National Stadium, Beijing China – DWG and Model Files

National Stadium, Beijing China – DWG and Model Files

 

Affectionately known as Bird’s Nest, it is situated in Olympic Green Village, Chaoyang District. It was designed as the main stadium of 2008 Beijing Olympic Games.

The Olympic events of track and field, football, gavelock, weight throw and discus were held there. Since October, 2008, after the Olympics ended, it has been opened as a tourist attraction.

The construction of it started on December 24, 2003. On July, 2004, the project was stopped temporarily due to the amendment of the design. On December 27 of the same year, the construction was resumed and finished in March, 2008. The gross cost of the whole project is 2,267 million Chinese yuan (about 33 million dollars).

 

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For more Autocad Free Drawings please visit Cadtemplates Website.

Analysis of a Pole Foundation spreadsheet

Analysis of a Pole Foundation spreadsheet

 

POLEFDN” is a spreadsheet program written in MS-Excel for the purpose of analysis of a pole foundation assuming the use of a rigid round pier which is assumed free (unrestrained) at the top and subjected to lateral and vertical loads.

Specifically, the required embedment depth, the maximum moment and shear, the plain concrete stresses, and the soil bearing pressures are calculated.This program is a workbook consisting of six (6) worksheets, described as follows:

Doc – Documentation sheet

Pole Fdn (Czerniak) – Pole foundation analysis for free-top round piers using PCA/Czerniak method

Pole Fdn (UBC-IBC) – Pole foundation analysis for free-top round piers using UBC/IBC method

Pole Fdn (OAAA) – Pole foundation analysis for free-top round piers using OAAA method

Granular Soil (Teng) – Pole foundation analysis in granular soil using USS/Teng method

Cohesive Soil (Teng) – Pole foundation analysis in cohesive soil using USS/Teng method

Program Assumptions and Limitations:

1. Since there is not a universally accepted method for pole foundation analysis, this program offers up five (5) different methods of determining embedment length for pole foundations. The “Pole Fdn(Czerniak)” worksheet is the primary method emphasized in this program, since it provides the most detail in overall analysis. However, it does yield the most conservative embedment depth results of all the methods presented.

2. The references used in the different analysis methods in this program are as follows:

a.”Design of Concrete Foundation Piers” – by Frank Randall Portland Cement Association (PCA) – Skokie, IL, May 1968

b.”Resistance to Overturning of Single, Short Piles” – by Eli Czerniak ASCE Journal of the Structural Division, Vol. 83, No. ST2, Paper 1188, March 1957

c.1997 Uniform Building Code (UBC), Section 1806.8, page 2-45

d.Outdoor Advertising Association of America (OAAA) – New York, NY

e.”Tapered Steel Poles – Caisson Foundation Design” Prepared for United States Steel Corporation by Teng and Associates, July 1969

f.AASHTO Publication LTS-5 – Standard Specifications for Structural Supports for Highway Signs, Luminaries, and Traffic Signals (Fifth Edition, 2009)

Note: references “a” and “b” refer to the “Pole Fdn(Czerniak)” worksheet, while references “e” and “f” refer to both the “Granular Soil(Teng)” and “Cohesive Soil(Teng)” worksheets.

3. The “Pole Fdn(Czerniak)” worksheet assumes that the foundation is short, rigid, meeting the criteria that the foundation embedment length divided by the foundation diameter
4. This program will handle both horizontally as well as vertically applied loads. The vertical load may have an associated eccentricity which results in an additional overturning moment which is always assumed to add directly to the overturning moment produced by the horizontal load.

5. This program assumes that the top of the pier is at or above the top of the ground surface level.

6. This program assumes that the actual resisting surface is at or below the ground surface level. This accounts for any weak soil or any soil which may be removed at the top.

7. The “Pole Fdn(Czerniak)” worksheet assumes that the rigid pier rotates about a point located at a distance, ‘a’, below the resisting the surface. The maximum shear in pier is assumed to be at that ‘a’ distance, while the maximum moment in the pier is assume to be at a distance = ‘a/2′.

8. The “Pole Fdn(Czerniak)” worksheet calculates the “plain” (unreinforced) concrete stresses, compression, tension, and shear in the pier. The respective allowable stresses are also determined based on the strength (f’c) of the concrete. This is done to determine if steel reinforcing is actually required. However, whether minimum reinforcing is to be used or not is left up to the user. The allowable tension stress in “plain” concrete is assumed to be equal to 10% of the value of the allowable compressive stress.

9. The “Pole Fdn(Czerniak)” worksheet calculates the actual soil bearing pressures along the side of the pier at distances equal to ‘a/2′ and ‘L’. The respective allowable passive pressures at those locations are determined for comparison. However, it is left up to the user to determine the adequacy.

10. Since all overturning loads are resisted by the passive pressure against the embedment of the pier, this program assumes that the pier acts in direct end bearing to resist only the vertical loading. The bottom of pier bearing pressure is calculated, which includes the self-weight of the pier, assumed at 0.150 kcf for the concrete

 

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18 Masonry Design spreadsheet

18 Masonry Design spreadsheet

 

AnchorageToMasonry.xls

BeamToWall.xls

BearingWallOpening.xls

BendingPostAtTopWall.xls

CollectorToWall.xls

DevelopmentSpliceMasonry.xls

Elevator-DSA-OSHPD.xls

FlushWallPilaster-CBC.xls

FlushWallPilaster-IBC.xls

GirderAtWall.xls

HorizontalBendingWall.xls

MasonryBeam.xls

MasonryBearingWall-CBC.xls

MasonryBearingWall-IBC.xls

masonrycolumn-cbc.xls

masonrycolumn-ibc.xls

masonryshearwall-cbc.xls

MasonryShearWall-IBC.xls

 

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Autodesk Spreadsheet Calculator for RSA Pro 2013

Autodesk Spreadsheet Calculator for RSA Pro 2013

 

Engineering spreadsheet environment and spreadsheet hosting application with embedded links to Robot Structural Analysis products, allowing users to integrate their spreadsheet applications and communicate with Robot Structural Analysis.

Spreadsheet Calculator consists of a set of simple and complex calculation schemas for many areas of structural engineering. It provides a practical representation of codes and standards that can be used when performing calculations as well as detailed formulas for specific engineering problems. You can create complex calculations by selecting simple problems.

You can also add custom calculations to the existing schemas or create new schemas using the Spreadsheet Calculator tools. This way you can build a library of custom applications. Parameters can be exchanged between schemas so the output of a given calculation can serve as the input for other calculations.

 

Spreadsheet Calculator program is an open system.

You can have an unlimited number of new schemas, codes, libraries, languages.

Because Spreadsheet Calculator is built on COM technology, you can exchange information among other programs and engineering tools.

Output from Spreadsheet Calculator can be read as input into the Autodesk Robot Structural Analysis program. There is no need to type the information.

You can generate structure models using the Autodesk Robot Structural Analysis program.

You can perform a detailed analysis of structure data.Calculations are presented as complete technical documents containing detailed formulas, code references, and drawings. A generalized schema of a library module as well as its graphical form is maintained for all engineering problems.

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TEKLA Structure Tutorial Videos

Tekla Structures is one of the most capable and advanced software in this field, but on the other hand, that makes it also a little more complicated because it has more tools, settings, possibilities, and opportunities for customization. Very much like with any other software, it`s possible to learn Tekla by yourself.

 

Tekla Structures tutorial Part 1

Tekla Structures tutorial Part 2

Tekla Structures tutorial Part 3

Tekla Structures tutorial Part 4

Bar Bending Schedule Of Box Culvert

Definition of Bar bending

It is the method of bending reinforcing steel into shapes which are important for reinforced concrete construction.

Definition of Bar bending schedule(BBS)

Bar bending schedule alias schedule of bars refers to a list of reinforcement bars, a specified RCC work item that is shown in a tabular form for a smooth view. This table sums up all the necessary particulars of bars ranging from diameter, shape of bending, length of each bent and straight portions, angles of bending, total length of each bar, and number of each type of bar. This information can be used for making an estimate of quantities.

It includes all the details essential for fabrication of steel like bar mark, bar type and size, number of units, length of a bar, shape code, distance between stirrups (column, plinth, beam) etc.

While generating bar schedules, it is important to take proper care about length. In case of bending, bar length will be raised at the bending positions.

Benefits of the Bar Schedule:

When bar bending schedule is applied along with reinforcement detailed drawing, it makes the quality of construction superior.

Once bar bending schedule is prepared, cutting and bending of reinforcement is performed at factory and shipped to job site. This improves quick implementation at site and minimizes construction time and cost as fewer workers are needed for bar bending. Bar bending also circumvents the wastage of steel reinforcement (5 to 10%) and thus project cost is saved significantly.

It offers the perfect estimation of reinforcement steel requirement for all the structural members which are applied to workout complete reinforcement requirement for whole project.

Bar bending schedule offers the steel quantity requirement in a better way and thus delivers an option to make optimal use of the design in case of cost overflow.

The process becomes simple for site engineers to validate and approve the bar bending and cutting length throughout inspection prior to positioning of concrete with the support of bar bending schedule and thus facilitates in superior quality control.

It becomes easier to handle the reinforcement stock necessary for identified time duration.

It will facilitate to fabrication of R/F with structure.

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Surcharge Pressures Boussinesq multiple loads

Surcharge Pressures Boussinesq multiple loads

 

This spreadsheet computes lateral pressure against retaining wall due to vertical surcharge area loads. It handles multiple area loads and uses theory of elasticity equations developed by Boussinesq. Subsequently, the spreadsheet calculates shear force and bending moment diagrams. Worksheet is protected but without password.

 

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