Natural Gas Thermal Mass Flow Meter
Natural Gas TMF Build
Accuracy of ±1.0% of rate
Temperature service −45 to +150 °C
Turndown ratio of 1:1200
- Line sizes DN10 to DN300
- Working pressure ≤ 2.5 MPa standard, up to 6.3 MPa on request
- Sensor wetted parts 316L stainless or Hastelloy C
The Natural Gas Thermal Mass Flow Meter measures pipeline natural gas on factory inlets, M&R stations, and CHP feed lines. Reads mass flow directly from heater power with no external T+P stack.
316L stainless wetted parts handle dry pipeline gas. CNEX Ex d IIC T6 Gb hazardous-area protection ships standard. Lead time stays 5–7 business days.
Benefits
- Direct mass flow: thermal-dispersion outputs Nm³/h on 4-20 mA; replaces orifice + DP + T + P + flow-computer stack below 2.5 MPa.
- ±1.0 % of rate: grade A standard with ±0.5 % repeatability; sufficient for boiler fuel logging and city-gate branch sub-measurement.
- 0.1 Nm/s low-flow detection: resolves low-fire burner hold and idle that orifice + DP (square-root-error below 30 %) reads with degraded accuracy.
- 1:1200 velocity turndown: one model covers low-fire through high-fire peak; no dual-orifice or parallel-meter bypass piping.
- On-board calorific log: MJ/Nm³ and kWh-equiv on configured GB/T 13611 reference, exporting hourly over Modbus or 4G GPRS.
- Hazardous-area: CNEX Ex d IIC T6 Gb (flameproof, Zone 1) standard; IP65/66/67 and EMC 2014/30/EU.
- Lead time: 5–7 business days from the factory.
Configure your build.
Select your specs; we’ll generate a TMF 12-position model code and ballpark price. Submit to engineering for verified sizing against your boiler nameplate, burner turndown curve, and gas composition within 4 business hours.
Your Configuration
TMF-100-U-A-EX-4-6-M4-2-2-Q-S
Pipe sizeDN100
TransmitterIntegral Ex d
Accuracy±1.0 % of rate
ConnectionFlanged ANSI 150 / PN25
NG referenceGB/T 13611
Gas curveFactory CH₄ 95 %
AGA-style correctionOff (< 2.5 MPa)
Output4-20 mA + HART
Pressure class≤ 2.5 MPa
Estimated unit price
Verified after engineer review
$2,680
Subtotal (× 1)$2,680
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✓ Ex d (CNEX flameproof) standard; CNEX + CNEX certificates
✓ Factory CH₄ calibration + calorific-value setup
✓ GB/T 13611 reference conditions pre-configured
✓ Reply within 4 business hours
✓ Factory CH₄ calibration + calorific-value setup
✓ GB/T 13611 reference conditions pre-configured
✓ Reply within 4 business hours
Typical applications
Industrial Boiler Fuel
Modulating industrial boilers across the full 1:1200 modulation range.
CHP Fuel Input
Gas-engine and gas-turbine CHP at 0.3–0.8 MPa, no Z-factor. MJ/h + kWh delivers monthly heat-rate and efficiency reporting.
Furnace / Kiln Burners
Wide-modulation service on steel reheat, ceramic kilns, glass-tank burners. +65 °C ambient covers near-furnace mounting; CNEX Ex d standard.
City-Gate Branch Allocation
Splits city-gate pipeline invoice across tenant branches by actual Nm³. ±1.0 % replaces share-of-capacity estimation.
Specifications
Performance
| Accuracy | ±1.0 % of rate grade A · ±1.5 % of rate grade B · ±0.5 % repeatability |
|---|---|
| Velocity range | 0.1 to 120 Nm/s (turndown 1:1200) |
| Temperature measurement | Pt1000 reference RTD, integrated · ±0.3 °C |
| Response time | 1 second |
| Pressure loss | Negligible > DN80 (< 1 kPa at rated flow) · wall-mounted probe, no bluff body |
| Power supply | 24 V DC or 220 V AC · ≤ 18 W maximum |
Process & Hazardous Area
| Medium | Pipeline-quality natural gas (CH₄-dominant), associated gas, processed NG after condensate separation |
|---|---|
| Pressure range | ≤ 2.5 MPa standard · 4.0 / 6.3 MPa / ANSI 300–600 LB on request |
| Medium temperature | -45 to +150 °C |
| Ambient temperature | -35 to +65 °C · 5 % to 90 % RH · 86 to 106 kPa atmospheric |
| Enclosure rating | IP66 + Ex d (CNEX flameproof) flameproof STANDARD · CNEX · GB 3836 |
| Signal distance | Sensor to remote Ex cabinet: up to 1000 m (square-head form) |
Gas Handling & Calorific Logging
| Hourly log record | Timestamp · Nm³ cumulative · Nm³/h avg · P · T · MJ/Nm³ · kWh-equivalent |
|---|---|
| Log capacity | 128 MB non-volatile · ~7 years at 1-hour granularity (rolls over) |
| Gas-composition input | Manual entry at commissioning · HART update from in-line GC optional |
| Calorific calculation | GB/T 11062 / factory heat-value table HHV or LHV · auto-compute from composition |
| CSV export | USB flash · Modbus register dump · optional MQTT push to cloud |
| Output stack | 4-20 mA + HART · Pulse · RS485 Modbus · PROFIBUS-DP · Foundation Fieldbus · 4G GPRS |
Materials & Construction
| Sensor wetted parts | 316L standard · Hastelloy C-276 optional (sour-gas service) |
|---|---|
| Body material | 304 SS standard · 316 SS · Hastelloy C optional |
| Sensor pair | Two Pt-class RTDs: one temperature reference, one heated at fixed ΔT |
| Electrical entry | M20 × 1.5 internal thread or ½″ NPT · Ex d flameproof cable gland |
| Housing | Aluminium alloy or stainless · Ex d (CNEX flameproof) flameproof enclosure · IP66 ingress |
| Net weight (DN100) | 12.4 kg integral, ANSI 150 flange · Ex d housing adds ~2 kg over IP66 version |
Flow range by pipe size.
Natural-gas flow range in Nm³/h referenced to GB/T 13611 (20 °C, 101.325 kPa) at 0.8 MPa gauge line pressure. The MJ/h column uses 37.5 MJ/Nm³ HHV; the engineering team validates against the boiler nameplate and burner turndown curve.
| Pipe size | Minimum (Nm³/h) | Typical range (Nm³/h) | Maximum (Nm³/h) | MJ/h at peak |
|---|---|---|---|---|
| DN15 (½″) | 0.4 | 4 – 31 | 50 | up to 1,875 |
| DN25 (1″) | 0.4 | 12 – 94 | 135 | up to 5,063 |
| DN40 (1½″) | 0.4 | 31 – 250 | 350 | up to 13,125 |
| DN50 (2″) | 0.8 | 47 – 327 | 468 | up to 17,550 |
| DN80 (3″) | 1.6 | 117 – 819 | 1,170 | up to 43,875 |
| DN100 (4″) | 2.3 | 180 – 1,255 | 1,794 | up to 67,275 |
| DN150 (6″) | 5 | 406 – 2,840 | 4,056 | up to 152,100 |
| DN200 (8″) | 9.4 | 702 – 4,914 | 7,020 | up to 263,250 |
| DN250 (10″) | 14 | 1,131 – 7,917 | 11,310 | up to 424,125 |
| DN300 (12″) | 19.5 | 1,638 – 11,466 | 16,380 | up to 614,250 |
Installation
Five rules deliver audit-ready kWh and MJ/h numbers.
- Downstream of regulator and dryer; regulator-tracked pressure swings bias the reading; mount after pressure stabilizes and after any dehydrator.
- 10×DN upstream, 5×DN downstream; single-point velocity biases on swirl profiles. Flow-straightener sleeve drops to 5×DN/3×DN (+6 %).
- Match GB/T 13611 reference at order; China 20 °C/101.325 kPa; EU ISO 13443 (15 °C); US 60 °F/14.696 psia.
- CNEX Ex d IIC T6 Gb standard; Zone 1 covers boiler-houses, CHP skids, city-gate stations; dual-compartment near gas engines.
- Configure MJ/h log at commissioning; load contract gas composition (CH₄/N₂/CO₂) once.
Frequently asked questions
Why specify a thermal mass meter for natural gas instead of orifice, turbine, or ultrasonic?
Each of the four candidate technologies has a sweet spot; and TMF-NG owns a very specific one. Orifice plate + DP transmitter is the legacy reference for custody-transfer fiscal measurement at high pressure (AGA 3 / ISO 5167) but its square-root authority collapses below 20 % of rated flow; a modulating industrial boiler running 10:1 turndown is invisible to an orifice below low-fire. Turbine meters (AGA 7) hit ±0.5 % accuracy and 10:1 turndown with wet-calibration but have rotating bearings that wear, suffer jet-contamination stalls on dirty landfill-adjacent gas, and cannot sit on a line that occasionally runs in reverse. Ultrasonic (AGA 9) is the modern custody-transfer standard for transmission-pipeline scale (DN300+ at 6.3 MPa+) but carries the capital cost to match. TMF-NG fits the five cases those alternatives struggle: (1) industrial boiler fuel line that needs 100:1 turndown from low-fire hold to high-fire peak, (2) no budget for a flow computer to run AGA-style on a 1.0 MPa supply where the correction is inside the accuracy range anyway, (3) the line has solenoid shut-off trip cycles that would stall a turbine’s bearings, (4) the measurement point has < 10D upstream straight pipe, (5) the site needs one instrument for each branch meter with full Ex d (CNEX flameproof) factory-standard, not as an optional upgrade. Specify natural-gas vortex when the clean dense-gas retrofit needs the lower capital cost per DN. Specify natural-gas precession swirl when space is tight and 3D+2D straight-pipe is the decisive constraint.
Do I need a separate AGA-style compressibility correction for natural gas?
It depends on the line pressure. Below 2.5 MPa; which covers the vast majority of industrial boiler-fuel and process-heating installations; the compressibility factor Z for typical pipeline-quality natural gas is 0.99 to 1.00, so AGA-style correction is below the meter’s ±1.0 % of rate accuracy range and you can safely skip it. Above 2.5 MPa; city-gate branch lines, high-pressure industrial mains, gas-turbine feed; Z drops into the 0.96 to 0.94 range and the correction becomes measurable. For those cases the TMF-NG offers an optional on-board AGA-style / GB/T 11062 compressibility block: enter gas-chromatograph composition and the meter applies the Z-factor correction internally using the raw sensor-bus pressure and temperature readings. This avoids the external flow computer but still delivers AGA-style-traceable Nm³/h. The TMF is not, by itself, a custody-transfer meter; if the application is fiscal measurement at a city-gate, pair it with an ultrasonic (AGA 9) primary and use the TMF-NG for check-measurement, not as the fiscal reference. For boiler fuel, CHP input, and factory branch flow measurement (the 80 % of applications), the native reading is accurate enough without AGA-style correction at all.
What Ex protection does a natural-gas thermal mass meter need?
Ex d (CNEX flameproof) flameproof is the standard build on the TMF-NG; not optional; because any line carrying pipeline-quality natural gas is classified Zone 1 or Zone 2 by default under IEC 60079 / GB 3836. Zone 1 covers the immediate area around flanges, valves, and the meter body where a gas release is expected during normal operation (typically 1 meter radius). Zone 2 covers the wider boiler room, metering station enclosure, or utility tunnel. IIB is the gas group for methane-based fuel gases (IIB1 for pure methane, IIB for typical pipeline NG with some ethane and propane). T4 is the temperature class; surface temperature limit 135 °C, which leaves adequate margin over the meter’s internal electronics. The TMF-NG ships with CNEX and CNEX certificates covering flameproof construction, flameproof cable-gland entries, and the integral display window. For Zone 0 applications (very rare in NG service; typically only inside a vent stack) the insertion TMFW with remote transmitter and a Zone 0-rated sensor head is the correct product. If the line routes through a general-purpose metering cabinet where the atmospheric concentration is positively below 10 % LEL under all failure modes, the meter can be derated to IP66 general-purpose; but that is an engineering exercise you do not want to run on anything new. Default is Ex d (CNEX flameproof).
Can I use the TMF-NG for custody-transfer / fiscal measurement?
Not as the primary fiscal reference. Custody transfer at the city-gate is governed by AGA 3 / AGA 7 / AGA 9 in the US, and GB/T 21391 (turbine) or GB/T 18603 (ultrasonic) in China; these require type-approval testing and ±0.5 % uncertainty budgets. Thermal mass falls under GB/T 32201 as a measurement-grade technology, not a fiscal reference. Where the TMF-NG earns its place: (a) check-measurement against a primary AGA 9 ultrasonic to detect drift and composition shifts, and (b) industrial sub-measurement where the operator bills at the city-gate master and the site splits the invoice by actual Nm³ — more accurate than burner-capacity allocation. If the facility is itself the fiscal seller (e.g. CHP steam to a tenant), specify AGA 9 ultrasonic or AGA 7 turbine as primary and use TMF-NG for operational instrumentation.
Need help sizing the natural-gas build?
Send pipe size, boiler MW + turndown, line pressure, gas composition. Engineer replies with sized Nm³/h + MJ/h, model code, price in 4 hours.