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emaanderson · 2 years ago

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Power Distribution Unit (PDU) Market Analysis, Size, Share, Growth, Trends and Forecast Till 2028

Research Nester published a report titled “Power Distribution Unit Market: Global Demand Analysis & Opportunity Outlook 2028” which delivers detailed overview of the power distribution unit market in terms of market segmentation by type, power phase, power rating, distribution channel, application, end user and by region.

Further, for the in-depth analysis, the report encompasses the industry growth indicators, restraints, supply and demand risk, along with detailed discussion on current and future market trends that are associated with the growth of the market.

Driven by the advancements in technologies like artificial intelligence, machine learning, internet of things and virtual healthcare, massive amount of data is generated on a daily basis worldwide. As a result, there is a rising demand for data centers, which is further anticipated to raise the adoption of power distribution units. Data centers are deployed in large spaces and for its functioning, these equipment are required to be provided with proper electrical supply.

Owing to the presence of numerous data centers around the world, there is also a growing focus of the nations to provide dedicated electrical connection support. These data centers are also known to consume around 1% of the global electricity demand, according to the statistics provided by the International Energy Agency (IEA). Such factors are anticipated to promote towards the growth of the global power distribution unit market.

“The Final Report will cover the impact analysis of COVID-19 on this industry.”

Download/Request Sample Copy of Strategic Report: https://www.researchnester.com/sample-request-714

The global power distribution unit market is further estimated to record a significant CAGR over the forecast period, i.e., 2021-2028. The demand for power distribution unit during the COVID-19 pandemic increased significantly owing to the sudden boom in the demand for data centers. Although, due to the severe restrictions in trade of goods, the market observed a temporary halt, thereby affecting the sales of the product. Yet it is anticipated that in the coming years, there would be a sharp demand for PDUs, backed by the growing advancement in ICT technologies around the world.

The power distribution unit market is segmented by end user into telecommunication & IT, BFSI, transportation, healthcare, defense and others, out of these, the telecommunication & IT segment is estimated to account for the largest market share over the forecast period. This growth can be attributed to the ongoing technological developments such as cloud computing, artificial intelligence, and internet of things (IoT) in telecommunication and IT industry. Moreover, the increasing number of data centers worldwide is anticipated to increase the demand for power distribution units over the coming years.

Regionally, the global power distribution unit market is segmented into five major regions including North America, Europe, Asia Pacific, Latin America and Middle East & Africa region. The market in North America is estimated to account for the largest market share over the forecast period. This growth can be attributed to the advancements in IT sector, growing demand for data centers, and increasing research & development activities in the North America region.

Increasing Need Among Data Center Operators for Efficient Power Monitoring Solutions to Drive the Market Growth

Backed by the increasing number of internet users worldwide, the demand for data centers has increased significantly. Also, with the growing dependency on these data centers, there is a rising need for reliable power distribution technology for its efficient operation. The conventional rack power distribution units are more inclined towards increasing the power density, which can trigger an overload event, therefore resulting in the halt of operations or even lead to a technical fault. Utilization of PDUs minimizes the risk of such critical faults and therefore allows maximum data center uptime. Moreover, power distribution units allow the data centers to monitor power usage and provides reliability in case of a critical power load. Such factors are estimated to propel the growth of power distribution unit market over the forecast period.

However, the rising concern for the increasing complexity of servers in a data center, which makes it difficult to locate and change the cables during the maintenance of power distribution units is anticipated to hamper the growth of the global power distribution unit market.

This report also provides the existing competitive scenario of some of the key players of the global power distribution unit market which includes company profiling of Leviton Manufacturing Co., Inc., Eaton (NYSE: ETN), ABB (NYSE: ABB), DPS Telecom, Cyber Power Systems, Inc. (TPE: 3617), Legrand SA (EPA: LR), Enlogic (CIS Global), Schneider Electric (EPA: SU), Hewlett Packard Enterprise Development LP (NYSE: HPE), and Delta Power Solutions.

The profiling enfolds key information of the companies which encompasses business overview, products and services, key financials and recent news and developments. On the whole, the report depicts detailed overview of the global power distribution unit market that will help industry consultants, equipment manufacturers, existing players searching for expansion opportunities, new players searching possibilities and other stakeholders to align their market centric strategies according to the ongoing and expected trends in the future.

#Power Distribution Unit (PDU) Market

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aimarketresearch · 2 days ago

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mrfrmarket · 19 days ago

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dorleco · 2 months ago

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(E/E) EV System Integration

September 3, 2024

by dorleco

with no comment

eMOBILITY CONTROLS

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Introduction

The fast adoption of electric cars (EVs) is causing a seismic shift in the global automotive surroundings. Electrification is being embraced by governments and industry globally as a means of reducing transportation’s negative environmental effects and decreasing dependency on fossil fuels. EV System Integration is one of the most important and challenging aspects of this shift as EVs become more common. The performance, credibility, and efficiency of an electric car depend on the seamless integration of its numerous parts, which range from software and charging infrastructure to battery systems and power electronics.

This blog explores the future of this developing field as well as the significance of EV System Integration for electric vehicles and the essential elements that go into it.

EV System Integration is divided into three main Components:

1. High Voltage Components

2. Low Voltage Components

3. Multiple CAN Networks

High Voltage Components

High-voltage components are found in both hybrid and all-electric vehicles. High-voltage components are directly connected to the power battery in pure electric vehicles.

Battery packs or fuel cells, battery management systems (BMS), electric motors, motor control units (MCU), power distribution units (PDU), electric air conditioning compressors, DC/DC converters, on-board chargers (OBC), EV chargers, charging outlets, PTC heaters, and high-voltage wiring harnesses are some of the most common examples of high-voltage component.

Battery Management System (BMS): Also known as the battery controller, the BMS is the essential component of battery management and protection. Its duties include monitoring the charging and draining of battery packs, assuring the safe and dependable usage of EV batteries, and providing the vehicle control unit (VCU) with basic parameter and fault diagnosis data.

Currently, the normal working voltage of electric car battery systems is between 200 and 600 volts. Additionally, its output current is 500A. EV driving range is directly impacted by battery capacity, which also influences charging time and efficiency.

Lithium-ion batteries currently rule the global market. Since lithium-ion battery technology is limited at this time, most electric automobiles employ them. Meanwhile, high-voltage electric vehicle systems use shielding design to lessen electromagnetic radiation produced by high-voltage components.

A motor controller is a device that controls the flow of energy from the battery to the drive motor. Vehicle advance (motor revolving in a forward direction), vehicle reverse (motor rotating in the opposite direction), DC/AC conversion, and other operations are among its primary duties. It achieves effective control to operate the motor by converting high voltage direct current to alternating current and interacting with other modules of the electric car through signals.

3. Power Distribution Unit (PDU): A PDU distributes high-voltage electricity throughout the vehicle in a manner akin to that of an electrical fuse box in a low-voltage circuit system.

High-voltage electrical equipment, including motor controllers, drive motors, electric air conditioner compressors, PTC heaters, and DC-DC converters, are powered by high-voltage battery distribution. A high-voltage charging current is distributed to the battery pack simultaneously from the AC or DC charging connector to charge it.

Certain DC/DCs convert high voltage to high voltage to support three things: 1) fast charging, 2) connection to standard charging stations, 3) BMS dependability.

Modern e-compressor technology is developing at a rapid pace, leading to the development of innovative, highly efficient heat pumps that are used to warm car interiors.

Low Voltage Components:

Low-voltage parts of an electric vehicle (EV) run independently of the high-voltage battery system that powers the electric motor, often on a 12V or 48V electrical system. These low-voltage parts are necessary for the car’s different support systems. The primary low-voltage parts of an EV are as follows:

1. 12V Battery

provides power to low-voltage electronics, such as lighting, control, and entertainment systems. Function: Supplies power to these components even when the high-voltage system is off by acting as a buffer.

2. Lighting System

Headlights, tail lights, and interior lights operate on a 12V electrical system and provide interior comfort and driving illumination.

3. Information Display System

Contains GPS, radios, touchscreens, and other multimedia interfaces for its intended use. Function: It manages user interactions and media entertainment and is powered by low-voltage technology.

4. Controls for HVAC Systems

HVAC (heating, ventilation, and air conditioning) controls and displays perform this role.

Function: Controls the temperature within the cabin using low-voltage electronics, even if the high-voltage system may still be used to power the compressor.

5. Braking and Power Steering Assistance

Its function is to supply power assistance for braking and steering. Function: To ensure ease of handling, low-voltage electric motors are used to increase the driver’s input effort.

6. Cooling Fans and Pumps

Its purpose is to control the cooling of a few low-power parts, such as auxiliary systems and some electronics. Function: Low voltage power source keeps systems within operating temperature ranges.

7. Power Windows, Wiper Motors, and Additional Comfort Systems

Manage vital car components including the wipers, seats, and windows. Function: Low voltage power supply ensures safe and convenient operation.

8. Instrument Cluster and Dashboard Displays

Function: Offers car data such as range, battery level, speed, and navigation. Function: Provides the driver with real-time data by running on low-voltage electricity.

9. Vehicle Control Unit (VCU):

The Vehicle Control Unit, also known as the “brain” of an electric vehicle (EV), functions as the main controller. It is essential to make sure that the electric powertrain, battery management system (BMS), and power electronics, among other various EV subsystems, all function as a unit. The vehicle’s central processing unit (VCU) gathers, processes, and transmits commands to different actuators to control operations including energy regeneration, braking, acceleration, and battery management.

Multiple CAN Networks

Multiple Controller Area Network (CAN) buses are frequently utilized in contemporary electric cars (EVs) to handle the intricate communication requirements between different Vehicle control units (VCUs) and other components. For dependable, real-time communication between the many systems in the car, CAN networks are essential. CAN networks are designed to handle specific duties for each other, which enables fault isolation and more efficient data delivery. The many CAN networks that are frequently seen in EVs are summarized as follows:

1. Powertrain CAN

Establishes communication between the electric powertrain’s parts. Key Components: Battery Management System (BMS): Keeps an eye on and regulates battery safety, charging, and performance. Motor controllers and inverters: Manage the power supply and regenerative braking of the electric motor. The Vehicle Control Unit (VCU) is in charge of managing the complete powertrain system and guaranteeing peak performance. Provides real-time data interchange for motor control, energy management, torque requirements, and battery status.

2. CAN Chassis

oversees communications regarding vehicle dynamics and safety systems? Key Components: The Anti-lock Braking System (ABS) regulates brakes and keeps track of wheel speed to keep wheels from locking up. Electronic Stability Control (ESC) keeps the car stable by controlling brake force distribution and engine power. The power steering system regulates and provides feedback for electric power steering. Function: By coordinating sensors and actuators connected to the suspension, steering, and braking systems, it preserves the stability and safety of the vehicle.

3. Battery CAN Network

The Battery CAN Network’s mission is to oversee and control batteries. Key Components: Temperature, voltage, and current battery sensors are part of the battery management system (BMS). Functions: The battery pack’s optimal operation is the responsibility of this CAN network. It controls the flow of data about diagnostics, thermal regulation, charging status, battery health, and cell balancing. To avoid overcharging, overheating, or any other problems that can compromise performance or safety, the network continuously checks on the battery.

4. HVAC CAN Network

Controls the temperature in the cabin and operates the HVAC system. Key Components: HVAC Control Unit Temperature sensors for electric compressors and heat pumps Functions: The interior climate control of the car is effectively ensured by this network. It controls how the seat heaters, defrosters, and cabin heating and cooling systems interact. This data is separated on a separate CAN network to avoid interfering with important driving systems.

5. Charging CAN Network

Function: Managing correspondence between the car’s internal charging infrastructure and external charging outlets. Key Components: Port Control Unit for Charging On-Board Charger (OBC) External Charging Station Interface The management of communication between the vehicle and the charging infrastructure is the sole purpose of this network. To provide safe and effective charging, it controls voltage and current, monitors charging status, and organizes the flow of electricity during charging. For instance, it makes sure the battery gets the right amount of power during fast charging so it doesn’t overheat or sustain damage.

Conclusion

An essential component of the shift to electric mobility is the integration of electric vehicle systems. It goes beyond simply putting different parts together; it also involves making sure they function effectively, safely, and sustainably as a whole. The EV System Integration issues will persist in their evolution along with the growth in EV adoption, and the corresponding technologies and processes will also change. The future of EV system integration promises to uncover even greater possibilities for electric vehicles, influencing the development of energy and transportation systems, thanks to advancements in batteries, power electronics, and software.

It is impossible to overestimate the significance of smooth EV system integration as the globe continues to move toward cleaner and more sustainable modes of transportation. It is the foundation of the electric car revolution, making sure that the promise of more intelligent, efficient, and environmentally friendly mobility is realized.

“Empowering your EV solutions with high-performance VCUs, cutting-edge CAN keypads, versatile CAN displays, and innovative EV software services — driving efficiency, connectivity, and reliability into every journey.” Connect with us @ [email protected]

#E/ESystems #Autonomousvehicle #EVSystemintegration #EVSoftwareservices #VCUProducts #Electricvehicle

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marketnewskk · 3 months ago

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pranalip · 3 months ago

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rameshjadhav · 5 months ago

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dbmrnewsreserach · 9 months ago

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ajitsuranase · 9 months ago

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rohitpalan · 10 months ago

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On-board Magnetic Sensors Market: Overview and Growth Analysis, 2023-2033

In the ever-evolving landscape of technology, the global on-board magnetic sensors market is poised for substantial growth, with a projected value of US$1.2 billion in 2023, according to recent data from Future Market Insights (FMI). FMI’s extensive analysis and forecasts indicate that the on-board magnetic sensors market is set to exhibit a robust CAGR of 7.0%, potentially surging past US$2.4 billion by 2033.

Increased automotive industry activity and technological advancements are also fueling demand for Internet of Things (IoT) developments, which support market expansion. Magnetic sensors are becoming increasingly popular in the navigation industry given their proximity switching, position detection, and other features.

Request a Sample of this Report : https://www.futuremarketinsights.com/reports/sample/rep-gb-17142

The market is now gaining from the rise in autonomous vehicle sales. To recognize obstacles and navigate safely, these automobiles require several on-board magnetic sensors. The market is expected to upsurge given the rising demand for EVs and hybrid cars. For location detection, these vehicles necessitate magnetic sensors.

There is a growing need for these sensors in navigation systems. There have also been developments in the ecosystem of onboard magnetic sensors. In the aerospace and military industries, magnetic sensors are being utilized with increasing frequency. These sensors offer input to control systems by detecting the position and orientation of objects. These are contributing to the market growth.

The demand for on-board magnetic sensors in the power distribution unit (PDU) has surged given the development of the service sector. The quick expansion of data centers and cloud providers has also contributed to this increased demand.

Governmental regulations requiring the installation of safety equipment and detecting components in cars are expected to create sizable opportunities for the market to expand. Different parts of EVs contain magnetic sensors. Electric car demand is expected to increase, providing industry participants with enormous revenue possibilities.

Key Takeaways

The on-board magnetic sensors market in the United States is expected to upsurge at 5.9% CAGR during the forecast period.

The market in the United Kingdom is anticipated to rise profitably, exhibiting a CAGR of 6.2% through 2033.

The market in China is expected to proliferate significantly, registering a CAGR of 7.9% from 2023 to 2033.

With a CAGR of 6.5% over the forecast period, the market in Japan is predicted to develop rapidly.

The market in South Korea is predicted to expand significantly between 2023 and 2033, reaching a CAGR of 7.4%.

Competitive Landscape

High-performance magnetic sensors are being developed and produced by market participants in the on-board magnetic sensors market. These sensors are made to fit into a variety of applications. They are also spending on research and development to improve the features of these sensors. Additionally, they are aiming to broaden their global footprint. They accomplish this through strategic alliances, collaborations, and acquisitions.

Recent Developments

Infineon Technologies AG added a unique AMR-based angle sensor to its sensor lineup in June 2019. This sensor was created to offer outstanding accuracy. The sensor is also designed to operate in weak magnetic fields.

Murata Manufacturing Co. Ltd. introduced the MRMS AMR sensor in May 2020. The sensor can detect a horizontal magnetic field. It supports several sensing positions with a single magnet. These AMR sensors use magnetic resistance change rates to detect magnetic fields.

Request for Methodology: https://www.futuremarketinsights.com/request-report-methodology/rep-gb-17142

On-board Magnetic Sensors Market Segmentation

By Type:

Squid Sensors

Magnetoresistive Sensors

Hall Effect Sensors

Others

By Magnetic Density:

>10 Gauss (Bias Magnetic Field Sensors)

1 Microgauss to 10 Gauss (Earth Field Sensors)

<1 Microgauss (Low-Field Sensors)

By Vertical:

Automotive

Consumer Electronics

Healthcare

Others

By Region:

North America

Latin America

Europe

Asia Pacific

Middle East and Africa(MEA)

#On-board Magnetic Sensors Market

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trinitytouch · 11 months ago

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What are the EV Charging Components?

As the automotive industry accelerates towards a sustainable future, Electric Vehicles (EVs) are at the forefront of this green revolution. One crucial aspect of this transition is the development of efficient and convenient EV charging solutions. In this blog post, we’ll delve into some key components that play a pivotal role in shaping the EV charging landscape.

Type 2 AC Charging Connector:

The Type 2 AC Charging Connector has emerged as a standard for AC charging in many regions. Known for its versatility and compatibility with various power levels, the Type 2 connector facilitates both slow and fast charging. This widely adopted connector is playing a vital role in making home and public charging stations accessible and user-friendly.

CCS DC Charging Connector:

Combining the benefits of both AC and DC charging, the Combined Charging System (CCS) DC Charging Connector is gaining popularity globally. Its ability to support high power levels allows for rapid charging, reducing the time it takes to replenish an EV’s battery. As more automakers embrace CCS, it contributes to a more standardized and interoperable charging infrastructure.

LEV DC Charging Connector:

The Low Voltage Direct Current (LEV DC) Charging Connector is designed for applications that require a lower voltage, making it suitable for certain electric two-wheelers and light electric vehicles. Its efficiency and compact design make it a practical solution for smaller EVs, contributing to the diversification of the electric vehicle market.

EV Charging Connector Holster:

Ensuring the safety and protection of charging connectors is crucial in both residential and public charging settings. The EV Charging Connector Holster is an innovative solution that provides a secure and organized space for connectors when not in use. This not only enhances safety but also prolongs the lifespan of the connectors, ensuring a reliable charging experience for EV owners.

Electric Vehicle Inlet:

The Electric Vehicle Inlet serves as the interface between the EV and the charging connector. It is a crucial component that allows for the transfer of power from the charging station to the vehicle’s battery. The design and compatibility of the inlet are significant factors in ensuring seamless and efficient charging, promoting a standardized approach across different EV models.

Power Distribution Unit:

The Power Distribution Unit (PDU) is the backbone of any charging infrastructure. It manages the distribution of power to multiple charging stations, optimizing the utilization of available electrical capacity. A well-designed PDU not only enhances the efficiency of charging stations but also supports scalability as the demand for EVs continues to grow.

As Electric Vehicles become an integral part of our transportation landscape, the development of advanced EV charging solutions plays a crucial role in accelerating the adoption of sustainable mobility. From versatile connectors to innovative holsters and power distribution units, these components are shaping the future of EV charging, making it more accessible, efficient, and user-friendly for consumers around the world.

#EV #India #ElectricVehicle #ElectricVehicles #ElectricCar #EVCharger #EVChargingSolution #EVChargingCable #ElectricVehicleCharger

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