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Industrial Power Monitoring Market - Global Industry Size, Share, Trends, Opportunity, and Forecast, Segmented By Component (Hardware, Software, Services), By Application (Utilities & Renewables, Manufacturing & Process Industry, Datacenters, Public Infrastructure, and Others), By Region, By Competition Forecast 2018-2028


Published on: 2024-12-08 | No of Pages : 320 | Industry : Power

Publisher : MIR | Format : PDF&Excel

Industrial Power Monitoring Market - Global Industry Size, Share, Trends, Opportunity, and Forecast, Segmented By Component (Hardware, Software, Services), By Application (Utilities & Renewables, Manufacturing & Process Industry, Datacenters, Public Infrastructure, and Others), By Region, By Competition Forecast 2018-2028

Forecast Period2024-2028
Market Size (2022)USD 4.08 billion
CAGR (2023-2028)5.19%
Fastest Growing SegmentHardware
Largest MarketNorth America

MIR Power Generation Transmission and Distribution

Market Overview

Global Industrial Power Monitoring Market has valued at USD 4.08 billion in 2022 and is anticipated to project robust growth in the forecast period with a CAGR of 5.19% through 2028.

In this market, a wide array of specialized hardware and software solutions are offered to enable real-time monitoring, data collection, and analysis of electrical parameters such as voltage, current, power factor, harmonics, and energy consumption. These solutions are employed to enhance energy efficiency, ensure power quality, minimize downtime, and reduce operational costs. Key components include sensors, meters, control systems, data analytics platforms, and communication technologies.

The industrial Power Monitoring market is driven by growing concerns over energy conservation, regulatory compliance, the need for sustainable practices, and the integration of renewable energy sources. Industries worldwide are increasingly adopting these technologies to gain better visibility into their energy usage, improve equipment performance, and achieve environmental and cost-saving objectives, making the market a pivotal enabler of modern industrial operations.

Key Market Drivers

Increasing Energy Efficiency Demands in Industries

In today's industrial landscape, optimizing energy consumption has become paramount. Industries are under constant pressure to reduce operational costs and environmental impacts. As a result, there is a growing demand for power monitoring solutions that can provide real-time insights into energy usage. These solutions enable businesses to identify inefficiencies and implement corrective measures, ultimately leading to significant cost savings and a reduced carbon footprint.

Power monitoring systems offer comprehensive data on energy consumption patterns, helping industries to pinpoint areas where energy is being wasted. By analyzing this data, companies can make informed decisions regarding equipment upgrades, maintenance schedules, and energy-efficient technologies. Moreover, the ability to monitor energy usage remotely allows for proactive energy management, ensuring that equipment operates at peak efficiency levels.

Regulatory Compliance and Sustainability Initiatives

Global efforts to combat climate change have resulted in stricter environmental regulations and sustainability initiatives. Many industries are now required to monitor and report their energy consumption and emissions. Power monitoring systems play a vital role in helping businesses meet these regulatory requirements. These solutions provide accurate and transparent data that can be used for compliance reporting, reducing the risk of fines and penalties.

Furthermore, industries are increasingly adopting sustainability goals to align with consumer expectations and reduce their carbon footprint. Power monitoring systems enable companies to track their progress toward these sustainability objectives by providing real-time data on energy usage and carbon emissions. This data is essential for making informed decisions about energy-efficient practices and renewable energy adoption.


MIR Segment1

Growing Adoption of Industrial IoT (IIoT) Technologies

The Industrial Internet of Things (IIoT) is revolutionizing the industrial sector by connecting various devices and systems to the internet for data collection and analysis. Power monitoring is an integral part of the IIoT ecosystem, as it allows industries to gather critical data on energy consumption and equipment performance. With the increasing deployment of sensors, smart meters, and connected devices, power monitoring systems are becoming more advanced and capable of delivering real-time insights.

These interconnected systems enable predictive maintenance, where anomalies in power consumption can trigger alerts and maintenance requests automatically. This proactive approach minimizes downtime, reduces maintenance costs, and extends the lifespan of industrial equipment. As industries continue to embrace IIoT technologies, the demand for advanced power monitoring solutions is expected to surge.

Rising Concerns About Power Quality and Reliability

Industries rely heavily on a stable and high-quality power supply to ensure uninterrupted production processes. However, power quality issues such as voltage sags, surges, harmonics, and outages can disrupt operations and damage sensitive equipment. In response to these concerns, there is a growing need for power monitoring systems that can identify and mitigate power quality problems.

Power monitoring solutions are equipped with advanced analytics capabilities that can detect anomalies in power supply and alert operators in real time. By proactively addressing power quality issues, industries can avoid costly downtime, equipment damage, and production losses. As a result, businesses are increasingly investing in power monitoring technologies to safeguard their operations and maintain a competitive edge.

Evolving Energy Management Strategies

The way industries manage energy has evolved significantly in recent years. Traditionally, energy management involved simply paying utility bills and conducting periodic energy audits. However, modern energy management strategies are much more dynamic and data-driven. Power monitoring systems provide the essential data needed to implement these strategies effectively.

One of the key trends in energy management is demand response, where industries adjust their energy consumption based on real-time pricing and grid conditions. Power monitoring systems enable industries to participate in demand response programs by providing the necessary visibility into energy usage patterns. This flexibility allows businesses to reduce energy costs during peak demand periods and support grid stability.

Increasing Complexity of Industrial Operations

Industrial operations are becoming increasingly complex due to factors such as globalization, automation, and digital transformation. With a greater number of interconnected machines and systems, industries require a comprehensive understanding of their power usage to optimize processes and ensure operational reliability.

Power monitoring solutions offer the visibility needed to manage these complex operations effectively. They provide insights into how different processes impact energy consumption and help identify opportunities for improvement. Moreover, these systems can integrate with other industrial automation and control systems, creating a holistic view of operations and energy management.

In conclusion, the global industrial Power Monitoring market is being driven by a combination of factors, including the need for energy efficiency, regulatory compliance, IIoT adoption, power quality concerns, evolving energy management strategies, and the increasing complexity of industrial operations. As industries continue to prioritize energy efficiency and sustainability, the demand for advanced power monitoring solutions is expected to remain robust, driving innovation and growth in the market.


MIR Regional

Government Policies are Likely to Propel the Market

Energy Efficiency Standards and Incentives

Energy efficiency has become a top priority for governments worldwide to reduce greenhouse gas emissions and promote sustainable industrial practices. To encourage industries to adopt power monitoring solutions and enhance energy efficiency, governments have implemented various policies and incentives. One common policy is the establishment of energy efficiency standards and regulations that mandate industries to meet specific energy consumption targets. These standards often require the installation of power monitoring systems to track and report energy usage accurately. Non-compliance can result in penalties or loss of eligibility for government incentives.

Governments also offer financial incentives, tax credits, and grants to industries that invest in power monitoring technologies. These incentives can significantly offset the initial costs of implementing power monitoring systems, making them more accessible to a broader range of businesses. As a result, the adoption of power monitoring solutions is stimulated, contributing to energy conservation and sustainability goals.

Renewable Energy Integration and Grid Modernization

Many governments are actively promoting the integration of renewable energy sources into the industrial sector as part of their clean energy transition strategies. However, renewable energy sources like wind and solar can be intermittent, leading to challenges in power quality and reliability. To address these issues, governments are implementing policies related to grid modernization and power monitoring.

Government initiatives often include funding for research and development of advanced power monitoring technologies capable of managing intermittent renewable energy sources efficiently. These systems enable industries to balance their energy demand with the availability of renewable energy, reducing their reliance on fossil fuels and lowering greenhouse gas emissions.

Moreover, governments may provide incentives for industries to invest in energy storage solutions that work in conjunction with power monitoring systems. These policies help ensure a stable power supply, even during periods of renewable energy variability, and promote the broader adoption of renewable energy sources in industrial operations.

Data Privacy and Security Regulations

As power monitoring systems collect vast amounts of sensitive data related to energy consumption, there is a growing concern about data privacy and security. Governments are implementing policies and regulations to address these concerns and protect the data generated by power monitoring technologies.

One critical policy area involves data privacy regulations that dictate how businesses can collect, store, and use energy consumption data. These regulations often require explicit consent from data subjects and strict adherence to data protection standards. Non-compliance can lead to substantial fines and legal consequences.

In addition to data privacy, governments are establishing cybersecurity standards and regulations specific to power monitoring systems. These policies aim to safeguard critical infrastructure from cyberattacks that could disrupt industrial operations and compromise sensitive data. Compliance with these regulations often involves regular cybersecurity assessments and the implementation of robust security measures.

By enforcing data privacy and security policies, governments are fostering trust in power monitoring technologies and encouraging their widespread adoption across industries.

Emissions Reporting and Carbon Pricing

To combat climate change and reduce industrial emissions, many governments have implemented policies related to emissions reporting and carbon pricing. These policies directly influence the adoption of power monitoring systems in industrial settings.

Emissions reporting policies require industries to measure and report their greenhouse gas emissions accurately. Power monitoring systems play a crucial role in this process by providing real-time data on energy consumption and emissions associated with industrial operations. Accurate data collection is essential for industries to comply with emissions reduction targets and avoid penalties.

Furthermore, governments may implement carbon pricing mechanisms, such as carbon taxes or cap-and-trade programs, to create financial incentives for industries to reduce their carbon footprint. Power monitoring systems help businesses track their emissions, assess the impact of emission reduction initiatives, and make informed decisions on carbon mitigation strategies.

By aligning their operations with emissions reporting and carbon pricing policies, industries are more likely to invest in advanced power monitoring solutions to monitor and reduce their environmental impact effectively.

Energy Performance Certification Programs

Energy performance certification programs are government initiatives designed to encourage industries to improve energy efficiency and reduce their environmental impact. These programs often involve rating systems that evaluate the energy performance of industrial facilities and processes.

Power monitoring systems are instrumental in these programs, as they provide the data needed to assess energy efficiency accurately. Industries that achieve higher energy performance ratings may be eligible for various incentives, including tax breaks, grants, or preferential treatment in government procurement processes.

Governments may also require industries to publicly disclose their energy performance ratings, creating transparency and competition among businesses to adopt power monitoring technologies and improve their energy efficiency.

These policies not only drive the adoption of power monitoring systems but also promote healthy competition and innovation in the industrial sector, resulting in reduced energy consumption and lower environmental impact.

Research and Development Funding

Governments recognize the importance of continuous innovation in the field of power monitoring to support their energy efficiency and sustainability goals. To promote research and development (R&D) in this area, they often allocate funding and establish research programs.

These government-funded R&D programs may focus on improving the accuracy and capabilities of power monitoring technologies, making them more accessible and affordable for industries. By collaborating with academic institutions and industry stakeholders, governments can stimulate innovation and drive the development of next-generation power monitoring solutions.

In addition to R&D funding, governments may also offer grants or subsidies to businesses engaged in the development and deployment of innovative power monitoring technologies. These incentives encourage companies to invest in research, create jobs, and bring cutting-edge solutions to the market faster.

In conclusion, government policies significantly influence the global industrial Power Monitoring market by shaping incentives, regulations, and funding opportunities. These policies not only drive the adoption of power monitoring systems but also contribute to energy efficiency, sustainability, and the overall competitiveness of industries. As governments continue to prioritize clean energy and environmental protection, the role of these policies in shaping the future of the Power Monitoring market will remain essential.

Key Market Challenges

Integration Complexity and Legacy Systems

One of the foremost challenges confronting the global industrial Power Monitoring market is the complexity of integrating power monitoring solutions into existing industrial infrastructure, particularly in industries with legacy systems. Industrial facilities are often characterized by diverse and aging equipment, each with varying levels of automation and compatibility with modern power monitoring technologies. This integration complexity presents several obstacles.

First and foremost, legacy systems may lack the necessary communication protocols or interfaces to seamlessly connect with modern power monitoring equipment. This can require costly and time-consuming retrofitting efforts, including the installation of additional sensors and communication hardware. In some cases, it may even necessitate the replacement of older equipment altogether, which can be financially burdensome for businesses.

Furthermore, legacy systems are often not designed with cybersecurity in mind, leaving them vulnerable to cyberattacks when connected to modern monitoring networks. This introduces significant security risks, as power monitoring systems handle sensitive data and play a critical role in ensuring the reliability of industrial operations. Mitigating these security risks requires significant investment in cybersecurity measures, such as firewalls, intrusion detection systems, and regular security audits.

Another integration challenge arises from the diversity of communication standards used in industrial settings. Different manufacturers and suppliers may employ proprietary communication protocols, making it challenging to establish interoperability between various components of a power monitoring system. This can lead to fragmented data collection and hinder the holistic view of energy consumption and equipment performance.

To address these integration complexities, businesses often require the expertise of specialized system integrators or consultants, which can add additional costs to the implementation of power monitoring solutions. Moreover, these integration challenges may deter some industries from adopting power monitoring altogether, delaying the realization of energy efficiency benefits and hindering progress towards sustainability goals.

Data Management and Analytics Complexity

The second major challenge facing the global industrial Power Monitoring market is the complexity of managing and analyzing the vast amounts of data generated by power monitoring systems. While these systems provide valuable insights into energy consumption and equipment performance, the sheer volume and complexity of data can overwhelm businesses and hinder their ability to derive actionable insights effectively.

Power monitoring systems collect a wide range of data points, including real-time power consumption, voltage fluctuations, harmonics, and equipment status. Managing this data requires robust data storage and retrieval systems capable of handling continuous streams of information. Moreover, the data often needs to be archived and accessible for compliance and historical analysis purposes, adding to the storage requirements.

Analyzing power monitoring data is another intricate task. It involves the use of advanced analytics and machine learning techniques to detect anomalies, predict equipment failures, and optimize energy usage. Developing and maintaining these analytics models can be resource-intensive and require specialized expertise in data science and domain knowledge.

Furthermore, the integration of data from power monitoring systems with other industrial data sources, such as production data or weather data, is essential for achieving a holistic view of operations and energy management. However, this integration can be challenging due to differences in data formats, time resolutions, and data quality.

Another layer of complexity arises from the need for real-time analysis and decision-making. In industries where equipment downtime can result in substantial financial losses, such as manufacturing or data centers, the ability to respond quickly to deviations in power quality or equipment performance is critical. This necessitates the development of real-time monitoring and alerting systems, which can be technically demanding and require continuous maintenance.

To address these data management and analytics challenges, businesses need to invest in robust data infrastructure, data governance, and the development of data analytics capabilities. This often entails additional costs in terms of software, hardware, and personnel training. Moreover, the need for skilled data scientists and engineers with domain knowledge in both industrial operations and data analytics is a competitive challenge for many industries.

In conclusion, the global industrial Power Monitoring market faces significant challenges related to the integration of monitoring solutions into complex industrial environments and the management and analysis of the vast amounts of data generated by these systems. Overcoming these challenges requires substantial investments in technology, expertise, and infrastructure, but the potential benefits in terms of energy efficiency, cost savings, and sustainability make it a worthwhile endeavor for industries seeking to thrive in an increasingly competitive and environmentally conscious landscape.

Segmental Insights

Hardware Insights

The Hardware segment had the largest market share in 2022 & expected to maintain it in the forecast period. Hardware components, such as power meters, sensors, and data acquisition equipment, are the foundational elements of any power monitoring system. They are responsible for collecting essential data on energy consumption, voltage levels, current, power quality, and other critical electrical parameters. This data forms the basis for understanding a facility's energy usage and performance. Hardware components are engineered for accuracy and reliability, ensuring the precise measurement of electrical parameters. In industries where even minor deviations can have significant consequences, such as manufacturing or data centers, the reliability of hardware is paramount. Businesses depend on accurate data to make informed decisions about energy efficiency, equipment maintenance, and operational optimization. Hardware components are designed to work seamlessly with a wide range of industrial equipment and systems. They can be integrated into existing infrastructure without major disruptions. This compatibility is essential for industries with legacy equipment and diverse systems, ensuring that power monitoring can be implemented effectively. Hardware components provide real-time data acquisition capabilities, allowing industries to monitor power quality and consumption continuously. This real-time visibility enables immediate response to anomalies, voltage fluctuations, or equipment malfunctions, reducing downtime and minimizing the risk of equipment damage. Hardware components are built to last and withstand the rigors of industrial environments. They have longer lifespans compared to software components, reducing the need for frequent replacements and associated costs. Many industries are subject to regulatory requirements regarding power monitoring and data accuracy.

Manufacturing & Process Industry Insights

The Manufacturing & Process Industry segment had the largest market share in 2022 and is projected to experience rapid growth during the forecast period. Manufacturing and process industries rely heavily on continuous and reliable operations to meet production targets and maintain product quality. Even brief interruptions or fluctuations in power supply can lead to significant downtime and production losses. Power monitoring systems are essential to ensure a stable and high-quality power supply, helping industries avoid costly disruptions and maintain operational efficiency. Manufacturing and process industries are often energy-intensive, with high electricity consumption levels. Effective power monitoring enables these industries to gain insights into their energy usage patterns, identify inefficiencies, and implement measures to optimize energy consumption. Reducing energy costs is a significant driver for these sectors, and power monitoring plays a crucial role in achieving energy efficiency goals. The manufacturing and process industries operate complex machinery and equipment that are sensitive to variations in power quality. Power monitoring systems continuously monitor equipment performance and power quality parameters, such as voltage and harmonics. By detecting anomalies and irregularities, these systems enable predictive maintenance, allowing industries to address potential issues before they lead to costly breakdowns. Many manufacturing and process industries are subject to regulatory requirements related to energy efficiency and emissions reduction. Power monitoring solutions help these industries gather the necessary data to demonstrate compliance with energy and environmental regulations. Accurate data collection and reporting are essential for avoiding fines and penalties. Controlling operational costs is a top priority for manufacturing and process industries to maintain competitiveness. Power monitoring systems provide insights into how different processes impact energy consumption. This information allows businesses to identify areas where energy is being wasted and make data-driven decisions to reduce operational expenses. In recent years, there has been a growing focus on environmental sustainability.

Regional Insights

North America

North America is the largest market for industrial power monitoring, accounting for over 30% of the global market share in 2022. The growth of the market in the region is being driven by the increasing adoption of smart technologies in industrial manufacturing and the rising demand for energy efficiency. The major players in the North American industrial power monitoring market include Schneider Electric, Eaton, Siemens, General Electric, and ABB.

Europe

Europe is the second-largest market for industrial power monitoring, accounting for over 25% of the global market share in 2022. The growth of the market in the region is being driven by the increasing government initiatives to promote energy conservation and sustainability. The major players in the European industrial power monitoring market include Schneider Electric, Siemens, ABB, Honeywell, and Rockwell Automation.

Asia Pacific

Asia Pacific is the fastest-growing market for industrial power monitoring, accounting for over 20% of the global market share in 2022. The growth of the market in the region is being driven by rapid industrialization and urbanization, as well as the growing awareness of the benefits of power monitoring. The major players in the Asia Pacific industrial power monitoring market include Schneider Electric, Siemens, ABB, Honeywell, and Mitsubishi Electric.

Recent Developments

  • In October 2021, Siemens Smart Infrastructure, in collaboration with partners Sagemcom and Bite Lietuva, unveiled their plans to participate in a large-scale project involving the deployment of 1.2 million smart meters throughout Lithuania. As part of this initiative, Siemens Smart Infrastructure will furnish the country's distribution system operator with a comprehensive EnergyIP meter data management system, which will be maintained by the company for a duration of 10 years.
  • In another significant development from August 2021, CyanConnode announced the successful acquisition of a contract with Schneider Electric. This contract pertains to the widespread implementation of smart meters across Northern India. CyanConnode's scope of work includes the supply of 152,000 Omnimesh modules, along with hardware, services, and software compliant with advanced metering infrastructure standards. Additionally, the contract encompasses an annual maintenance agreement to ensure the ongoing efficiency and reliability of the smart metering system.

Key Market Players

  • Schneider Electric SE
  • Eaton Corporation plc
  • Siemens AG
  • General Electric Company
  • ABB Ltd
  • Honeywell International Inc.
  • Rockwell Automation Inc
  • Emerson Electric Co.
  • Yokogawa Electric
  • Mitsubishi Electric Corporation

By Component

By Application

By Region

  • Hardware
  • Software
  • Services
  • Utilities & Renewables
  • Manufacturing & Process Industry
  • Datacenters
  • Public Infrastructure
  • Others
  • North America
  • Europe
  • Asia Pacific
  • South America
  • Middle East & Africa

Table of Content

To get a detailed Table of content/ Table of Figures/ Methodology Please contact our sales person at ( chris@marketinsightsresearch.com )
To get a detailed Table of content/ Table of Figures/ Methodology Please contact our sales person at ( chris@marketinsightsresearch.com )