gnss settlement sensors will make long-term maintenance analytics more practical. Settlement records are often slow, which means the useful signal may appear over months instead of days. Platforms can compare cumulative settlement, daily rate, seasonal pattern, rainfall, groundwater, traffic loading, filling stage, and excavation history. Kingmach products such as JMYC-62XXAD and JMDL-47XXAT can support this longer view when the baseline and reference point remain stable. Owners will benefit from reports that separate normal consolidation from renewed deformation after new construction, water-level change, or heavy traffic. This is especially important for roadbeds, bridges, buildings, dykes, dams, and reclamation foundations where movement may continue after handover. Future reports should show rate changes, dormant periods, and renewed activity in a way maintenance teams can compare across many assets.

Care & Maintenance of gnss settlement sensors
Remote acquisition for gnss settlement sensors needs commissioning checks across the whole data chain. Verify RS485 wiring, bus address, power supply, channel name, units, reference point, and platform display before routine collection begins. For Kingmach hydrostatic sensors and automated settlement systems, move through each channel and confirm that the displayed point matches the physical location. Label cabinets, cables, tubes, and sensor numbers clearly. During operation, data gaps should be compared with power outages, communication faults, storms, cabinet work, or platform changes. If a sensor is replaced, record the old serial number, new serial number, old baseline, new baseline, and reason for replacement. Remote data is only trustworthy when the physical point and digital channel stay aligned. The record should include who inspected the point, what changed on site, and whether nearby instruments showed the same trend, so the maintenance team can separate sensor trouble from real settlement. The record should include who inspected the point, what changed on site, and whether nearby instruments showed the same trend, so the maintenance team can separate sensor trouble from real settlement.
Kingmach gnss settlement sensors
In underground works, gnss settlement sensors help separate vertical movement from the noise of excavation, support installation, groundwater, and nearby traffic. Tunnel bottom uplift, subway station settlement, foundation pit base heave, and adjacent ground movement can all affect construction safety. Kingmach JMDL-47XXAT is described for tunnel bottom uplift and base uplift in deep foundation pits, while hydrostatic products can compare several elevations across a station or tunnel section. The monitoring plan should define which reading triggers inspection, who receives the alert, and what nearby data should be checked. Settlement should be reviewed with displacement, support force, water level, tilt, and visual inspection. That wider view keeps a single curve from being overread or ignored. For critical infrastructure, the settlement point should be part of a wider review with displacement, tilt, strain, load, rainfall, and groundwater information. For critical infrastructure, the settlement point should be part of a wider review with displacement, tilt, strain, load, rainfall, and groundwater information.
FAQ
Q: What are gnss settlement sensors used for?
A: They measure vertical deformation such as foundation settlement, subgrade settlement, embankment heave, tunnel bottom uplift, dam settlement, bridge deflection, and building settlement.
Q: Which Kingmach models are related to this group?
A: Common models include JMDL-47XXAT, JMDL-62XXAT/ADT, JMQJ-62XXADT, JMYC-62XXAD, and JMCJ-1003/1005.
Q: What is the difference between single-point and hydrostatic monitoring?
A: Single-point gauges measure settlement at a specific embedded point, while hydrostatic systems compare several points against a reference level through connected liquid paths.
Q: Can the readings be collected remotely?
A: Yes. Several Kingmach hydrostatic and settlement instruments support RS485 output or automatic acquisition systems for remote collection.
Q: Why is the reference point important?
A: Settlement is often calculated relative to a reference. If the reference changes or is poorly documented, the whole settlement curve can become misleading.
Reviews
Andrew Lee
The visualization software is intuitive and powerful. It helps us analyze monitoring data efficiently.
Michael Anderson
The strain gauges and load cells are extremely accurate and stable. They performed very well in our bridge monitoring project. Highly recommended!
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