1.High measurements precision
2.Unique housing design
3.Easy data reading
4.Battery power supply
5.With compact
Port: Shanghai
Minimum Order Quantity: 1 Set/Sets
Supply Ability: 2000 Set/Sets per Month
Payment Terms: T/T
Contact SupplierPackaging Detail: Carton as per export standard.
Delivery Detail: within 7 workdays
DMTFW-E Energy Meter measuring energy flow for pipe DN50-250mm.
Series DMTFW-E transit-time ultrasonic energy meters utilize newest digital transit-time processing technology, with compact shape featuring longevity, good stability and high accuracy for all-electronic industrial environment. The meters are cost-effective, service-friendly, of simple design and extremely robust. Its new free-flow jet principle provides an extremely high measuring accuracy.
Features:
1.With compact, solid shape, suitable for bad environment conditions
2.No moving parts, no pressure loss or abrasion
3.Heat flow function
4.Low start-up flow rate,minimum measurable flow velocity 0.003m/s
5.Self-adapting ultrasonic receiving circuit, work stably in bad pipe condition
6.Quick transient response, can trace the flow rate change within seconds
7.With Infrared meter reading function
8.Battery power supply,can work constantly for 6 years
9.Unique housing design, can work underwater
10.Flange is made by mold to remove possibility of leakage
11.With self-diagnosing function and fault indicator
Main advantages:
1.High measurements precision: 0.1 C.
2.High operational reliability and minimum maintenance requirements
3.Compared to mechanical meters, very low hydraulic losses
4.Easy data reading, storage and evaluation/processing
5.Identification of leaks in water distribution systems
6.Measured data can be transferred to remote control stations
Applications:
1.static compact energy meter using ultrasonic technology
2.Highly accurate recording of all billing data in local and district heating and cooling systems.
3.Process control and instrumentation.
4.Substituting mechanical heat flow meters with high measuring reliability.
5.Technological measurements of instantaneous flow rate and consumption in water-supply networks.