Fișa disciplinei:

FI-D PID-174 Consultanta tehnologie in design.pdf

Department:

Interior Design and Design

Course Leader:

șef lucr.dr.habil.arh. Justin Baroncea

Learning outcomes:

Optimizing technical solutions in relation to functionality, aesthetics, and economic feasibility, by offering personalized support to students in developing execution details and the corresponding technical documentation.
Improving critical analysis and reasoning skills regarding technological choices, through individual and group sessions where students justify their decisions in front of faculty members and invited professionals.
Supporting the coherent integration of technological solutions within the diploma project, in accordance with quality requirements (operational safety and accessibility, energy efficiency, sustainability, fire safety, acoustics, etc.).
Developing the ability to select and apply current and appropriate constructive solutions that match the proposed design concept, considering the materials used, implementation processes, and execution details.
Forming an interdisciplinary vision on the role of technology in integrated design, with a focus on collaboration with technical specialists and consultants.
Preparing students for professional practice by encouraging informed and well-documented technological decisions, aligned with current regulations and quality standards.

Content:

Integration of installations and technologies within the project
Solutions for integrating HVAC, electrical, sanitary, and lighting systems into design projects, without compromising the aesthetic concept.
Approaches related to smart systems, automation, and home technologies.
Constructive solutions and execution detailing
Current implementation methods for design elements.
Nodes, finishes, assembly solutions, and compatibility between systems and materials.
Material selection and sustainability
Choosing durable, recyclable or recycled materials suitable for the project’s context.
Evaluating material performance based on resistance, maintenance, and environmental impact.
Accessibility and universal design
Applying universal design principles to ensure access for people with disabilities.
Integration of tactile and visual elements for orientation and safety.
Acoustic comfort and sound performance
Systems and materials for soundproofing, acoustic absorption, and reverberation control.
Solutions aligned with standards for different types of spaces (offices, residences, public areas).
Applicable norms and regulations
Compliance with national and European technical standards related to safety, fire protection, hygiene, energy efficiency, and accessibility.
Interpretation and practical application of current legislation within technical documentation.
Concept analysis and technological compatibility
Assessing the integration of constructive elements in line with the design intent.
Adapting solutions to user needs and to functional and structural requirements.

Teaching Method:

a. Tutorial sessions / Individual consulting:
Weekly work sessions focused on each student’s diploma project.
Personalized technical solutions based on the stage and specifics of each design.
b. Specialized technical support and interdisciplinary consulting:
Thematic dialogues on materials, technologies, and installations.
Guidance for ensuring compatibility between technical solutions and the design concept.
c. Group sessions and thematic discussions:
Presentations and debates on relevant topics: sustainability, accessibility, resilience, acoustic comfort, etc.
Peer-to-peer exchanges based on individual project progress.

Assessment:

Continuous assessment (60%) – based on participation in consulting and correction sessions throughout the semester.
Final evaluation (40%) – Practical colloquium, consisting of the presentation and defense of the technological solutions developed for the diploma project.

Evaluation criteria:
a. Clarity and accuracy of drawings and technical details (20%)
Compliance with standards and regulations.
Precision and readability of technical documentation.
b. Consistent participation and openness to feedback (30%)
Quality of proposed solutions.
Development of the technical approach over time.
c. Coherence and justification of constructive and technological choices (20%)
Integration of sustainability, safety, and energy efficiency principles.
Alignment with the overall design concept.
d. Integration of technical details without compromising aesthetics or functionality (30%)
Ability to maintain a cohesive design language.
Quality and completeness of the final technical documentation.