| Customization: | Available |
|---|---|
| After-sales Service: | 24/7 After Sales Services |
| Warranty: | 12 Months From Delivery |
|
Still deciding? Get samples of US$ 400/Piece
Order Sample
|
| Shipping Cost: | Contact the supplier about freight and estimated delivery time. |
|---|
| Payment Methods: |
|
|---|---|
| Support payments in USD |
| Secure payments: | Every payment you make on Made-in-China.com is protected by the platform. |
|---|
| Refund policy: | Claim a refund if your order doesn't ship, is missing, or arrives with product issues. |
|---|
Suppliers with verified business licenses
Audited Supplier Audited by an independent third-party inspection agency
Product Overview
The ZZYS30 vortex flowmeter, a marvel of velocity flow technology, serves a multitude of applications with unmatched precision.
Engineered to perfection, it excels at measuring, monitoring, and controlling the flow of liquids, steam, and virtually all gases.
Boasting an innovative structure, it stands resilient against mechanical vibrations, impacts, and contamination.
Designed with no moving parts, this flowmeter experiences no wear and tear, requires zero mechanical maintenance, offers low pressure loss, and ensures stable, high-accuracy performance.
Installation is effortless, and the flexibility of matching the sensor and signal converter to specific needs is a game-changer.
Product features:
Broad application versatility, ideal for measuring the flow of steam, gas, and liquid with exceptional accuracy.
Superior vibration tolerance with zero drift at zero point, effectively neutralizing external vibration impacts.
The ZZY30 offers integrated temperature and pressure measurement options, significantly reducing installation costs.
Provides (0-5) kHz frequency output, (4-20) mA output, and supports HART communication/Modbus protocol for seamless data integration.
Featuring Bluetooth communication for parameter settings, it is wear-resistant, dirt-resistant, maintenance-free, ensures a long service life, and is explosion-proof for maximum safety.
Technical Index
Measurement Medium: Suitable for gas, liquid, and steam applications.
Connection Method: Available in flange clamp type, flange type, and insertion type for versatile installation options.
Caliber Specifications:
Flange Clamping Type: Available in sizes 25, 32, 50, 80, and 100 for a tailored fit.
Flange Connection Type: Select from sizes 100, 150, and 200 to suit your specific needs.
Flow Measurement Range: Achieve accurate readings with a Reynolds number range of 1.5×10^4~4×10^6. Gas flow velocity: 5~50m/s; Liquid flow velocity: 0.5~7m/s.
Normal Measurement Flow Range: Specifically designed for liquid applications,
Gas Flow Measurement Range: Refer to Table 2 for detailed specifications.
Steam Flow Range: Refer to Table 3 for comprehensive data.
Measurement Accuracy: Consistently precise with 1.0 and 1.5 class accuracy.
Measured Medium Temperature Range:
Room Temperature: -25ºC to 100ºC. High Temperature Range: -25ºC to 150ºC, extendable to -25ºC to 250ºC. Output Signal: Generates pulse voltage signals with a high level of 8~10V and low level of 0.7~1.3V. Pulse duty cycle is approximately 50%, with a transmission distance of up to 100m.
Pulse Current Remote Transmission Signal: 4-20 mA, with an impressive transmission distance of up to 1000m. Instrument Use Environment: Operates efficiently in temperatures from -25ºC to +55ºC and humidity levels of 5~90% RH at 50ºC. Constructed from durable stainless steel and aluminum alloy.
Power Supply: Options for DC24V or a 3.6V lithium battery to ensure continuous operation.
Explosion-Proof Grade: Certified intrinsically safe iaIIbT3-T6 with an IP65 protection level.
| Technical parameters | |
| Medium | Steam, Gas, Liquid |
| Measuring range | See flow1-3 |
| Caliber | DN15, DN25, DN40, DN50, DN80, DN100, DN200, DN250, DN300 |
| Medium pressure | ≤100 bar, more pressure need be customized |
| Medium temperature | -40°C~+240°C |
| Ambient temperature | Ordinary type: -40°C~+85°C Ex-proof type: -40°C~+60°C |
| Accuracy | Liquid, Re≥20000 is ±1.0%, gas and steam, ±1.5% |
| Repeatability | ±0.3% |
| Material | Measuring pipe:304,316L, HC276 |
| Sensor: 316L, HC276 | |
| Converter shell: casting aluminum | |
| Instrument caliber | Flange connection: DN15-DN300 |
| Clamping connection: DN15-DN100 | |
| Flange standard | DIN, ANSI, HG20592 (Can be customized) |
| Pressure loss Gasandliquid saturated steam |
ΔP=Cqv²Px ΔP: pressure loss(pa) qv: volume flow qm: mass flow ΔP=Cqm²Px PX: density C: constent |
| Display | Two-line LCD display, four button operation Instantaneous flow, accumulated flow, vortex frequency, medium temperature, pressure(selectable), circular or non-circular display |
| Power supply | Ordinary type: (14~36) VDC Ex-proof type: (14~30) VDC Battery power supply |
| Loading | No-ex-proof: RB=(UB-14DVC)/22MA≤1200Ω Ex-proof: RB=(UB-14DVC)/22MA≤600Ω |
| Output | Two wire 4~20mA |
| Ex-proof class | Exd II CT6 CE19.1438 Ex ( ia ) II CT6 |
| Cable interface | 1/2''NPT( Internal thread, recommended), M201.5 (Internal thread) |
| Housing protection class | IP67 |
| Connection type | Flange (DN15-DN300), Clamping (DN15-DN100) |
| Mounting type | Integral mounting, split mounting (special shielded cable connect the pipe and indicator) |
| Gas | |||
| Air: t=20°C p=1.013bar abs =1.7210-4 mpa.s Q: flow (sheet 1) | |||
| Nominal diameter | Internal diameter | Qmin(m3/h) | Qmax(m3/h) |
| DN15 | 16 | 6.79 | 32.56 |
| DN25 | 24 | 10.20 | 113.94 |
| DN40 | 38 | 25.3 | 326.63 |
| DN50 | 50 | 43.89 | 565.49 |
| DN80 | 74 | 96.14 | 1238.64 |
| DN100 | 97 | 165.14 | 2128.27 |
| DN150 | 146 | 374.23 | 4821.57 |
| DN200 | 193 | 702.95 | 9056.8 |
| DN250 | 253 | 1123.7 | 14478 |
| DN300 | 305 | 1632.1 | 21028 |
| Liquid | |||
| Water: t=20°C p=1.013bar abs ≤10cp Q: flow | |||
| Nominal diameter | Internal diameter | Qmin(m3/h) | Qmax(m3/h) |
| DN15 | 16 | 0.45 | 5 |
| DN25 | 24 | 0.81 | 11.40 |
| DN40 | 38 | 2.04 | 28.57 |
| DN50 | 50 | 3.53 | 49.47 |
| DN80 | 74 | 7.74 | 108.37 |
| DN100 | 97 | 13.30 | 186.21 |
| DN150 | 146 | 30.13 | 421.86 |
| DN200 | 193 | 52.66 | 792.42 |
| DN250 | 253 | 90.5 | 1266.8 |
| DN300 | 305 | 113.41 | 1839.8 |
| Saturated steam | |||||||||
Nominal Diameter |
Inner Diameter |
Mass flow Qm (kg/h) under different pressure and density | |||||||
| P=1bar G | P=3.5bar G | P=5.2bar G | P=7 bar G | ||||||
| ρ=1.13kg/m3 | ρ=2.43kg/m3 | ρ=3.28kg/m3 | ρ=4.17kg/m3 | ||||||
| t=120.6°C | t=148.2°C | t=160.4°C | t=170.6°C | ||||||
| min | max | min | max | min | max | min | max | ||
| DN15 | 16 | 5.87 | 36.97 | 7.68 | 79 | 8.93 | 106.68 | 10.06 | 135.69 |
| DN25 | 24 | 11.82 | 129.39 | 17.26 | 276.4 | 20.09 | 373.53 | 22.66 | 474.82 |
| DN40 | 38 | 29.64 | 370.71 | 43.33 | 792.33 | 50.63 | 1070.2 | 56.8 | 1361.2 |
| DN50 | 50 | 51.31 | 641.82 | 75.02 | 1371.8 | 87.19 | 1852.8 | 98.33 | 2356.6 |
| DN80 | 74 | 112.41 | 1405.8 | 164.33 | 3004.7 | 191 | 4058.4 | 215.39 | 5161.8 |
| DN100 | 97 | 193.14 | 2415.5 | 282.36 | 5162.7 | 328.16 | 6973.3 | 370.09 | 8869.2 |
| DN150 | 146 | 437.56 | 5472.4 | 639.69 | 11696 | 743.45 | 15798 | 838.44 | 20093 |
| DN200 | 193 | 821.91 | 10279 | 1201.6 | 21970 | 1396.5 | 29675 | 1574.9 | 37743 |
| DN250 | 253 | 1313.9 | 16433 | 1920.9 | 35122 | 2232.5 | 47439 | 2517.7 | 60337 |
| DN300 | 305 | 1908.3 | 23866 | 2789.8 | 51010 | 3242.4 | 68899 | 3656.6 | 87630 |
Nominal Diameter |
Inner Diameter |
Mass flow Qm (kg/h) under different pressure and density | |||||||
| P=10.5 bar G | P=14 bar G | P=17.5 bar G | P=20 bar G | ||||||
| ρ=5.89kg/m3 | ρ=7.6kg/m3 | ρ=9.32kg/m3 | ρ=10.54kg/m3 | ||||||
| t=186.2°C | t=198.5°C | t=208.5°C | t=215.6°C | ||||||
| min | max | min | max | min | max | min | max | ||
| DN15 | 16 | 12.78 | 191.71 | 16.51 | 247.55 | 20.23 | 303.36 | 22.89 | 343.32 |
| DN25 | 24 | 26.93 | 670.88 | 30.6 | 857.88 | 33.87 | 955.48 | 36.04 | 1201.41 |
| DN40 | 38 | 67.51 | 1878.2 | 76.72 | 2150.7 | 84.93 | 2395.3 | 90.35 | 2557.7 |
| DN50 | 50 | 116.89 | 3251.7 | 132.82 | 3723.4 | 147.03 | 4147 | 156.42 | 4428.1 |
| DN80 | 74 | 256.03 | 7122.4 | 290.93 | 8155.8 | 322.06 | 9083.7 | 342.62 | 9699.3 |
| DN100 | 97 | 439.91 | 12238 | 499.9 | 14013 | 553.38 | 15608 | 588.69 | 16666 |
| DN150 | 146 | 996.62 | 27725 | 1132.5 | 31747 | 1253.7 | 35359 | 1333.7 | 37756 |
| DN200 | 193 | 1872.1 | 52079 | 2127.3 | 59634 | 2354.9 | 66419 | 2505.2 | 70921 |
| DN250 | 253 | 2992.7 | 83254 | 3400.71 | 95333 | 3764.6 | 106180 | 4004.9 | 113380 |
| DN300 | 305 | 4346.5 | 120920 | 4939.1 | 138460 | 5467.5 | 154210 | 5816.5 | 164660 |
| Selection list | ||||||||
| model | Explanation | |||||||
| ZZY30 | ||||||||
| Connection | F | Flange connection | ||||||
| W | Flange clamping | |||||||
| Temperature Resistance Class |
T1 | Match with 250°c probe | ||||||
| T2 | Match with 350°c probe | |||||||
Nominal diameter |
015 | DN15 | ||||||
| 020 | DN20 | |||||||
| 025 | DN25 | |||||||
| 032 | DN32 | |||||||
| 040 | DN40 | |||||||
| 050 | DN50 | |||||||
| 065 | DN65 | |||||||
| 080 | DN80 | |||||||
| 100 | DN100 | |||||||
| 125 | DN125 | |||||||
| 150 | DN150 | |||||||
| 200 | DN200 | |||||||
| 250 | DN250 | |||||||
| 300 | DN300 | |||||||
Structure |
Z | Integrated T and P compensation | ||||||
| F | Regular model | |||||||
| S | Split | |||||||
| Material | R1 | 304 | ||||||
| RL | 316L | |||||||
Instrument model |
N | 24V power supply Output 3 wire pulse | ||||||
| V1 | 24V power, on-site display, 4-20mA, RS485, Impulse output | |||||||
| V1 B |
24V +battery power supply, on-site display, 4-20 mA, RS485, pulse output | |||||||
| Pressure Class | N | Normal | ||||||
| H | High pressure | |||||||
PACKING & SHIPPING
We ensure timely delivery of your ordered products, adhering strictly to your required schedule.
Key Installation Requirements
Piping Conditions
For optimal performance, installing the vortex flowmeter necessitates a specific length of straight pipe section both before and after the device. The typical scenarios to consider (where D represents the pipe diameter) include:
| Piping condition | upstream | Downstream |
| Concentric shrinkage pipe full open gate valve |
15D | 5D |
| ∠90° square elbow | 20D | 5D |
| Same plane 2∠90°elbow | 25D | 5D |
| Semi-open gate valve regulating valve | 50D | 5D |
| Different plane 2∠90°elbow | 40D | 5D |
| With rectifier tube bundle | 12D | 5D |
1.
The sensor must be affixed to a pipeline that is horizontal, vertical, or inclined (with liquid flowing upwards) and matches the sensor's diameter. Ensure a specific length of straight pipe before and after the sensor: 15-20D for the upstream section and 5-10D for the downstream section.
2.
Ensure the pipe around the liquid sensor is filled with the liquid being measured.
3.
Avoid installing the sensor on pipes exposed to strong mechanical vibrations.
4.
The inner diameter of the straight pipe section should match the sensor's diameter as closely as possible. If not, use a slightly larger diameter, with an error margin of ≤3% and not exceeding 5mm. Do not install the sensor in areas with strong electromagnetic interference, limited space, or where maintenance is inconvenient..
5.
Horizontal pipeline installation is the most prevalent for flow sensors. For gas flow measurement with slight liquid content, place the sensor at the highest point. For liquid flow measurement with slight gas content, install it at the lowest point.
6.
Vertical pipeline installation for sensors: For gas flow, the sensor can be installed with no flow direction restriction. If gas contains some liquid, ensure the flow is bottom-up. For liquid flow, the flow should be bottom-up to prevent additional weight on the probe.
7.
Side installation on horizontal pipelines: Suitable for superheated steam, saturated steam, and low-temperature liquids. Side mounting is preferred if possible to reduce temperature effects on the amplifier.
8.
Inverted installation on horizontal pipelines is generally discouraged, except for saturated steam and high-temperature liquids or systems needing frequent cleaning.
9.
When dealing with high-temperature steam, the insulation layer should be limited to one-third of the bracket height.
10.
For pressure and temperature measurement points, based on the requirements: place the pressure measurement point 3-5D downstream and the temperature measurement point 6-8D downstream of the sensor.
){kind=link}