Article | August 25, 2021
Environmental regulations are tightening, resource extraction sites are nearing the end of their useful lives and must be cleaned up, and the list goes on. Environmental engineers are needed to take advantage of these career opportunities in order to ensure that human impact on the environment is sustainable. But exactly what is environmental engineering?
What is Environmental Engineering?
Environmental engineering entails both the protection of people from the environment and the protection of the environment from people. Environmental engineers, for example, help to protect people's health from the effects of pollution by designing pollution mitigation systems. When an environmental engineer, on the other hand, designs a system that treats waste to ensure that any spills into groundwater are less toxic, they are protecting the environment from the negative effects of humans.
Environmental engineers rely on knowledge from a variety of disciplines, including chemistry, geology, physics, biology, soil science, and others, to complete their work; it is a highly interdisciplinary field.
In which industries can environmental engineers work?
Environmental engineers work in a wide range of industries and for a wide range of companies due to the wide range of tasks they perform. In this section, we will look at some of the most common areas in which they work. Oil, mining, and forestry are all resource industries that have a significant environmental impact. Companies in these industries frequently hire environmental engineers to minimize the impact these industries have on the environment in order to comply with government environmental regulations. For example, in the mining industry, an environmental engineer may be hired to treat mine waste to make it less toxic.
Many environmental engineers go on to work for government agencies, assisting in the verification of companies' compliance with environmental regulations and, in some cases, developing environmental regulations themselves. Public infrastructure projects, such as dams and bridges, are another area where environmental engineers are needed. They are required to ensure that the environmental impact of these projects is kept to a minimum.
Environmental engineers are responsible for safeguarding the environment against human impact as well as safeguarding humans against any serious negative effects caused by the environment. They can work in the resource industry, government, education, research, environmental clean-up companies, and engineering consulting firms. Environmental engineers are more needed than ever as stricter environmental regulations take effect around the world and there is a greater need to clean up anything that has a significant impact on the environment.
Article | August 24, 2021
Recent M&A activity has slowed slightly in 2022, owing primarily to economic and geopolitical uncertainty. In the short term, deal activity is expected to remain stable. This continued investment is expected to be driven by capital availability, private equity (PE) investors, and strategic balance sheet strength.
Despite a drop in deal volume in the last quarter, deal activity remained consistent with pre-pandemic levels. Volumes in the four quarters ending in the first quarter of 2022 exceeded pre-pandemic levels by 18%. Deal values fell in the last two quarters due to fewer megadeals (deals worth at least $1 billion), as companies became warier of complications arising from government approvals.
With the exception of construction machinery, North American activity drove deal volume growth over the last four quarters across all engineering and construction (E & C) subsectors. This region saw a shift toward local, strategic investor transactions, emphasising the impact of global economic headwinds.
Prospects for Engineering Transactions
Despite headwinds from slowing economic activity, rising interest rates, and cost pressure from rising material costs, increased competition for labor, and ongoing supply chain issues, the outlook for E & C sector deal activity remains positive, driven by the continued availability of capital and bolstered by the Infrastructure Investment and Jobs Act.
The recent improvement in the performance of the residential market is expected to continue, owing to historically low interest rates, a housing gap caused by underbuilding over the last decade, the millennial generation entering prime home-buying age, and housing inventory near all-time lows.
The non-residential market is expected to expand, but the outlook varies by sector. Transportation, manufacturing, and education are expected to benefit from infrastructure spending, while construction spending on offices and hotels is expected to decline, owing to continued remote working and business travel trends post-pandemic.
“E&C deal activity is expected to remain stable due to the Infrastructure Investment and Jobs Act, private equity and corporate dry powder, realignment of end market exposure and acquisition of new technologies to support operations, despite the impact of inflation, supply chain disruption, labor shortages, and the war in Ukraine.”
- Danny Bitar, US Engineering and Construction Deals Leader in the United States
ROBOTICS AND AUTOMATION
Article | July 13, 2022
The report "Global Industrial Robot Market: Analysis by Industry, by Type, by Region, Size and Trends with Impact of COVID-19 and Forecast Up to 2026" valued the global industrial robot market at $33.90 billion in 2021 and projected it to $61.09 billion by 2026. Because of increased productivity and efficiency, lower manufacturing costs, and lower overall product purchase prices. Industry 4.0 has accelerated the development of collaborative robots and artificial intelligence (AI)-enabled robots, allowing industries to streamline processes, increase productivity, and reduce errors.
Sectors are investing in robotic systems as the next generation of industrial robots becomes cheaper, autonomous, more mobile, cooperative, and adaptable. During the forecast period of 2022 to 2026, the industrial robot market is expected to grow at a CAGR of 12.50%.
The Dynamics of the global industrial robot market
Automation boosts productivity, raises quality, and decreases errors. Rising automation demand has increased the adoption of robots in various industries, and rising automation demand is a major market driver. The growing electronics industry, rapid installation of industrial robots, high wages, and the growing role of AI in robotics are all expected to drive growth in the industrial robot market.
The purchase and installation of robots requires significant capital investment, and the benefits provided may take many years to outweigh the initial cost. The high initial investment required for industrial robot-assisted production automation may act as a barrier to the market's growth. Other market challenges include safety concerns and privacy concerns.
The development of collaborative robots, or co-bots, is a growing trend in robotics. Cobots are designed to collaborate with humans and are increasingly being used in industrial applications. Cobots use safety-rated sensors, which allow laborers to work in the same area without being harmed.
Other trends that are expected to drive the growth of the engineering industry with the help of robot market during the forecasted period include the use of micro-electromechanical systems (MEMS), the rise of the cloud robotics market, next-generation tech accessories, and job opportunities in industrial robotic advancements.
Article | July 11, 2022
With the emergence of new technologies and a greater emphasis on customer centricity, businesses are rapidly shifting to intelligent software engineering services to drive innovation across products and services and provide real-life, superior user experiences. Future-ready organizations use next-generation software engineering services wisely to align development requirements with business objectives, accelerate the software lifecycle (from pre-maturity to completion), and optimize software performance. Innovative software engineering solutions can help organizations launch dependable, scalable, and high-quality apps faster, revamp their business models, and build strong and secure IT infrastructures - all while capitalizing on new growth opportunities.
Modernization: Customer Centric Apps
According to Gartner, by 2022, more than 75% of global organizations will be running containerized applications in production. A container is the entire run-time environment bundled into a single package, including applications, system libraries, configuration files, settings, and other binaries. Containers enable faster development, testing, deployment, and re-engineering of apps across multiple environments, including local laptops, on-premise data centers, and cloud platforms.
A Power Up: A Creative Future with Generative AI
A new disruptive technology, generative AI, enables organizations to create artifacts that previously required human expertise, allowing for breakthrough innovation in the fields of content, visual arts, design, and other creative activities. In the near future, the technology is expected to revolutionize the field of software engineering.
No Code Law: Democratization of Software
No code-low code application development platforms will continue to gain traction in organizations. These platforms enable citizen developers – non-technical business users in organizations – to create compelling apps in a more efficient and convenient manner.
Rise in Event-Driven Architecture
When an event is detected, it is routed through event channels from event producer to event consumer. This allows the services to be decoupled, allowing them to be acted on, scaled, and deployed in a seamless and independent manner. Intelligent software engineering services can be used to launch new products and services in new industries and fields. At Innover, we provide premier software engineering services that assist clients in developing proven, custom applications that customers want, reinventing their core capabilities, and delivering cutting-edge industrial solutions with speed and precision.