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Selected Works: Pro Gallery
Havant Thicket Reservoir Visitor Centre - Havant, UK
New Built | Sustainability | Parametric Modelling | Thermal Modelling
The Visitor Centre forms part of the Havant Thicket Reservoir development in Hampshire — the UK’s first major new reservoir in over 30 years and its largest, covering 160 hectares with a capacity of 8.7 billion litres. Designed as a public gateway to the landscape, the centre supports community engagement, environmental education, and recreation. Facilities will include a café, flexible activity space, shop, and interpretation areas, serving as a hub for learning and connection to the natural environment.
The design process was guided by sustainability and performance. Parametric modelling, using Rhino/Grasshopper and the Ladybug suite, informed façade design through hundreds of iterations, testing daylight access, U-values, and glazing ratios to optimise comfort and energy use. Thermal modelling in IES, based on CIBSE steady-state methodology, was employed to precisely size heating and cooling systems, reducing the risk of oversizing.
Sustainability measures include a high-performing building fabric, form optimisation, and consideration of on-site renewable technologies such as wind turbines and floating photovoltaics. Proposals also feature a bird hide built with eco-friendly natural materials, a low-embodied-carbon structure, low-GWP refrigerant systems for MEP, vacuum toilets for water efficiency, and a design language that highlights natural materials.
The outcome is envisioned as a welcoming public space that not only enhances user experience but also raises awareness of sustainability in the built environment. By integrating renewable strategies, resilient systems, and an ecological design approach, the project seeks to create a benchmark for future water infrastructure visitor facilities in the UK.
The Visitor Centre forms part of the Havant Thicket Reservoir development in Hampshire — the UK’s first major new reservoir in over 30 years and its largest, covering 160 hectares with a capacity of 8.7 billion litres. Designed as a public gateway to the landscape, the centre supports community engagement, environmental education, and recreation. Facilities will include a café, flexible activity space, shop, and interpretation areas, serving as a hub for learning and connection to the natural environment.
The design process was guided by sustainability and performance. Parametric modelling, using Rhino/Grasshopper and the Ladybug suite, informed façade design through hundreds of iterations, testing daylight access, U-values, and glazing ratios to optimise comfort and energy use. Thermal modelling in IES, based on CIBSE steady-state methodology, was employed to precisely size heating and cooling systems, reducing the risk of oversizing.
Sustainability measures include a high-performing building fabric, form optimisation, and consideration of on-site renewable technologies such as wind turbines and floating photovoltaics. Proposals also feature a bird hide built with eco-friendly natural materials, a low-embodied-carbon structure, low-GWP refrigerant systems for MEP, vacuum toilets for water efficiency, and a design language that highlights natural materials.
The outcome is envisioned as a welcoming public space that not only enhances user experience but also raises awareness of sustainability in the built environment. By integrating renewable strategies, resilient systems, and an ecological design approach, the project seeks to create a benchmark for future water infrastructure visitor facilities in the UK.
1 Princes Street - London, UK
Retrofit | Heritage Integration | Sustainability | Planning | Thermal Modelling | Circular Economy | Whole Life Carbon
Situated in the City of London, 1 Princes Street is a landmark building originally constructed in 1931 by Sir Edwin Cooper, featuring a striking Grade II-listed façade, a domed double-height banking hall, and approximately 79,077 sq ft of floor area. The project converts this historic office into a hotel, with the goal of providing affordable, sleep-focused accommodation in the heart of the City.
The design approach emphasizes heritage integration, low embodied carbon, and principles of the circular economy. The existing structure and façade are retained and restored, while reuse and recycling strategies are applied to onsite materials. Innovations include detailed whole life carbon analysis, sensitive upgrading of the building envelope, use of low GWP refrigerants, and thermal modelling to optimise energy performance and comfort.
Tools and methods used include IES for thermal modelling and Part L compliance, OneClick LCA for whole life carbon assessment, and the CIBSE TM54 methodology to predict energy consumption. The project has successfully achieved planning application approval and is moving into detailed design stage.
The vision is to offer a hotel that respects its heritage, delivers high sustainability standards, and provides calm, affordable lodging in the heart of the City of London — balancing preservation with innovation and low environmental impact.
Situated in the City of London, 1 Princes Street is a landmark building originally constructed in 1931 by Sir Edwin Cooper, featuring a striking Grade II-listed façade, a domed double-height banking hall, and approximately 79,077 sq ft of floor area. The project converts this historic office into a hotel, with the goal of providing affordable, sleep-focused accommodation in the heart of the City.
The design approach emphasizes heritage integration, low embodied carbon, and principles of the circular economy. The existing structure and façade are retained and restored, while reuse and recycling strategies are applied to onsite materials. Innovations include detailed whole life carbon analysis, sensitive upgrading of the building envelope, use of low GWP refrigerants, and thermal modelling to optimise energy performance and comfort.
Tools and methods used include IES for thermal modelling and Part L compliance, OneClick LCA for whole life carbon assessment, and the CIBSE TM54 methodology to predict energy consumption. The project has successfully achieved planning application approval and is moving into detailed design stage.
The vision is to offer a hotel that respects its heritage, delivers high sustainability standards, and provides calm, affordable lodging in the heart of the City of London — balancing preservation with innovation and low environmental impact.
7 Leicester Place Hotel Conversion — London, UK
Retrofit | Sustainability | Thermal & Compliance Modelling
Located in the West End area, the building is currently a corner office building with approval for change of use to a 230-bed capsule-style hostel over ~ 875 m² of upper floor area.
The conversion aims to repurpose underutilized office floors (Class E) into visitor accommodation, addressing urban demand for compact, affordable lodging in a central location while preserving the lower-level cinema use. The scheme handles the constraints of the building’s tight footprint, mixed-use context, and heritage/conservation sensitivities.
The design strategy centers on sustainability, cost-effective upgrades, and high-performance fabric. Thermal modelling and Part L compliance modelling in IES guide energy strategies and envelope improvements. Proposed systems include an efficient electric heating and cooling system, and operational energy benchmarking to set aspirational performance targets. Emphasis is placed on fabric-first upgrades (insulation, airtightness, glazing) to minimize loads.
Tools and analysis methods used include IES for both thermal and compliance modelling, to ensure adherence to Part L energy requirements and to optimise system sizing and envelope decisions.
The envisioned outcome is a hotel conversion that balances operational efficiency, environmental responsibility, and responsive retrofit of existing structure. It aims to deliver compact, sustainable accommodation making efficient use of existing assets and setting a retrofit benchmark for high-performance reuse in dense, sensitive urban contexts.
Located in the West End area, the building is currently a corner office building with approval for change of use to a 230-bed capsule-style hostel over ~ 875 m² of upper floor area.
The conversion aims to repurpose underutilized office floors (Class E) into visitor accommodation, addressing urban demand for compact, affordable lodging in a central location while preserving the lower-level cinema use. The scheme handles the constraints of the building’s tight footprint, mixed-use context, and heritage/conservation sensitivities.
The design strategy centers on sustainability, cost-effective upgrades, and high-performance fabric. Thermal modelling and Part L compliance modelling in IES guide energy strategies and envelope improvements. Proposed systems include an efficient electric heating and cooling system, and operational energy benchmarking to set aspirational performance targets. Emphasis is placed on fabric-first upgrades (insulation, airtightness, glazing) to minimize loads.
Tools and analysis methods used include IES for both thermal and compliance modelling, to ensure adherence to Part L energy requirements and to optimise system sizing and envelope decisions.
The envisioned outcome is a hotel conversion that balances operational efficiency, environmental responsibility, and responsive retrofit of existing structure. It aims to deliver compact, sustainable accommodation making efficient use of existing assets and setting a retrofit benchmark for high-performance reuse in dense, sensitive urban contexts.
North Light Studios — Arts University Bournemouth, UK
New Build | Timber Structure | Sustainability | Thermal Modelling | Planning
North Light Studios is a new two-storey fine arts building for Arts University Bournemouth, replacing the previous 2000 structure and spanning approximately 1,800 m². The facility provides state-of-the-art studio spaces for fine art, sculpture, traditional printing, and flexible open studio areas, alongside ancillary offices.
The design emphasizes sustainability and high-performance building systems. A timber structure was selected to minimize embodied carbon, complemented by an all-electric MEP system, natural ventilation, and solar PV integration. Solar gain studies informed west façade overhangs, and operational energy and embodied carbon benchmarking were carried out to set aspirational performance targets. Despite requirements for large, uninterrupted wall spaces to display artwork, the building successfully integrates thermal modelling and daylight analysis to optimize internal comfort and energy performance.
The planning application was approved in May 2023, marking a key milestone in AUB’s campus development. The project delivers a sustainable, high-performance, and visually inspiring environment for fine arts education, showcasing renewable energy integration, low-carbon materials, and advanced environmental modelling as part of a responsible, future-focused design strategy.
North Light Studios is a new two-storey fine arts building for Arts University Bournemouth, replacing the previous 2000 structure and spanning approximately 1,800 m². The facility provides state-of-the-art studio spaces for fine art, sculpture, traditional printing, and flexible open studio areas, alongside ancillary offices.
The design emphasizes sustainability and high-performance building systems. A timber structure was selected to minimize embodied carbon, complemented by an all-electric MEP system, natural ventilation, and solar PV integration. Solar gain studies informed west façade overhangs, and operational energy and embodied carbon benchmarking were carried out to set aspirational performance targets. Despite requirements for large, uninterrupted wall spaces to display artwork, the building successfully integrates thermal modelling and daylight analysis to optimize internal comfort and energy performance.
The planning application was approved in May 2023, marking a key milestone in AUB’s campus development. The project delivers a sustainable, high-performance, and visually inspiring environment for fine arts education, showcasing renewable energy integration, low-carbon materials, and advanced environmental modelling as part of a responsible, future-focused design strategy.
Herefordshire Council Heat Decarbonization Plans
Retrofit | Sustainability | Thermal Modelling | Low-Carbon Strategies
The project covers six schools under Herefordshire Council — five primary and one secondary — encompassing a total of approximately 12,476 m² across 13 buildings. The £1.5 million programme aimed to remove gas-fired boilers, decarbonise heating systems, and reduce operational costs while lowering carbon emissions across all sites.
A tailored approach was taken for each school following detailed site surveys, with measures selected based on feasibility and cost-to-carbon ratio. Interventions included building fabric improvements, draught-proofing, cavity wall insulation, double glazing, mechanical ventilation to improve indoor air quality, LED lighting, BMS upgrades, rainwater harvesting, solar PVs, and all-electric heating and cooling systems. The potential for Salix funding was explored, and the financial benefits of each intervention were analysed alongside energy and carbon savings.
Technical analysis involved TM54 methodology to predict energy and carbon reductions, helping to optimise each school’s retrofit package for both environmental and operational efficiency. The plans provide a roadmap for sustainable, low-carbon operations, improving the learning environment while demonstrating a cost-effective and replicable approach to school decarbonisation.
The project covers six schools under Herefordshire Council — five primary and one secondary — encompassing a total of approximately 12,476 m² across 13 buildings. The £1.5 million programme aimed to remove gas-fired boilers, decarbonise heating systems, and reduce operational costs while lowering carbon emissions across all sites.
A tailored approach was taken for each school following detailed site surveys, with measures selected based on feasibility and cost-to-carbon ratio. Interventions included building fabric improvements, draught-proofing, cavity wall insulation, double glazing, mechanical ventilation to improve indoor air quality, LED lighting, BMS upgrades, rainwater harvesting, solar PVs, and all-electric heating and cooling systems. The potential for Salix funding was explored, and the financial benefits of each intervention were analysed alongside energy and carbon savings.
Technical analysis involved TM54 methodology to predict energy and carbon reductions, helping to optimise each school’s retrofit package for both environmental and operational efficiency. The plans provide a roadmap for sustainable, low-carbon operations, improving the learning environment while demonstrating a cost-effective and replicable approach to school decarbonisation.
Islington Waste Recycling Centre — London, UK
Retrofit | Electrification | Low-Carbon Design | Sustainability
The project focuses on decarbonising the Islington Waste Recycling Centre through electrification of building systems and transitioning fleet vehicles to electric vehicles (EVs). The scope includes refurbishment of six air handling units, replacement of gas-fired domestic hot water systems with air-to-water heat pumps, and additional solar PV capacity to increase renewable energy generation.
A dynamic Excel-based tool was developed to enable the council to understand how electrification of the campus fleet and buildings would impact the electrical infrastructure. The tool allows users to input vehicle types, charging capacities, battery requirements, and electrification timelines, and to model scenarios with either smart or uncontrolled charging. It outputs electricity demand, peak loads, and the number of chargers required, helping the council plan a smooth and efficient transition to electric vehicles.
The project reduces operational carbon emissions, supports the adoption of electric fleets, and demonstrates a cost-effective approach to municipal decarbonisation. As a result, the interventions are estimated to save 234 tCO₂, creating a resilient, energy-efficient campus for ongoing waste management operations.
The project focuses on decarbonising the Islington Waste Recycling Centre through electrification of building systems and transitioning fleet vehicles to electric vehicles (EVs). The scope includes refurbishment of six air handling units, replacement of gas-fired domestic hot water systems with air-to-water heat pumps, and additional solar PV capacity to increase renewable energy generation.
A dynamic Excel-based tool was developed to enable the council to understand how electrification of the campus fleet and buildings would impact the electrical infrastructure. The tool allows users to input vehicle types, charging capacities, battery requirements, and electrification timelines, and to model scenarios with either smart or uncontrolled charging. It outputs electricity demand, peak loads, and the number of chargers required, helping the council plan a smooth and efficient transition to electric vehicles.
The project reduces operational carbon emissions, supports the adoption of electric fleets, and demonstrates a cost-effective approach to municipal decarbonisation. As a result, the interventions are estimated to save 234 tCO₂, creating a resilient, energy-efficient campus for ongoing waste management operations.
Leas Lift — Folkestone, UK
Retrofit | Heritage Integration | Sustainability | Low-Carbon Design
The project involved major refurbishment and extension works to the Grade II* listed Leas Lift, a historical landmark in Folkestone. The works included full refurbishment of the top station back-of-house areas, lower station exhibition and waiting areas, the historic pump room, and a new extension housing a café, enhancing both heritage value and visitor experience.
The design focused on heritage integration, operational efficiency, and sustainability. The existing heating system was replaced with an air-source heat pump, complemented by a PV array to further reduce operational carbon while maintaining compliance with historical conservation requirements. Overheating studies and thermal performance assessments informed building operation strategies.
Technical analysis included overheating modelling using the TM52 methodology, Part L compliance checks, and thermal modelling in IES, ensuring energy performance targets were met while respecting the historic fabric.
The project delivers a multi-functional, low-carbon visitor destination that preserves the historic significance of Leas Lift, enhances public engagement through improved exhibition and café spaces, and demonstrates a sensitive approach to sustainable retrofit in a heritage context.
The project involved major refurbishment and extension works to the Grade II* listed Leas Lift, a historical landmark in Folkestone. The works included full refurbishment of the top station back-of-house areas, lower station exhibition and waiting areas, the historic pump room, and a new extension housing a café, enhancing both heritage value and visitor experience.
The design focused on heritage integration, operational efficiency, and sustainability. The existing heating system was replaced with an air-source heat pump, complemented by a PV array to further reduce operational carbon while maintaining compliance with historical conservation requirements. Overheating studies and thermal performance assessments informed building operation strategies.
Technical analysis included overheating modelling using the TM52 methodology, Part L compliance checks, and thermal modelling in IES, ensuring energy performance targets were met while respecting the historic fabric.
The project delivers a multi-functional, low-carbon visitor destination that preserves the historic significance of Leas Lift, enhances public engagement through improved exhibition and café spaces, and demonstrates a sensitive approach to sustainable retrofit in a heritage context.
Bohunt School Extension — Wokingham, UK
New Build | Education | Sustainability | Low-Carbon Design | Overheating Assessment
The project involved expanding Bohunt School to accommodate over 400 additional students, providing new teaching spaces including science classrooms, general-purpose classrooms, a learning and resource centre, a café/social study area, and a multipurpose hall. The extension was designed to integrate seamlessly with the existing campus, enhancing the educational environment and supporting future growth.
During Stages 2 and 3, a comprehensive IES model was developed to assess heating and cooling requirements, manage overheating risks, and ensure compliance with BB101 standards. The design prioritised natural and hybrid ventilation to minimise operational energy demand, while PV panel arrays were incorporated for onsite renewable energy generation. The extension’s heating circuit was futureproofed to be compatible with low-carbon heat sources, such as air-source heat pumps. A detailed resilience study of the existing school heating system was conducted, including heat meter monitoring during winter months to confirm spare capacity for the new building.
The project delivers energy-efficient, low-carbon teaching facilities that provide enhanced learning spaces for students while integrating renewable energy and resilient infrastructure. The design balances operational efficiency, comfort, and sustainability, creating a flexible and future-ready educational environment.
The project involved expanding Bohunt School to accommodate over 400 additional students, providing new teaching spaces including science classrooms, general-purpose classrooms, a learning and resource centre, a café/social study area, and a multipurpose hall. The extension was designed to integrate seamlessly with the existing campus, enhancing the educational environment and supporting future growth.
During Stages 2 and 3, a comprehensive IES model was developed to assess heating and cooling requirements, manage overheating risks, and ensure compliance with BB101 standards. The design prioritised natural and hybrid ventilation to minimise operational energy demand, while PV panel arrays were incorporated for onsite renewable energy generation. The extension’s heating circuit was futureproofed to be compatible with low-carbon heat sources, such as air-source heat pumps. A detailed resilience study of the existing school heating system was conducted, including heat meter monitoring during winter months to confirm spare capacity for the new building.
The project delivers energy-efficient, low-carbon teaching facilities that provide enhanced learning spaces for students while integrating renewable energy and resilient infrastructure. The design balances operational efficiency, comfort, and sustainability, creating a flexible and future-ready educational environment.
Piggott School Science Block — Wokingham, UK
New Build | Education | Sustainability | Low-Carbon Design | Overheating Assessment
The project involved a science block extension at Piggott Secondary School, providing three new fully equipped science classrooms, a preparation room, and a new multipurpose hall accommodating over 200 students, along with a sixth form area and a full-scale kitchen. The design aimed to expand the school’s teaching capacity while enhancing student facilities and overall campus functionality.
The science block extended the school’s existing services, making the heating system compatible with low-carbon heat sources. The new dining and multipurpose hall incorporated PV arrays and air-source heat pumps for space heating and domestic hot water, reducing operational carbon emissions. Overheating assessments were carried out to analyse the openings and layout of the spaces, ensuring a comfortable environment for all users. The design integrates natural ventilation supported by NVHR units, maintaining airflow and thermal comfort while minimising the need for mechanical cooling.
The project delivers energy-efficient, low-carbon educational spaces that support teaching and student wellbeing. It balances sustainability, operational efficiency, and comfort, creating a functional and future-ready learning environment for Piggott School.
The project involved a science block extension at Piggott Secondary School, providing three new fully equipped science classrooms, a preparation room, and a new multipurpose hall accommodating over 200 students, along with a sixth form area and a full-scale kitchen. The design aimed to expand the school’s teaching capacity while enhancing student facilities and overall campus functionality.
The science block extended the school’s existing services, making the heating system compatible with low-carbon heat sources. The new dining and multipurpose hall incorporated PV arrays and air-source heat pumps for space heating and domestic hot water, reducing operational carbon emissions. Overheating assessments were carried out to analyse the openings and layout of the spaces, ensuring a comfortable environment for all users. The design integrates natural ventilation supported by NVHR units, maintaining airflow and thermal comfort while minimising the need for mechanical cooling.
The project delivers energy-efficient, low-carbon educational spaces that support teaching and student wellbeing. It balances sustainability, operational efficiency, and comfort, creating a functional and future-ready learning environment for Piggott School.
Wychavon District Council – Former Police Station Conversion, Pershore, UK
Retrofit | Public Sector Decarbonisation | Low-Carbon Design
This project involved the transformation of a former police station in Pershore into a modern office building for Wychavon District Council. The works included upgrading the heating and electrical systems, improving insulation and glazing, and implementing low-carbon technologies to enhance energy performance and reduce operational costs.
Funding of £145,000 was secured through the Public Sector Decarbonisation Scheme, administered by Salix Finance. This initiative supports public sector organisations in reducing carbon emissions and improving energy efficiency. The design approach focused on energy efficiency and low-carbon operation, delivering a retrofit that balances comfort, functionality, and environmental performance.
The project demonstrates a cost-effective pathway for public sector decarbonisation, transforming an existing structure into a sustainable, energy-efficient workspace while contributing to the council’s broader net-zero carbon objectives.
This project involved the transformation of a former police station in Pershore into a modern office building for Wychavon District Council. The works included upgrading the heating and electrical systems, improving insulation and glazing, and implementing low-carbon technologies to enhance energy performance and reduce operational costs.
Funding of £145,000 was secured through the Public Sector Decarbonisation Scheme, administered by Salix Finance. This initiative supports public sector organisations in reducing carbon emissions and improving energy efficiency. The design approach focused on energy efficiency and low-carbon operation, delivering a retrofit that balances comfort, functionality, and environmental performance.
The project demonstrates a cost-effective pathway for public sector decarbonisation, transforming an existing structure into a sustainable, energy-efficient workspace while contributing to the council’s broader net-zero carbon objectives.
Bangalore International Airport – Terminal 2, Bangalore, India
New Build | Airport Terminal | Architecture | BIM
Terminal 2 at Bangalore International Airport is one of the largest airport expansion projects in India, covering approximately 255,000 square meters. Completed to accommodate the city’s rapidly growing passenger demand, the terminal is designed as a world-class facility that blends functionality with a distinctive architectural identity.
The scope of work included BIM modelling and preparation of architectural drawings to support execution in selected areas of the project. This involved detailing layouts for brick walls, toilets, and railings, ensuring high levels of coordination and accuracy within the wider multidisciplinary team. My contribution focused on a dedicated section of the terminal, providing BIM support to streamline construction workflows and enhance precision.
Now fully operational, Terminal 2 stands as a landmark gateway, offering an enhanced passenger experience while strengthening Bangalore’s position as a major international hub.
Terminal 2 at Bangalore International Airport is one of the largest airport expansion projects in India, covering approximately 255,000 square meters. Completed to accommodate the city’s rapidly growing passenger demand, the terminal is designed as a world-class facility that blends functionality with a distinctive architectural identity.
The scope of work included BIM modelling and preparation of architectural drawings to support execution in selected areas of the project. This involved detailing layouts for brick walls, toilets, and railings, ensuring high levels of coordination and accuracy within the wider multidisciplinary team. My contribution focused on a dedicated section of the terminal, providing BIM support to streamline construction workflows and enhance precision.
Now fully operational, Terminal 2 stands as a landmark gateway, offering an enhanced passenger experience while strengthening Bangalore’s position as a major international hub.
Prestige Golfshire Marriott Resort, Bangalore, India
New Build | Hospitality | Architecture | BIM
The Prestige Golfshire Marriott Resort is a luxury hospitality development located on the outskirts of Bangalore, designed to provide world-class accommodation and leisure facilities. The project reflects the city’s growing demand for premium resorts, combining modern architecture with an emphasis on guest comfort and high-quality amenities.
The scope of work focused on developing a comprehensive BIM model to support accurate Bill of Quantity (BOQ) calculations and to streamline coordination across project teams. Responsibilities included preparing architectural drawings in Autodesk Revit, creating BIM models aligned with design intent, and managing team outputs to ensure accuracy and efficiency.
The Prestige Golfshire Marriott Resort is a luxury hospitality development located on the outskirts of Bangalore, designed to provide world-class accommodation and leisure facilities. The project reflects the city’s growing demand for premium resorts, combining modern architecture with an emphasis on guest comfort and high-quality amenities.
The scope of work focused on developing a comprehensive BIM model to support accurate Bill of Quantity (BOQ) calculations and to streamline coordination across project teams. Responsibilities included preparing architectural drawings in Autodesk Revit, creating BIM models aligned with design intent, and managing team outputs to ensure accuracy and efficiency.
National Data Centre, Bhopal, India
New Build | Architectural Design & Visualization | Sustainability
The National Data Centre in Bhopal is a prestigious 1500-rack facility, ranking as the fifth largest data centre in India. Developed on a 20,000 m² site, the project was designed to strengthen the country’s digital infrastructure while prioritising energy performance, resilience, and environmental impact.
The architectural scope included design development, coordination, and the integration of a comprehensive sustainability strategy. As part of this, the design considered onsite solar photovoltaic arrays to offset electricity demand, as well as rainwater harvesting systems to reduce potable water use and improve long-term environmental performance.
The National Data Centre in Bhopal is a prestigious 1500-rack facility, ranking as the fifth largest data centre in India. Developed on a 20,000 m² site, the project was designed to strengthen the country’s digital infrastructure while prioritising energy performance, resilience, and environmental impact.
The architectural scope included design development, coordination, and the integration of a comprehensive sustainability strategy. As part of this, the design considered onsite solar photovoltaic arrays to offset electricity demand, as well as rainwater harvesting systems to reduce potable water use and improve long-term environmental performance.
Chappan Placemaking, Indore, India
Urban Design | Public Realm | Construction drawings | 3D Visualization
The Chappan Placemaking project reimagined one of Indore’s most vibrant streets, transforming a one-kilometre stretch into a lively open plaza. The design sought to celebrate the street’s cultural and social significance, providing safe, accessible, and engaging spaces for pedestrians while enhancing the city’s urban identity.
The approach focused on placemaking principles, prioritising walkability, visual connectivity, and flexible open spaces that could host a variety of social and cultural activities. Key elements included the creation of wide pedestrian zones, interactive gathering spaces, and streetscape enhancements that reinforced Chappan as a civic and cultural hub.
My role encompassed site survey, concept design development, walkthrough creation, preparation of working drawings, and site supervision during execution, ensuring design intent translated effectively into the built environment.
The project has been widely appreciated by both citizens and authorities, establishing Chappan as a landmark example of community-led urban design in Indore and demonstrating the positive impact of thoughtful public realm interventions.
The Chappan Placemaking project reimagined one of Indore’s most vibrant streets, transforming a one-kilometre stretch into a lively open plaza. The design sought to celebrate the street’s cultural and social significance, providing safe, accessible, and engaging spaces for pedestrians while enhancing the city’s urban identity.
The approach focused on placemaking principles, prioritising walkability, visual connectivity, and flexible open spaces that could host a variety of social and cultural activities. Key elements included the creation of wide pedestrian zones, interactive gathering spaces, and streetscape enhancements that reinforced Chappan as a civic and cultural hub.
My role encompassed site survey, concept design development, walkthrough creation, preparation of working drawings, and site supervision during execution, ensuring design intent translated effectively into the built environment.
The project has been widely appreciated by both citizens and authorities, establishing Chappan as a landmark example of community-led urban design in Indore and demonstrating the positive impact of thoughtful public realm interventions.
Senior Citizen Housing, Indore, India
New Build | Residential | Architectural Design & Visualization
The Senior Citizen Housing project in Indore was conceived to provide a safe, comfortable, and inclusive residential environment for elderly residents. The development aimed to combine functionality with a sense of community, addressing the specific spatial, social, and accessibility needs of senior living.
The architectural scope included conceptual design, renderings, and preparation of working drawings, ensuring a balance between aesthetic quality and practical usability. The design focused on barrier-free access, clear circulation, and communal spaces that encourage interaction and support wellbeing.
The approach emphasised user-centric design principles, integrating natural light, ventilation, and landscaped courtyards to create a healthy and welcoming living environment. Material choices and detailing were guided by durability, ease of maintenance, and comfort.
The project demonstrates how architecture can contribute to dignity, independence, and quality of life for elderly communities, providing not only housing but also a supportive and enriching residential experience.
The Senior Citizen Housing project in Indore was conceived to provide a safe, comfortable, and inclusive residential environment for elderly residents. The development aimed to combine functionality with a sense of community, addressing the specific spatial, social, and accessibility needs of senior living.
The architectural scope included conceptual design, renderings, and preparation of working drawings, ensuring a balance between aesthetic quality and practical usability. The design focused on barrier-free access, clear circulation, and communal spaces that encourage interaction and support wellbeing.
The approach emphasised user-centric design principles, integrating natural light, ventilation, and landscaped courtyards to create a healthy and welcoming living environment. Material choices and detailing were guided by durability, ease of maintenance, and comfort.
The project demonstrates how architecture can contribute to dignity, independence, and quality of life for elderly communities, providing not only housing but also a supportive and enriching residential experience.
Food Testing Lab, Indore, India
New Build | Research Facility | Architectural Design & Visualization
The Food Testing Lab in Indore was designed as a specialised facility to support food safety, quality control, and research. The project required a robust architectural response that balanced high technical performance with a clean, functional, and modern environment suited for laboratory operations.
The design scope included architectural planning, detailed drawings, and 3D visualisations using Enscape, ensuring clear communication of design intent and client approvals. The lab spaces were planned with efficiency and workflow in mind, accommodating equipment layouts, safety protocols, and user comfort.
The design approach prioritised functionality, hygiene, and adaptability, with circulation and zoning strategies that ensured separation of clean and operational areas. Natural light and ventilation were integrated where possible, reducing reliance on artificial systems while maintaining strict lab standards.
By combining architectural precision with advanced rendering, the project delivered a state-of-the-art laboratory facility that enhances research capacity while projecting an image of reliability, modernity, and scientific excellence.
The Food Testing Lab in Indore was designed as a specialised facility to support food safety, quality control, and research. The project required a robust architectural response that balanced high technical performance with a clean, functional, and modern environment suited for laboratory operations.
The design scope included architectural planning, detailed drawings, and 3D visualisations using Enscape, ensuring clear communication of design intent and client approvals. The lab spaces were planned with efficiency and workflow in mind, accommodating equipment layouts, safety protocols, and user comfort.
The design approach prioritised functionality, hygiene, and adaptability, with circulation and zoning strategies that ensured separation of clean and operational areas. Natural light and ventilation were integrated where possible, reducing reliance on artificial systems while maintaining strict lab standards.
By combining architectural precision with advanced rendering, the project delivered a state-of-the-art laboratory facility that enhances research capacity while projecting an image of reliability, modernity, and scientific excellence.
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