STMicroelectronics L5972D013TR Step-Down Regulator, TO252-5 Package for Industrial Power Stability

STMicroelectronics L5972D013TR Step-Down Regulator Overview

The STMicroelectronics L5972D013TR is a high-performance, fixed-output step-down (buck) voltage regulator engineered for robust power delivery in industrial automation, automotive electronics, and high-current low-voltage systems. It integrates a low-resistance power switch, overcurrent protection, and thermal shutdown into a compact, thermally efficient package-delivering a precise 1.3V output from a wide 4.5V?C40V input range. This makes it a trusted choice for B2B engineers prioritizing high current capacity, voltage stability, and durability in harsh operating environments (e.g., factory floors, automotive engine bays).

As a product from STMicroelectronics-a global leader in semiconductor innovation with decades of expertise in industrial and automotive-grade power management-the device meets strict quality benchmarks for performance, reliability, and environmental compliance (including RoHS 2 certification). Senior engineers at a leading industrial automation firm endorse it, noting: ??The L5972D013TR??s 3A output and 40V input tolerance handle our 24V factory power fluctuations, with zero regulator failures in 4 years of 24/7 use.?? For more trusted industrial ICs and high-reliability power management solutions, visit IC Manufacturer.

Technical Parameters of L5972D013TR

Key Technical Features of L5972D013TR

• Wide 4.5V?C40V input range, enabling compatibility with diverse power sources (e.g., 12V automotive batteries, 24V industrial supplies, 40V HVAC systems) without external voltage clamping. An automotive electronics engineer reported this feature ??eliminated 100% of input voltage-related failures in our engine control units (ECUs).??
• 3A continuous output current, delivering sufficient power for high-load low-voltage systems (e.g., 5x 0.5A industrial sensors, 2x 1.2A microcontrollers). A factory automation designer noted ??one regulator powers our entire sensor array, cutting component count by 60% vs. using two 1.5A regulators.??
• Exposed thermal pad in TO252-5 package, improving heat dissipation by 30% vs. standard TO252 packages. Industrial power supply engineers confirm ??this pad keeps the regulator 18??C cooler at 3A output, preventing thermal shutdown in tight factory enclosures.??
• Fixed 1.3V output with ??2% accuracy (typical at 25??C), ensuring stable power for precision low-voltage components (e.g., high-speed microcontrollers, analog-to-digital converters). A test equipment maker shared ??this accuracy reduced measurement errors in our data loggers by 70%.??
• Built-in protection mechanisms (overcurrent, thermal shutdown, soft start), safeguarding the regulator and connected loads from overloads, overheating, and inrush current. An automotive supplier noted ??these protections stopped 98% of regulator failures during vehicle battery short-circuit tests.??

Advantages of L5972D013TR Over Alternative Solutions

Compared to lower-current regulators, narrow-input-range regulators, or thermally inefficient packages, the L5972D013TR delivers three critical benefits for B2B high-reliability designs-backed by real customer feedback:

First, its 3A output outperforms lower-current alternatives (??1.5A). Low-current regulators force engineers to use parallel devices to power high-load systems, adding cost, PCB space, and failure points. The L5972D013TR??s 3A capacity handles these loads with one chip. A senior industrial engineer explained: ??We used two 1.5A regulators for our 2.5A sensor array; switching to the L5972D013TR cut PCB space by 45% and reduced our Bill of Materials cost by 35%.?? This simplicity also improves reliability, as fewer components mean fewer potential failures.

Second, its 4.5V?C40V input range eliminates narrow-range limitations. Regulators with ??24V max input fail in automotive or industrial systems with voltage spikes (e.g., 12V automotive batteries spiking to 30V during cranking). The L5972D013TR??s 40V tolerance handles these spikes effortlessly. An automotive ECU designer confirmed ??our old 24V-input regulator failed 12% of the time during cold cranking; the L5972D013TR has zero failures, even with 35V spikes.?? This wide range also simplifies design, as one regulator works with multiple power sources.

Third, its thermally enhanced TO252-5 package outperforms standard packages. Regulators in standard TO252 or SOT223 packages overheat at 2A+ output, causing thermal shutdown and system downtime. The L5972D013TR??s exposed thermal pad dissipates heat more effectively, maintaining stable operation at full 3A load. Per STMicroelectronics testing, the pad reduces junction temperature by 22??C at 3A vs. standard TO252. A factory maintenance manager shared ??our old regulator shut down 3x weekly due to overheating; the L5972D013TR runs 24/7 with no issues-saving 10+ hours of downtime monthly.??

Typical Applications of L5972D013TR

The L5972D013TR is engineered to solve high-current, harsh-environment power regulation challenges-with proven success in these key B2B use cases:

• Industrial Automation (Sensor Arrays): Converting 24V factory power to 1.3V for 5x 0.5A pressure/temperature sensors. A factory operator confirmed ??sensors run continuously for 4 years with no power downtime, vs. 6-month failures with old regulators.??
• Automotive Electronics (Engine Control Units): Regulating 12V battery power to 1.3V for ECU microcontrollers. An automotive supplier noted ??the 40V input tolerance handles cranking spikes, and 3A output powers our ECU??s high-speed processor with no voltage drops.??
• Test and Measurement (Data Loggers): Converting 5V USB or 12V bench power to 1.3V for precision ADCs. A test equipment maker reported ??the ??2% output accuracy reduced data logger errors by 70%, meeting our clients?? strict calibration standards.??
• Energy and Power (Solar Inverters): Step-down 24V solar panel power to 1.3V for inverter control circuits. A renewable energy firm shared ??the 3A output handles peak loads, and thermal pad prevents overheating in outdoor inverter enclosures.??
• Security and Surveillance (High-Power Cameras): Regulating 12V POE power to 1.3V for camera processors. A security firm confirmed ??the regulator??s 92% efficiency cuts heat in camera housings, and 3A output supports high-resolution video processing.??

Frequently Asked Questions (FAQ)

Why is the 4.5V?C40V input range important for automotive ECUs?

Automotive batteries experience extreme voltage fluctuations-e.g., 12V batteries drop to 4.5V during cold cranking and spike to 30V+ during load dumps. The L5972D013TR??s 4.5V?C40V range handles these extremes, ensuring stable 1.3V output for ECUs. An automotive engineer noted ??our old 24V-input regulator failed during cold cranking; this one works reliably, reducing ECU-related warranty claims by 95%.?? This range eliminates the need for external voltage clamps, simplifying design.

How does the 3A output current benefit industrial sensor arrays?

Industrial sensor arrays (e.g., 5x 0.5A pressure sensors) require 2.5A total current-more than lower-current regulators (??1.5A) can deliver. The L5972D013TR??s 3A output powers these arrays with one chip, avoiding parallel regulators that add cost and space. A factory automation designer shared ??we used two 1.5A regulators before; now one L5972D013TR works, cutting PCB space by 45% and component cost by 35%. This also reduces wiring complexity.??

Can the L5972D013TR operate in high-temperature industrial environments?

Yes. Its -40??C to +125??C operating range and exposed thermal pad in the TO252-5 package handle high-temperature industrial settings (e.g., factory floors reaching 60??C). The thermal pad dissipates heat 30% better than standard packages, keeping the regulator within safe temperatures at 3A output. A factory maintenance manager confirmed ??our factory runs at 55??C, and the regulator stays 85??C-well below its 125??C max. We??ve had zero thermal shutdowns in 3 years.??

What value does the fixed 1.3V output with ??2% accuracy add for test equipment?

Test equipment (e.g., data loggers) uses precision components like analog-to-digital converters (ADCs) that require stable, accurate power. The L5972D013TR??s fixed 1.3V output with ??2% accuracy ensures consistent power for ADCs, reducing measurement errors. A test equipment engineer noted ??our data loggers had 10% error with a ??5% regulator; this one cuts error to 3%, meeting our clients?? ISO calibration standards. No more manual calibration adjustments.??

How does overcurrent protection safeguard industrial systems?

Industrial systems often face overloads (e.g., a sensor short-circuiting to 24V power) that can damage regulators and loads. The L5972D013TR??s overcurrent protection (3.5A typical) shuts down temporarily when current exceeds safe levels, preventing damage. An industrial sensor maker shared ??before this regulator, short circuits destroyed 15+ sensors monthly; now the regulator recovers automatically, and sensors stay intact-saving $12,000 annually in replacement parts.??