Current Sensors

Part Number	Description / PDF	Quantity
DS300ID Danisense	CURRENT TRANSDUCER 300A	0
DS400ID Danisense	CURRENT TRANSDUCER 400A	10
DL2000UB-10V Danisense	CURRENT TRANSDUCER 2000A	0
DS200UB-10V Danisense	CURRENT TRANSDUCER 200A	0
DS50ID Danisense	CURRENT TRANSDUCER 50A	16
DS400UB-10V Danisense	CURRENT TRANSDUCER 400A	0
DS300UB-10V Danisense	CURRENT TRANSDUCER 300A	0
DS600ID Danisense	CURRENT TRANSDUCER 600A	7
DS1000UB-10V Danisense	CURRENT TRANSDUCER 1000A	0
DS600UB-10V Danisense	CURRENT TRANSDUCER 600A	0
DM1200UB-10V Danisense	CURRENT TRANSDUCER 1200A	0
DS50UB-10V Danisense	CURRENT TRANSDUCER 50A	0
DC200IF Danisense	CURRENT TRANSDUCER 200A	16
DM1200ID Danisense	CURRENT TRANSDUCER 1200A	1
DL2000ID Danisense	CURRENT TRANSDUCER 2000A	3
DQ600ID Danisense	CURRENT TRANSDUCER 600A	3
DS200ID Danisense	CURRENT TRANSDUCER 200A	6
RCMH070IB+ Danisense	TYPE B RESIDUAL CURRENT MONITOR	2
DP50IP Danisense	50A PROGRAMMABLE CURRENT TRANSDU	3

Current Sensors

1. Overview

Current sensors are transducers that measure electric current flow in conductors and convert it into proportional electrical signals. They play critical roles in energy management, motor control, power quality monitoring, and system protection across industries. Modern applications demand high accuracy, galvanic isolation, and fast response times for optimizing efficiency in electrified systems.

2. Major Types & Functional Classification

Type	Functional Characteristics	Application Examples
Shunt Resistor	Low cost, inline measurement, direct current conversion via Ohm's law	Power supplies, battery management systems
Hall Effect	Galvanic isolation, DC/AC measurement, moderate bandwidth	Automotive traction inverters, industrial motor drives
Current Transformer	High-voltage isolation, AC-only operation, high accuracy	Grid metering, circuit breaker protection
Rogowski Coil	Flexible coreless design, fast transient response, requires integrator	Pulsed power systems, fault current detection
Optical Current Sensor	Immune to EMI, high precision, complex signal processing	Smart grids, high-voltage substations

3. Structure & Components

Typical current sensors contain: 1) Sensing element (shunt resistor, Hall chip, magnetic core) 2) Signal conditioning circuitry (amplifiers, filters) 3) Isolation barrier (if applicable) 4) Output interface (analog voltage/current, digital protocols). High-performance models integrate temperature compensation and digital calibration features.

4. Key Technical Specifications

Parameter	Description	Importance
Measurement Range	Maximum current capacity (e.g., 500A)	Determines application suitability
Accuracy Class	Error tolerance (e.g., 0.5%)	System control reliability
Bandwidth	Frequency response (DC-100kHz)	Dynamic performance capability
Isolation Voltage	Dielectric withstand rating (e.g., 3kV)	Electrical safety compliance
Response Time	Signal output delay ( s-ms range)	Protection system effectiveness

5. Application Fields

Key industries include: Renewable energy (solar inverters, wind turbines), Automotive (EV battery management, 48V systems), Industrial automation (CNC machines, robotics), Consumer electronics (smart meters), Aerospace (actuator monitoring). Typical equipment: Variable frequency drives, uninterruptible power supplies, charging stations.

6. Leading Manufacturers & Products

Manufacturer	Product Series	Key Features
LEM SA	HASS & LTSR Series	Open-loop Hall effect with ASIC processing
Allegro Micro	ACS758/ACS3761x	Galvanically isolated Hall ICs
Honeywell	CSP-VA/CSNP Series	Current transformers for grid applications
TT Electronics	Pulse Series	High-precision shunt resistors
ACR Systems	Rogowski Coil Models	Flexible aperture AC measurement

7. Selection Recommendations

Key considerations: 1) Required measurement range vs peak currents 2) DC/AC signal type compatibility 3) Isolation requirements 4) Environmental conditions (temperature, vibration) 5) Cost vs performance trade-offs. Example: For EV battery management, select Hall-effect sensors with 200A range, 1% accuracy, and automotive qualification.

8. Industry Trends

Emerging trends include: 1) Integration with IoT for predictive maintenance 2) Wide bandgap semiconductor-based sensors 3) Increased adoption of closed-loop Hall sensors for EV applications 4) MEMS-based miniaturized current monitoring 5) AI-enhanced signal processing for harmonic analysis. The market is projected to grow at 7.2% CAGR through 2030 driven by electrification demands.