Building Integrated Photovoltaic Market in Canada

The global building integrated photovoltaic market is expected to grow with a CAGR of 15.8% from 2025 to 2031. The building integrated photovoltaic market in Canada is also forecasted to witness strong growth over the forecast period. The major drivers for this market are the swift growth of solar photovoltaic installation capacities globally, driven by rising demand for renewable energy sources and growing recognition of energy security, self-sufficiency, and supportive government regulations.

The future of the building integrated photovoltaic market in Canada looks promising with opportunities in the industrial, commercial, and residential markets.

• Within the application category, the roof segment is expected to witness the highest growth over the forecast period due to enhanced strength and superior aesthetic charm in integrated roofs and skylights.
• Within the end use industry category, industrial will remain the largest segment due to increasing utilization to decrease dependence on non-renewable energy sources.

Emerging Trends in the Building Integrated Photovoltaic Market in Canada

The Canadian market for building integrated photovoltaic is witnessing game-changing shifts due to improvements in technology, growing interest in energy-efficient buildings, and a strong drive toward minimizing greenhouse gas emissions. The emphasis on alternative energy sources and environmentally friendly construction methods is making BIPV technologies popular in homes, business facilities, and public buildings. With proper legislation in place, the Canadian BIPV market is promising. Some of these trends include the following.

• Increased Adoption in Commercial Buildings: Canada is BIPV-ready, and the business sector has taken notice as they transition toward more sustainable buildings. Canada is well subsidized, allowing for BIPV installations on both new and older buildings during retrofits. Integrating solar energy systems into business infrastructures, such as electric-generating facades, windows, and roofs, allows Canadian businesses to not only meet their sustainability targets but also achieve considerable savings on electricity expenses. In addition, they satisfy green building policies. This trend will continue to grow as businesses focus more on attaining LEED certification and achieving long-term energy goals.
• Integration of BIPV with Smart Building Technologies: The integration of BIPV systems with smart building technologies is on the rise within the smart systems of Canada’s metropolitan spaces. A smart city requires efficient energy utilization, which is being integrated with BIPV for Canadian cities. Buildings now have the capability to monitor their energy use in real-time, adjust their HVAC systems, and store excess energy that would otherwise go to waste. In Canada’s colder regions, where heating costs can be high, the smart building capabilities can significantly improve overall energy performance.
• Development of Solar-Incorporated Building Elements: The integration of solar power into construction materials such as roofing solar panels, solar glass, and photovoltaic building facades is emerging as one of the most important trends in the Canadian BIPV market. These materials allow building structures to easily accommodate solar energy-harvesting equipment. They are both functional and aesthetically pleasing, making them suitable for use in residential and commercial buildings. Many governments and builders are adopting this trend and hope that its adoption will encourage more builders and property owners to consider BIPV.
• Government Incentives and Renewable Energy Targets: Government policies significantly impact the adoption of the BIPV market in Canada. Both federal and provincial levels offer several programs aimed at increasing the use of renewable energy technologies, such as funding, reimbursements, and tax incentives for BIPV system installations. Canada is also working toward a net-zero goal by 2050, which, along with a desire for a greener economy, further supports the deployment of BIPV solutions. These subsidies make BIPV technology more economically accessible, enhancing its acceptance in commercial, residential, and institutional sectors.
• Focus on Residential BIPV Solutions: The Canadian residential market for BIPV products will develop significantly as homeowners increasingly focus on decreasing energy consumption and reducing their carbon footprint. Solar BIPV technology applied as building elements offers homeowners architectural beauty, energy efficiency, and environmental friendliness. These solutions are gaining traction among Canadian homeowners due to high energy prices and growing concerns about climate change. Residential BIPV is likely to rise considerably in the coming years, supported by increased government funding and a focus on energy-saving homes.

These trends highlight the increasing acceptance of building integrated photovoltaic solutions across Canada, driven by the need for sustainability, energy efficiency, and government support. The combination of smart technologies with BIPV, the growing focus on solar BIPV materials, and their adoption in commercial and residential buildings is transforming the market. As Canada moves toward greater reliance on renewable energy and sustainability, BIPV will be instrumental in the country’s transition to a greener and more energy-efficient future.

Recent Developments in the Building Integrated Photovoltaic Market in Canada

The building integrated photovoltaic market in Canada, is at a growth stage due to advances in technology, increased interest in energy sustainability, and an evolving system of laws and regulations. These factors are revolutionizing the design, construction, and energy supply of buildings. As green energy becomes more sought-after, BIPV is positioned at the forefront of new-age construction. Below is a list of five notable recent developments that indicate the advancement of the building integrated photovoltaic market in Canada.

• Increase in the Number of BIPV Projects: BIPV projects in Canada are becoming increasingly prevalent in commercial and institutional spaces. Projects that involve the installation of solar energy systems in commercial buildings result in significant energy savings once completed. Among these are government buildings, universities, and office complexes, which have swiftly adopted BIPV solutions while achieving their environmental and energy efficiency goals. More large-scale projects are expected to incorporate BIPV as technology advances and costs decrease, which will help expand the use of renewable energy throughout Canada.
• Improvement of Technology in Canada’s Construction Industry: In Canada, advancements in the construction industry have made it possible to incorporate solar panels and photovoltaic cells that work under low-light conditions, increasing BIPV adoption. The evolution of solar panels and solar cells that function in low light enhances the effectiveness and reliability of BIPV solutions even in Canada’s frigid temperatures, improving the overall energy generation capacity of these systems. As technology continues to improve, BIPV will become even more competitive in terms of energy production.
• The adoption of net metering has allowed users to offset installation costs through energy credits, thus expanding the use of BIPV systems in Canada. Net metering allows businesses and homeowners to feed excess power back to the grid in exchange for credits. This accelerates the adoption of BIPV systems by promoting the installation of solar systems, including BIPV. With additional net metering programs across the nation, more Canadians will view BIPV systems as a viable and cost-effective renewable energy option.
• Operating Costs: The reduction of operating costs aligns with two other objectives: offsetting Canadian carbon emissions and achieving net-zero energy goals by 2050. BIPV systems are being integrated into high-performance buildings and prioritized for their low environmental impact and sustainability. In Canada, programs like LEED and Passive House promote the use of green building technology. The adoption of BIPV reduces reliance on external energy sources in these types of buildings.
• Solar-Powered Buildings in City Areas as a Priority: Canada is gradually integrating solar technologies, such as solar energy, into urban areas, as solar power has become crucial for growth. Solar energy is now being utilized in urban residential and commercial complexes with energy-efficient, self-contained buildings that include BIPV systems. Additionally, building solar panels into streets, walls, windows, and other architectural components is beginning to make waves. Major cities like Toronto, Vancouver, and Montreal are where Canadian urban planners are heavily focusing resources to mitigate the environmental harm caused by new developments.

This dramatic shift in the construction sector is supported by new technological innovations, regulations, and a greater focus on environmentally friendly buildings. The Canadian construction industry’s increasing adoption of building integrated photovoltaic systems will help transform the country’s energy infrastructure. BIPV, alongside net metering, improved photovoltaic efficiency, and large-scale BIPV projects, will help Canada achieve its renewable energy goals.

Strategic Growth Opportunities for Building Integrated Photovoltaic Market in Canada

The building integrated photovoltaic (BIPV) industry in Canada possesses great growth potential across numerous sectors. The construction industry’s inclination toward sustainability, coupled with policies favoring energy-efficient BIPV systems, is edging closer to becoming the industry norm. With advancements in technology that increase efficiency while lowering costs, Canada is likely to experience dramatic growth. Here are five areas where strategic growth in BIPV is possible:

• Residential Buildings: Similar to the commercial sector, the residential construction industry in Canada offers intensive growth potential, predominantly due to the recent surge in demand from consumers wishing to lower energy consumption and carbon emissions. BIPV systems can be integrated invisibly into building rooftops and facades, allowing for reliable and attractive electricity generation. With skyrocketing fuel prices and increasing government incentives, there has been a rapid shift toward energy independence and increased property value through BIPV solutions. Growth in the residential market will be rapid with the rising demand for energy-efficient houses.
• Commercial and Industrial Buildings: The commercial and industrial sectors in Canada continue to embrace BIPV strategies to decrease energy spending and meet energy efficiency targets. Canadian enterprises can embed solar technology within building-integrated photovoltaic systems mounted on walls and roofs, increasing their level of energy self-sufficiency. Considering the shift toward sustainability and green building certification programs such as LEED, BIPV is increasingly being adopted for major commercial developments. Carbon emission reduction and cost-saving goals among Canadian businesses will make BIPV systems a dominant feature of commercial and industrial energy strategies.
• Public Infrastructure and Government Buildings: Canadian public infrastructure and government buildings can greatly benefit from BIPV adoption. In efforts to lower emissions, the Canadian government fully supports the implementation of renewable energy technologies in public projects by integrating BIPV systems into schools, government buildings, and community centers. At the same time, these projects serve as marketing tools for the private sector to increase BIPV adoption for other applications.
• Smart Cities and Urban Development: BIPV is becoming popular in urban energy design as Canada focuses on developing smart cities. BIPV technologies are already being embedded into buildings, infrastructure, streetlights, public spaces, and transport hubs. These systems not only provide clean energy but also aid in the development of urban environments. Adoption of BIPV systems in Toronto, Vancouver, and Montreal is crucial for building smarter, greener cities with self-sustainable urban spaces.
• Renewable Energy Integration and Off-Grid Solutions: Given Canada’s unique geography and climate, BIPV has the potential to serve remote areas in off-grid regions. BIPV systems power rural and northern regions where access to traditional power structures is limited. The integration of BIPV into cabins, community buildings, and isolated homes provides energy independence in hard-to-reach areas. As off-grid alternatives grow, the energy demand in these regions will lead to increased reliance on BIPV systems.

The BIPV industry in Canada stands to grow across the residential, commercial, public infrastructure, smart city, and off-grid sectors. This adoption is facilitated by technological development, government support, and rising consumer interest in sustainability. With BIPV’s emerging importance in the market, Canada will be able to significantly improve the energy efficiency of its buildings. These measures will greatly help reduce carbon emissions while integrating renewable energy sources into the construction sector, alongside achieving the aforementioned energy savings.

Building Integrated Photovoltaic Market in Canada Drivers and Challenges

The building integrated photovoltaic (BIPV) markets in Canada are affected by various drivers and challenges, including technology development, economics, regulation, and market acceptance. While these drivers are positive for BIPV growth, some challenges, such as high initial investment and complicated integration, still need to be addressed. In the following section, we will analyze the most notable drivers and challenges of BIPV’s future in Canada.

The factors responsible for driving the building integrated photovoltaic market in Canada include:

• Solar panels have recently experienced advancements such as higher efficiency, lighter weight, and improved integration with building materials. These innovations are major contributors to the growth of the BIPV market in Canada. Technologies like bifacial panels, flexible modules, and transparent solar glass photovoltaic cells enable seamless incorporation into building designs. As solar efficiency increases and costs decrease, BIPV systems become more accessible for residential, commercial, and industrial buildings. This technological evolution will accelerate BIPV adoption in Canada.
• Every area of Canada is focusing on reducing carbon emissions while promoting renewable energy. This has created an environment conducive to BIPV system growth. Federal and provincial incentives such as BIPV rebates, tax credits, and grants make it easier for building owners to implement these systems. Policies like carbon taxes and green building certifications also encourage the adoption of renewable energy technologies. For BIPV systems to be integrated into residential and commercial buildings across Canada, the BIPV market must continue expanding.
• Soaring Energy Costs and the Need for Energy Self-Sufficiency: As energy costs rise, Canadians are seeking ways to reduce their reliance on conventional power sources. Solar panels integrated into building structures offer an efficient way to achieve energy sovereignty, as BIPV systems produce electricity from renewable energy sources. With BIPV systems, property owners can self-generate the energy needed to power their buildings, significantly reducing energy bills. This is especially true for regions with high energy costs and increasing interest in sustainable, self-sufficient living.
• Growth in Consumer Awareness of Sustainability and the Environment: In Canada, there is an increasing interest in building self-sustainable, energy-conserving, and eco-friendly BIPV systems. End consumers, private corporations, and government institutions have begun to understand how traditional energy systems affect the environment, leading to efforts to mitigate harmful practices. The projected growth of BIPV systems in Canada will be fueled by further legislation aimed at environmental protection, as these systems provide an opportunity for people to self-power buildings. As consumers become more aware of their surroundings, the demand for multifunctional structures like BIPV-powered buildings is expected to rise.
• Stress on Energy-Efficient Urban Spaces and Smart Cities: There is increasing attention on developing energy-efficient cities as urban areas in Canada continue to grow. The integration of smart cities has made it easier to adopt BIPV systems as an urban design innovation. Incorporating solar energy equipment within building infrastructure, such as walls, roofs, and public buildings, allows cities to save on energy costs and reduce external energy reliance. Canada’s rapid adoption of smart cities serves as an impetus for adopting BIPV technology to meet sustainability targets and improve urban living.
• Considerable Capital Investment Requirement: A core issue for the BIPV market in Canada is the significant upfront cost required for installation. While BIPV systems are economically favorable in the long run due to energy savings, the costs associated with material procurement, system design, and installation present challenges, especially for residential and small commercial developments. Even with government subsidies, these high expenses make it difficult for some property owners to justify the return on investment. This presents an obstacle, but as the industry develops and BIPV becomes more mainstream, costs should decrease, making the investment more worthwhile.

Challenges in the building integrated photovoltaic market in Canada are:

• Integration Problems within Complex Building Structures: Incorporating BIPV systems into new or pre-constructed buildings can be difficult and problematic in terms of accuracy, implementation, and integration with other building components. Each building has its own set of design and structural rules, making BIPV integration a highly detailed and calculated process. Additionally, geographical building restrictions need to be considered during construction, which can further complicate integration. The added level of regulatory compliance can make the integration process time-consuming. Unfortunately, this causes some developers to hesitate in utilizing BIPV solutions.
• Problems Related to Regulations and Permit Issues: In Canada, building codes combined with zoning regulations can obstruct the use of BIPV in buildings. There is no uniform set of codes for BIPV, and these codes are frequently absent altogether, leading to unfavorable consequences for developers and property owners. Additionally, the application process for solar energy permits is often complex and lengthy, especially in densely populated areas. Among all the regions in Canada, these regulatory challenges seem to be the most prominent. To address this, the government and industry must collaborate to amend building code restrictions and simplify permit acceptance processes.

As the BIPV market in Canada grows, the cost of energy is expected to rise due to increasing government incentives, changes in policies, and investments in improving technology. These growth factors are readily available in Canada. Nonetheless, challenges such as legal obstacles, complex integrations, and high initial costs still persist. However, with cooperation from industry experts, addressing these issues will unlock the full potential of BIPV technology. If these problems are tackled diligently, Canada’s BIPV market will flourish, helping Canada achieve its energy goals and sustainable construction practices.

List of Building Integrated Photovoltaic Market in Canada Companies

Companies in the market compete on the basis of product quality offered. Major players in this market focus on expanding their manufacturing facilities, R&D investments, infrastructural development, and leverage integration opportunities across the value chain. Through these strategies, building integrated photovoltaic companies cater to increasing demand, ensure competitive effectiveness, develop innovative products & technologies, reduce production costs, and expand their customer base.

Some of the building integrated photovoltaic companies profiled in this report include:

Building Integrated Photovoltaic Market in Canada by Segment

The study includes a forecast for the building integrated photovoltaic market in Canada by technology, application, and end use industry.

Technology [Analysis by Value from 2019 to 2031]:

• Crystalline Silicon
• Thin Film
• Others

Building Integrated Photovoltaic Market in Canada by Application [Analysis by Value from 2019 to 2031]:

• Roof
• Glass
• Wall
• Facade
• Others

Building Integrated Photovoltaic Market in Canada by End Use Industry [Analysis by Value from 2019 to 2031]:

• Industrial
• Commercial
• Residential

Features of this Building Integrated Photovoltaic Market in Canada Report

• Market Size Estimates: Building integrated photovoltaic in Canada market size estimation in terms of value ($B).
• Trend and Forecast Analysis: Market trends and forecasts by various segments.
• Segmentation Analysis: Building integrated photovoltaic in Canada market size by technology, application, and end use industry in terms of value ($B).
• Growth Opportunities: Analysis of growth opportunities in different technology, application, and end use industry for the building integrated photovoltaic in Canada.
• Strategic Analysis: This includes M&A, new product development, and competitive landscape of the building integrated photovoltaic in Canada.
• Analysis of competitive intensity of the industry based on Porter’s Five Forces model.

This report answers the following 10 key questions:

Q.1. What are some of the most promising, high-growth opportunities for the building integrated photovoltaic market in Canada by technology (crystalline silicon, thin film, and others), application (roof, glass, wall, facade, and others), and end use industry (industrial, commercial, and residential)?
Q.2. Which segments will grow at a faster pace and why?
Q.3. What are the key factors affecting market dynamics? What are the key challenges and business risks in this market?
Q.4. What are the business risks and competitive threats in this market?
Q.5. What are the emerging trends in this market and the reasons behind them?
Q.6. What are some of the changing demands of customers in the market?
Q.7. What are the new developments in the market? Which companies are leading these developments?
Q.8. Who are the major players in this market? What strategic initiatives are key players pursuing for business growth?
Q.9. What are some of the competing products in this market and how big of a threat do they pose for loss of market share by material or product substitution?
Q.10. What M&A activity has occurred in the last 5 years and what has its impact been on the industry?