Structural analysis of a buidling using Robot Structural Analysis

01Q

What are HVAC systems? Why are they essential in the modeling of buildings?

Answer:

HVAC system is basically an assembly of various types of equipment installed together to provide heating and cooling along with indoor climate control. HVAC systems involve mechanical, electrical and I & C components to provide comfort to the occupants of building/space or to preserve goods, products or items placed in space.

HVAC cooling systems may be integrated with HVAC heating systems or these may be installed separately depending upon HVAC design. HVAC system also serves on industrial scale to keep the machinery running by maintaining the temperature of space/hall/room where machines are installed. HVAC water chillers have become essential for any industry for its various needs.

The appropriate application of advanced control strategies in Heating, Ventilation, and Air-conditioning (HVAC) systems is key to improving the energy efficiency of buildings. Significant advances have been made in the past decades on model development to provide better control over the energy consumption of system components while simultaneously ensuring a satisfactory indoor environment in terms of thermal comfort and indoor air quality. Yet it is an ongoing challenge to select and implement the best-suited modeling technique for improving the control strategy of HVAC systems. For the development of modeling research it is important that the building research community is informed about the role, application, merits, shortcomings and outcomes of different modeling techniques used in HVAC systems. Even though several review articles have been published on modeling techniques, the weaknesses and strengths of these modeling techniques, along with performances of developed models associated with research studies, have rarely been identified. This study presents a critical review of current modeling techniques used in HVAC systems regarding their applicability and ease of acceptance in practice and summarizes the strengths, weaknesses, applications and performance of these modeling techniques. Additionally, the performance and outcome of some of the developed models used in real world HVAC systems have been discussed. From the extensive critical review it is evident that almost every model has a major/minor shortcoming generated from assumptions, unmeasured disturbances or uncertainties in some system properties. This review aims at highlighting the shortcomings of existing application-based research on HVAC systems, and accordingly, recommendations are presented to improve the performance of building HVAC systems.

02Q:

AIM: To desing the HVAC system for each floor for the building designed in the weel 7 assignment and to assign all the collectors, Duct, blower at appropriate groups tp com[lete the modeling of HVAC UNIT.

TOOLS USED:

• Mechanical template
• collobrate
• manage links
• manage tab
• systems
• airterminals
• Duct
• Layout connect

PROCEDURE:

1) Open the Revit and go to new and select the Mechaical template and save the template with appropriate name.

2) Draw the grids and specify the coordinates as 0'0" in both the direction.

3) Then select the collobrate tab and collobrate the model .

4) Go to manage tab and select the manage link the Architectural model that we have created in week 7.

5)Relocate the cordinates and acquire coordinates

6)Select the system tab and select the air teminals and place the Return diffures and supplying diffuser in the rooms at appropriate place and place the Blowers and collectors

7) Select the elements in the room and click on duct option the dudcts are automatically created you choose in which direction you need.

8) look in 3D view wheather the ducts are clasihing with any wall and adjust by increasing the offset in the properties browser.

9)Similarly add all the HVAC Componets to the remaing floor.

RESULT: The HVAC system componets like collecter, blowers are placed in the building successfully.

03Q:

Use the add-ins tab to load plug-ins for robot structural analysis to your Revit software

    AIM: To load plug-ins for robot structural analysis to your Revit software using the add-ins tab.

    INTRODUCTION:

• Robot Structural Analysis Professional is structural load analysis software that verifies code compliance and uses BIM-integrated workflows to exchange data with Revit.
• It can help you to create more resilient, constructible designs that are accurate, coordinated, and connected to BIM. 

    PROCEDURE:

    Step:1

• First we click on the autodesk app store, as shown below.
• After clicking this, the autodesk store website will be opened.
• Next download the structural analysis toolkit 2019 from the autodesk app store.

    Step:-2

• After installing the structural analysis toolkit, open the revit software.
• Then open the analyze toolbar, the robot structural analysis option will appears at the right side corner, as shown below.

    RESULT:-

• The robot structural analysis is successfully installed from the autodesk app store.

04Q:

Why do we need to assess buildings/analyze while modeling elements? Does design affect modeling in anyways?

Answer:

Structural analysis is the process of calculating the forces, moments and deflections to which the members in a structure are to be subjected. There is a vast range of analysis tools offering speed, precision and economy of design. 3-D, FE modelling, bespoke portal frame, cellular beam or plate grider design software are now widely available. Modelling catenary actions, cold formed member performance or grillage analysis - all these are now commonplace for structures, where hand analysis is impossible. Increasingly sophisticated analysis methods continue to improve the accuracy with which the behaviour of structures can be predicted.

To perform an accurate analysis a structural engineer must determine information such as structural loads, geometry, support conditions, and material properties. The results of such an analysis typically include support reactions, stresses and displacements. This information is then compared to criteria that indicate the conditions of failure. Advanced structural analysis may examine dynamic response, stability and non-linear behavior. There are three approaches to the analysis: the mechanics of materials approach (also known as strength of materials), the elasticity theory approach (which is actually a special case of the more general field of continuum mechanism), and the finite elements approach. The first two make use of analytical formulations which apply mostly simple linear elastic models, leading to closed-form solutions, and can often be solved by hand. The finite element approach is actually a numerical method for solving differential equations generated by theories of mechanics such as elasticity theory and strength of materials. However, the finite-element method depends heavily on the processing power of computers and is more applicable to structures of arbitrary size and complexity.

05Q:

AIM :

 From the structural model developed in week 6 and 7, export the complete analytical model to robot structural analysis.
             a. List your assumptions on what boundary conditions will be realistic for the analysis approach
             b. Use the design standards to decide what loads must be applied to floorings based on the type of structure decided
             c. List the load combinations and include them in the analysis model
             d. Analyze the building and report the following results
                              i. Maximum Moment in each floor for all Load Combinations
                              ii. Maximum Displacement in each floor for all Load combinations
                              iii. Lateral Displacement in building for all Lateral Load combinations
             e. After analysis, do you think you have a better approach or idea in modeling structural members?

Answer:

PROCEDURE:

Step:-1

• First we have to open the structural model. • Next we open the structural settings in the manage toolbar, as shown below.

Step:-2

• Next we add the bounday conditions to the analytical model, as shown in the below figure.
• Next we apply the loads to the analytical model using the loads option in the analyze toolbar, as shown below.

Step:-3

• Next we have to exoport the complete analytical model to the robot structural analysis,
• using the robot structural analysis option in the analyze toolbar, as shown in the below figure.

Step:-4

• After selecting the robot structural analysis option the new tab will be visible and click on the ok button, as shown in the below figure.

Step:-5

• Here there is an error for exporting the analytical model to robot structural analysis, as shown below.
• Now i can't able to export the analytical model to robot structural analysis. • And the results manager is also getting an error, as shown in the below figure.

RESULT:

06Q:

 What is energy analysis and why do we need to consider it while modeling in Revit?

How does the factor of sustainability improve the quality of your design?

Energy simulation can help you analyze the movement of energy in, out, and through the rooms and volumes in a building model. This information can help designers make better informed, cost-effective decisions that improve the performance and reduce the environmental impact of buildings.

Whole building energy simulation measures expected energy use (fuel and electricity) based on the building's geometry, climate, building type, envelope properties, and active systems (HVAC & Lighting). It takes into account the interdependencies of the building as a whole system.

By performing energy analysis on proposed designs during the conceptual stage, you can make informed decisions early in the design process. The analysis results can provide insight into the role of building form and materials on potential building energy use.

To use Energy Analysis for Autodesk® Revit®, first use Revit to create several conceptual masses to visualize different design ideas. For each mass, enable mass floors, define energy settings, and submit an energy simulation to the Autodesk Green Building Studio cloud service. When Revit displays an alert, the simulation is complete and ready for viewing.

After performing energy simulations for the proposed designs, compare the results. Discard ideas that don't meet minimum sustainability standards. Iterate the more successful designs by changing their position, shape, materials, or other variables to improve the energy analysis results. When you choose a conceptual design for development, you can continue to work in Revit, adding building elements to the model based on the conceptual mass.