Optical Sensors - Photoelectric, Industrial

Part Number	Description / PDF	Quantity
CX-421-Z Panasonic	SENSOR REFLECTIVE 300MM NPN OPEN	8
EX-Z11BR Panasonic	SENSOR THROUGH-BEAM 50MM NPN	0
FT-A11W Panasonic	SENSOR THROUGH-BEAM 3.6M	2
CX-423-P-J Panasonic	SENSOR REFLECTIVE PNP 300MM PNP	1
HG-C1050L3-P-J Panasonic	SENSOR REFLECTIVE 50MM PNP	17
EX-19B-PN-CN03-M8 Panasonic	SENSOR THROUGH-BEAM 1M PNP	0
EX-11B-R Panasonic	SENSOR THROUGH-BEAM 15CM NPN	4
NA1-PK3-C5 Panasonic	SENSOR CROSS-BEAM 100MM NPN OPEN	0
HG-C1100L3-P-J Panasonic	SENSOR REFLECTIVE 100MM PNP	3
FD-L20H Panasonic	SENSOR REFLECTIVE 23MM R2 BEND	22
EX-Z12FB-R Panasonic	SENSOR THROUGH-BEAM 200MM NPN	5
RX-D700 Panasonic	SENSOR REFLECTIVE 700MM NPN OPEN	8
FD-Z40W Panasonic	SENSOR REFLECTV FBR FLAT DIFFUSE	30
CX-412A-P-C05 Panasonic	SENSOR THROUGH-BEAM 15M PNP	4
EX-Z11B Panasonic	SENSOR THROUGH-BEAM 50MM NPN	4
EX-L262 Panasonic	SENSOR REFLCTV 70MM NPN OPEN COL	1
EX-28B Panasonic	SENSOR REFLECTIVE 150MM NPN	4
RX-M50 Panasonic	SENSOR TRANSMISSIVE 50M NPN OPEN	4
CY-122VA-P Panasonic	SENSOR REFLECTIVE 60CM PNP	3
CY-192B-Z-Y Panasonic	SENSOR RETROREFL 4M NPN OPEN COL	13

Optical Sensors - Photoelectric, Industrial

1. Overview

Industrial photoelectric sensors are optoelectronic devices that detect the presence or absence of objects by emitting and receiving light beams. These sensors convert optical signals into electrical signals through photodetection mechanisms, enabling non-contact measurement and control in industrial environments. Their importance lies in enabling automation, improving production efficiency, and ensuring process reliability across various sectors including manufacturing, logistics, and quality control.

2. Main Types and Functional Classification

Type	Functional Characteristics	Application Examples
Through-Beam Sensors	Separate emitter and receiver units for high detection accuracy	Conveyor belt object counting
Reflective Sensors	Single unit with reflector for compact installations	Packaging integrity verification
Diffuse Sensors	Object-reflective detection without separate reflector	Color contrast detection in sorting systems
Fiber Optic Sensors	Flexible light transmission for confined spaces	Semiconductor manufacturing equipment
Slot Sensors	U-shaped design for precise positional detection	Printed circuit board alignment systems

3. Structure and Components

Typical construction includes: 1) Light source (LED/Laser diode) emitting specific wavelengths (660nm-950nm) 2) Photodetector (photodiode/CCD array) for signal reception 3) Signal processing circuitry with amplification and threshold detection 4) Protective housing with optical window (IP65-IP69K ratings) 5) Electrical interface (2-wire/3-wire configurations) Advanced models integrate temperature compensation and digital communication protocols (IO-Link).

4. Key Technical Specifications

Parameter	Significance
Detection Range	Determines maximum operational distance (20mm-50m)
Response Time	Measures detection speed (10 s-2ms)
Accuracy	Defines position detection precision ( 0.02mm)
Environmental Resistance	Specifies operating conditions (-40 C to +70 C, dust/water protection)
Output Type	Identifies electrical interface (NPN/PNP, analog/digital)

5. Application Fields

Key industries include: - Automotive Manufacturing: Robotic welding verification - Logistics: Parcel dimension measurement systems - Food Processing: Fill-level detection in transparent containers - Electronics Assembly: Component presence verification - Medical Devices: Lab automation sample tracking Example: In automotive production lines, photoelectric sensors detect door panel alignment with 0.1mm precision at 2m/s conveyor speeds.

6. Leading Manufacturers and Products

Manufacturer	Country	Representative Product
Siemens	Germany	OBT1-16GM300-S91L
Omron	Japan	E3Z-T61
Keyence	Japan	LKG50A-W15T
Pepperl+Fuchs	Germany	R2000-6
Balluff	USA	BOS 18M

7. Selection Recommendations

Key considerations: 1. Detection requirements: Distance, object size, and speed 2. Environmental factors: Ambient light, temperature, and contamination 3. Installation constraints: Space limitations and mounting options 4. Output requirements: Digital/analog signal compatibility 5. Cost-benefit analysis: Balancing precision with operational budgets Example: Choose fiber optic sensors for high-temperature furnace applications exceeding 100 C.

8. Industry Trend Analysis

Current development trends include: - Miniaturization through MEMS technology (sensor size reduction by 40% since 2015) - Integration of AI algorithms for adaptive threshold adjustment - Wireless communication capabilities (Bluetooth/Wi-Fi 6 adoption) - Increased sensitivity in visible light spectrum (enhanced color detection) - Growth in safety-rated sensors (SIL2/PLc compliance) Market projections indicate 8.2% CAGR through 2027 driven by Industry 4.0 adoption.