What all3D Oy, an AVEVA specialist, can offer to your company?

As an AVEVA specialist, we offer a range of services to support our clients in leveraging these technologies in projects.

  • Consulting and Advisory Services: Providing expert advice and guidance on the implementation, configuration, and optimization of AVEVA E3D software to meet the specific needs and objectives of each clients’ projects.
  • Training and Education: Offering comprehensive training programs and workshops to educate clients’ teams on the use of AVEVA E3D software, ensuring that users have the necessary skills and knowledge to maximize the software’s potential.
  • Developing custom solutions and integrations tailored to clients’ unique requirements, such as custom plugins, automation scripts, and integrations with other software systems to enhance productivity and workflow efficiency.  In comes our easyTools package, designed to improve usage for clients.
  • Project Implementation and Support: Assisting clients with the implementation and rollout of AVEVA E3D software within their organizations, providing ongoing support and assistance throughout the project lifecycle to ensure smooth operation and successful outcomes.
  • Data Management and Migration: Offering services related to data management, migration, and cleanup to help clients organize and streamline their engineering data within AVEVA E3D environments, ensuring data integrity and consistency.
  • Clash Detection and Resolution: Providing specialized services for clash detection and resolution using AVEVA E3D software, helping clients identify and resolve clashes and interferences within their projects to minimize rework and construction delays.
  • Customization and Optimization: Assisting clients with customizing and optimizing their AVEVA E3D environments to improve performance, efficiency, and usability, through custom configurations, templates, and workflows.
  • Project Collaboration and Coordination: Facilitating collaboration and coordination among multidisciplinary teams working on AVEVA E3D projects, through tools, processes, and best practices for effective communication and teamwork.
  • Quality Assurance and Best Practices: Providing quality assurance services and implementing best practices for AVEVA E3D projects, including standards compliance, quality control processes, and audits to ensure project deliverables meet the highest standards.
  • Continuous Improvement and Innovation: Staying abreast of the latest developments and innovations in AVEVA E3D technology, and providing clients with insights, recommendations, and strategies for continuous improvement and innovation in their projects.

By offering a comprehensive range of services, we can support our clients in maximizing the value and impact of these technologies on clients projects, ultimately driving success and delivering superior outcomes.

Role and Duties of an AVEVA E3D Administrator

What does AVEVA Admin do?

The AVEVA E3D Administrator plays a pivotal role in ensuring the successful implementation, configuration, and maintenance of the AVEVA E3D software within an organization. As a key member of the project management team, the E3D Administrator is responsible for various critical tasks that contribute to project success and efficiency.



  • System Configuration and Setup: Configure and set up the AVEVA E3D environment, including project templates, user roles, permissions, and project-specific settings, to ensure optimal performance and adherence to project requirements.
  • User Management: Manage user accounts, permissions, and access levels within the AVEVA E3D system to ensure that each user has appropriate access rights based on their role and responsibilities.
  • Project Management Support: Provide support to project managers and engineering teams by assisting with project setup, data management, and troubleshooting issues related to the AVEVA E3D software, ensuring smooth project execution.
  • Training and Documentation: Develop training materials and documentation to onboard new users and train existing users on the use of the AVEVA E3D software, ensuring that users have the necessary knowledge and skills to effectively utilize the software.
  • Customization and Configuration: Customize and configure the AVEVA E3D software to meet the specific needs and requirements of the organization, including customizing user interfaces, workflows, and reports, to optimize productivity and workflow efficiency.
  • Data Management and Integration: Oversee data management processes within AVEVA E3D, including data import/export, data integrity checks, and integration with other engineering and design software systems, to ensure seamless data flow and consistency.
  • Technical Support and Troubleshooting: Provide technical support and troubleshooting assistance to users encountering issues with the AVEVA E3D software, diagnosing problems and implementing solutions to ensure smooth operation and minimize downtime.


The role of the AVEVA E3D Administrator is crucial for effective project management and utilization of the AVEVA E3D software within the organization. By overseeing system configuration, user management, training, customization, and technical support, the E3D Administrator ensures that the software is utilized to its full potential, maximizing its impact on project outcomes.


Key Skills:

  • Proficiency in AVEVA E3D software and its features
  • Strong technical and problem-solving skills
  • Excellent communication and interpersonal skills
  • Attention to detail and ability to work collaboratively in a team environment

In conclusion, the AVEVA E3D Administrator plays a vital role in driving project success by effectively managing the implementation and utilization of the AVEVA E3D software. With their expertise and dedication, they contribute to the efficient execution of engineering and design projects within the organization.


Exploring the Depths of Laser Scanning

What is laser scanning?

In a world fueled by technology, the capabilities of modern tools continue to expand, revolutionizing the way we interact with our surroundings. One such groundbreaking technology making waves across various industries is laser scanning. From architecture to archaeology, this versatile tool is transforming the way we capture, analyze, and interpret spatial data.

But what exactly is laser scanning, and what is it used for? Let’s delve into the intricacies of this cutting-edge technology and explore its diverse applications.

Understanding Laser Scanning:

Laser scanning, also known as LiDAR (Light Detection and Ranging), is a method used to capture precise spatial data by emitting laser beams towards a target and measuring the reflected light. These beams create a point cloud—a collection of millions of individual points in 3D space—representing the surface geometry of the scanned object or environment. By meticulously capturing this data, laser scanning enables the creation of highly detailed and accurate digital models of real-world objects or landscapes.

Applications Across Industries:

1. Architecture and Construction.

2. Archaeology and Cultural Heritage Preservation.

3. Civil Engineering and Infrastructure:

In the realm of civil engineering and infrastructure, laser scanning plays a pivotal role in infrastructure planning, design, and maintenance. Civil engineers utilize laser scanning to create precise digital representations of transportation networks, bridges, tunnels, and other infrastructure assets. This data aids in asset management, condition assessment, and the detection of structural deformities or defects, ensuring the safety and longevity of critical infrastructure systems.

4. Environmental Monitoring and Conservation:

Laser scanning contributes significantly to environmental monitoring and conservation efforts by facilitating the mapping and analysis of natural landscapes, ecosystems, and habitats. Researchers utilize laser scanning to monitor changes in vegetation, topography, and land cover over time, aiding in biodiversity assessment and habitat conservation. Furthermore, laser scanning enables the creation of detailed terrain models for flood risk assessment, watershed management, and environmental impact analysis.

5. Entertainment and Virtual Reality.

Laser scanning in Surveying:

Laser scanning has revolutionized the field of surveying, offering surveyors an efficient and precise method for capturing detailed spatial data of landscapes, structures, and environments. Here’s how laser scanning is used in surveying:

  • Highly Accurate 3D Mapping: Laser scanning produces dense point clouds that accurately represent the surface geometry of the scanned area. Surveyors can use these point clouds to create detailed 3D models of terrain, buildings, and other features with exceptional accuracy.
  • As-Built Surveys: Laser scanning is employed for conducting as-built surveys of existing structures and infrastructure. By capturing detailed measurements of buildings, roads, bridges, and other assets, surveyors can create accurate digital representations for renovation, retrofitting, or maintenance purposes.
  • Topographic Mapping: Laser scanning facilitates the creation of precise topographic maps by capturing elevation data with high accuracy. Surveyors can use laser scanners to measure terrain features, such as hills, valleys, and contours, enabling comprehensive mapping of land surfaces for urban planning, land development, and environmental assessments.
  • Volume Calculations: Laser scanning enables surveyors to accurately calculate volumes of stockpiles, excavation sites, and landfills. By comparing multiple scans over time, surveyors can monitor changes in volume and track the progress of construction projects or mining operations.
  • Monitoring Structural Deformation: Laser scanning is utilized for monitoring structural deformities and movements in buildings, bridges, dams, and other infrastructure assets. By conducting regular scans and comparing the data to previous measurements, surveyors can detect deviations from the original design and identify potential issues before they escalate.
  • Utility Mapping: Laser scanning aids in the mapping and documentation of underground utilities, such as pipes, cables, and conduits. Surveyors can use specialized laser scanning techniques, such as ground-penetrating LiDAR, to detect and visualize subsurface infrastructure without the need for excavation, reducing the risk of damage and disruption to utilities.
  • Urban Planning and Development: Laser scanning supports urban planning and development initiatives by providing accurate spatial data for analyzing existing infrastructure, land use patterns, and environmental conditions. Surveyors use laser scanning to assess site suitability, plan transportation networks, and visualize proposed development projects in 3D.
  • Heritage Documentation: Laser scanning plays a crucial role in documenting historical sites, monuments, and cultural heritage assets. Surveyors can capture detailed 3D scans of archaeological sites, statues, and buildings, preserving them digitally for conservation, research, and educational purposes.

What is laser scanning in BIM?

Laser scanning plays a pivotal role in Building Information Modeling (BIM) processes by capturing accurate and detailed spatial data of existing buildings or infrastructure.

Here’s how laser scanning is utilized in BIM:

  • As-Built Documentation: Laser scanning is used to create precise as-built documentation of existing structures. By capturing millions of data points, laser scanners generate highly detailed 3D models of buildings, capturing their current state with exceptional accuracy.
  • Point Cloud Generation: The data collected by laser scanners is processed to generate point clouds, which serve as the foundation for creating BIM models. Point clouds contain millions of individual points in 3D space, accurately representing the surfaces and features of the scanned environment.’
  • Modeling Existing Conditions: BIM software tools allow designers and architects to import point cloud data and use it as a reference for modeling existing conditions. By overlaying the point cloud with parametric BIM elements, such as walls, floors, and structural components, designers can create accurate digital representations of the existing structure.
  • Clash Detection and Coordination: Laser scanning aids in clash detection and coordination during the design and construction phases of a project. By comparing the BIM model with the point cloud data, potential clashes between proposed design elements and existing conditions can be identified and resolved early in the process, reducing costly errors and rework.
  • Renovation and Retrofitting: Laser scanning facilitates renovation and retrofitting projects by providing architects and engineers with detailed as-built information of existing buildings. BIM models derived from laser scanning data enable designers to assess structural integrity, plan modifications, and visualize proposed changes before construction begins.
  • Facility Management: Laser scanning contributes to facility management by providing accurate as-built documentation for building owners and operators. BIM models derived from laser scanning data serve as valuable resources for managing and maintaining building assets, tracking changes over time, and facilitating efficient facility operations.
  • Visualization and Simulation: Laser scanning enhances visualization and simulation capabilities in BIM workflows. By integrating point cloud data with BIM models, designers can create immersive 3D visualizations, virtual walkthroughs, and simulations, enabling stakeholders to better understand proposed designs and make informed decisions.

Laser scanning plays a crucial role in BIM processes by capturing accurate as-built data and facilitating the creation of detailed digital models of existing buildings and infrastructure. By leveraging laser scanning technology, BIM practitioners can improve project efficiency, enhance collaboration, and deliver high-quality designs that meet the needs of clients and stakeholders.

What are the benefits of laser scanning in construction?

Laser scanning offers numerous benefits in construction, revolutionizing traditional methods of data capture, analysis, and project management. Here are some key advantages of using laser scanning in construction:

  • Accurate As-Built Documentation: Laser scanning provides highly accurate and detailed as-built documentation of existing structures and environments. By capturing millions of data points, laser scanners create precise 3D models that accurately represent the current state of construction sites, buildings, and infrastructure.
  • Time and Cost Savings: Laser scanning helps streamline construction processes, leading to significant time and cost savings. By capturing comprehensive data quickly and efficiently, laser scanning reduces the need for manual measurements and site visits, accelerating project timelines and minimizing labor costs.
  • Enhanced Safety: Laser scanning enhances safety on construction sites by reducing the need for personnel to work in hazardous or hard-to-reach areas. Scanners can capture data from a distance, eliminating the need for workers to access dangerous or inaccessible locations, thus reducing the risk of accidents and injuries.
  • Improved Accuracy and Quality Control: Laser scanning ensures high levels of accuracy and precision in construction projects. By capturing detailed measurements of existing conditions, construction teams can detect discrepancies, deviations, and potential issues early in the process, enabling proactive quality control and minimizing rework.
  • Clash Detection and Coordination: Laser scanning facilitates clash detection and coordination by comparing as-built conditions with proposed designs. By overlaying laser scan data with Building Information Modeling (BIM) models, construction teams can identify clashes between design elements and existing conditions, enabling timely resolution and minimizing conflicts during construction.
  • Efficient Retrofitting and Renovation: Laser scanning supports retrofitting and renovation projects by providing accurate as-built documentation of existing structures. By capturing detailed 3D models of buildings, laser scanning enables designers and engineers to assess structural integrity, plan modifications, and visualize proposed changes before construction begins, thus minimizing costly surprises and delays.
  • Remote Monitoring and Progress Tracking: Laser scanning enables remote monitoring and progress tracking of construction projects. By conducting periodic scans of construction sites, project stakeholders can monitor progress, track changes, and identify potential issues in real-time, even from remote locations, facilitating better decision-making and project management.
  • Documentation for Facility Management: Laser scanning provides valuable documentation for facility management purposes. By creating accurate 3D models of buildings and infrastructure, laser scanning enables facility managers to efficiently manage assets, plan maintenance activities, and optimize operations throughout the lifecycle of the facility.

In summary, laser scanning offers a wide range of benefits in construction, including improved accuracy, efficiency, safety, and cost-effectiveness. By leveraging laser scanning technology, construction teams can enhance project outcomes, minimize risks, and deliver high-quality results that meet the needs of clients and stakeholders.



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