Transmitter SINEAX G536

▶Product Introduction

SINEAX G536 transmitter is used to obtain the phase angle or power factor between current and voltage in single-phase systems or symmetrically loaded three-phase systems.

▶Product Features

▪Monitor reactive power demand in energy distribution systems and process engineering
▪Determine the characteristic values of reactive power compensation
▪Germanischer Lloyd standards, applicable to ships
▪The output signal can be used for indication, registration, monitoring, and control
▪Ensure safety through current isolation and shockproof terminals (IP20)

▶technical data

▪Measurement input: single-phase AC current system or 3/4 line three-phase system under the same load
▪Nominal voltage 100V, 230V, 400V or user-defined 10... 690V
▪Nominal current 1A, 5A or user-defined 0.5... 6A
▪Nominal frequency 50/60Hz or 10... 400Hz
▪Measurement range: Phase angle -60 °... 0 °...+60 ° el or -180 °... 0 °...+180 ° el or
▪Power factor 0.5... cap 0... ind... 0.5 or -1... ind... 0... cap... 1... ind... 0... cap... -1
▪Measurement range ≥ 20 ° el, clearly indicating only reaching
▪Measurement output: maximum output value 0... 20mA, 4... 20mA, 0... 10V or
▪User defined within the range of 1... 20mA or 1... 10V
▪Output signal unipolar, symmetrical bipolar or zero crossing
▪Set time with optional input frequency of 2, 4, 8 or 16 cycles
▪Accuracy: Level 0.5 within 15... 30 ℃
▪Power supply: 24-60V AC/DC or 85-230V AC/DC (can also be measured from internal input)
▪24V AC/24-60V DC, connected through the low voltage side
▪Dimensions: 69.1 x 70 x 112.5 mm,
▪Top mounted guide rail installation (35x15mm or 35x7.5mm)

▶application

SINEAX G536 transmitter is used to obtain losses caused by nonlinear loads or reactive impedance. During a day, this type of loss can cause strong fluctuations that hinder static reactive power compensation, as overcompensation is prohibited. The inverter and transformer are connected or directly connected. Should change
The transmitter, also used for phase angle or power factor, can output a DC signal proportional to the measured phase angle or power factor by applying distortion input variables that are dominated by the fundamental wave.