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Question 1 of 30
1. Question
Type of ties that should be tied into the structure at each floor level in orthogonal directions as far as practicable.
Correct
Corner columns should be tied into the structure at each floor level in orthogonal directions as far as practicable. (Code of Practice for Precast Concrete Construction 2016 – 2.7.8.7 Corner column ties).
Incorrect
Corner columns should be tied into the structure at each floor level in orthogonal directions as far as practicable. (Code of Practice for Precast Concrete Construction 2016 – 2.7.8.7 Corner column ties).
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Question 2 of 30
2. Question
Each bearing wall or column should be tied continuously at all levels. The tie should be able to resist a tensile force equal to the maximum design dead and imposed load at the column or wall from any one story.
Correct
Vertical ties to columns and walls, each bearing wall or column should be tied continuously at all levels. The tie should be able to resist a tensile force equal to the maximum design dead and imposed load at the column or wall from any one story. (Code of Practice for Precast Concrete Construction 2016 – 2.7.8.8 Vertical ties to columns and walls).
Incorrect
Vertical ties to columns and walls, each bearing wall or column should be tied continuously at all levels. The tie should be able to resist a tensile force equal to the maximum design dead and imposed load at the column or wall from any one story. (Code of Practice for Precast Concrete Construction 2016 – 2.7.8.8 Vertical ties to columns and walls).
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Question 3 of 30
3. Question
It means a duct through which smoke or other products of combustion or fumes from any cooking apparatus or stove or oven, or vitiated air, pass or are intended to pass for the purpose of reaching the open air.
Correct
Flue means a duct through which smoke or other products of combustion or fumes from any cooking apparatus or stove or oven, or vitiated air, pass or are intended to pass for the purpose of reaching the open air. (Building (Construction) Regulations – Part I Regulation 2).
Incorrect
Flue means a duct through which smoke or other products of combustion or fumes from any cooking apparatus or stove or oven, or vitiated air, pass or are intended to pass for the purpose of reaching the open air. (Building (Construction) Regulations – Part I Regulation 2).
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Question 4 of 30
4. Question
It means that part of a private street, cul-de-sac or access road used or intended to be used by vehicular traffic.
Correct
Carriageway means that part of a private street, cul-de-sac or access road used or intended to be used by vehicular traffic. (Building (Construction) Regulations – Part I Regulation 2).
Incorrect
Carriageway means that part of a private street, cul-de-sac or access road used or intended to be used by vehicular traffic. (Building (Construction) Regulations – Part I Regulation 2).
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Question 5 of 30
5. Question
In Basis of design, adequate durability for its environment. “Cx, Cy” stands for?
Correct
“Cx, Cy” stands for plan dimensions of a column in basis of design/aim of design. (Code of Practice for Structural Use of Concrete 2013 – 2.1.1 Aim of design).
Incorrect
“Cx, Cy” stands for plan dimensions of a column in basis of design/aim of design. (Code of Practice for Structural Use of Concrete 2013 – 2.1.1 Aim of design).
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Question 6 of 30
6. Question
What is the load factor Transportation of recommended equivalent load factors to account for dynamic forces arising during handling, transportation and erection?
Correct
1.5 Load factor in Transportation of recommended equivalent load factors to account for dynamic forces arising during handling, transportation and erection. (Code of Practice for Precast Concrete Construction 2016 – 2.5.3 Handling and Transportation – Table 2.2).
Incorrect
1.5 Load factor in Transportation of recommended equivalent load factors to account for dynamic forces arising during handling, transportation and erection. (Code of Practice for Precast Concrete Construction 2016 – 2.5.3 Handling and Transportation – Table 2.2).
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Question 7 of 30
7. Question
What is the effective bearing length of a member is lesser of: bearing length of?
Correct
In effective bearing length, the effective bearing length of a member is lesser of: bearing length of One-half of bearing length plus 100 mm or 600 mm. (Code of Practice for Precast Concrete Construction 2016 – 2.7.9.3 Effective bearing length).
Incorrect
In effective bearing length, the effective bearing length of a member is lesser of: bearing length of One-half of bearing length plus 100 mm or 600 mm. (Code of Practice for Precast Concrete Construction 2016 – 2.7.9.3 Effective bearing length).
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Question 8 of 30
8. Question
The net bearing width for isolated members should be that of non-isolated members plus how many mm?
Correct
I net bearing width of isolated members the net bearing width for isolated members should be that of non-isolated members plus 20 mm. (Code of Practice for Precast Concrete Construction 2016 – 2.7.9.3 Effective bearing length).
Incorrect
I net bearing width of isolated members the net bearing width for isolated members should be that of non-isolated members plus 20 mm. (Code of Practice for Precast Concrete Construction 2016 – 2.7.9.3 Effective bearing length).
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Question 9 of 30
9. Question
A method that need to use to reduce risk of concrete spalling, A design concrete mix for which it has been demonstrated by local experience or fire testing that no spalling of concrete occurs under fire exposure?
Correct
Method D is used to reduce the risk of concrete spalling, A design concrete mix for which it has been demonstrated by local experience or fire testing that no spalling of concrete occurs under fire exposure. (Code of Practice for Structural Use of Concrete 2013 – Chapter 4 Durability and fire resistance – Methods to reduce risk of concrete spalling).
Incorrect
Method D is used to reduce the risk of concrete spalling, A design concrete mix for which it has been demonstrated by local experience or fire testing that no spalling of concrete occurs under fire exposure. (Code of Practice for Structural Use of Concrete 2013 – Chapter 4 Durability and fire resistance – Methods to reduce risk of concrete spalling).
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Question 10 of 30
10. Question
Classification of floor uses in where people may congregate?
Correct
Class 3 is used in floors where people may congregate. (Code of Practice for Dead and Imposed Loads 2011 – 3.2 Table 3.1).
Incorrect
Class 3 is used in floors where people may congregate. (Code of Practice for Dead and Imposed Loads 2011 – 3.2 Table 3.1).
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Question 11 of 30
11. Question
What is the maximum percentage reduction of total distributed imposed load on all floors (including roof) carried by the member under consideration?
Correct
40 is the maximum percentage reduction of total distributed imposed load on all floors (including roof) carried by the member under consideration. (Code of Practice for Dead and Imposed Loads 2011 – 3.7.3.1 Table 3.11).
Incorrect
40 is the maximum percentage reduction of total distributed imposed load on all floors (including roof) carried by the member under consideration. (Code of Practice for Dead and Imposed Loads 2011 – 3.7.3.1 Table 3.11).
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Question 12 of 30
12. Question
It means the horizontal dimension of the building parallel to the direction of the wind.
Correct
Depth means the horizontal dimension of the building parallel to the direction of the wind. (Code of Practice on Wind Effects in Hong Kong 2004 – 2 – Definitions).
Incorrect
Depth means the horizontal dimension of the building parallel to the direction of the wind. (Code of Practice on Wind Effects in Hong Kong 2004 – 2 – Definitions).
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Question 13 of 30
13. Question
What is the weight percentage of Lime in typical composition and physical properties of soda lime silicate glass?
Correct
5% – 14% is the weight percentage of lime in soda lime silicate glass. (Code of Practice for the Structural Use of Glass 2018 – 4.1.2 Glass Material – Table 4.1).
Incorrect
5% – 14% is the weight percentage of lime in soda lime silicate glass. (Code of Practice for the Structural Use of Glass 2018 – 4.1.2 Glass Material – Table 4.1).
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Question 14 of 30
14. Question
Temporary buildings or buildings which will remain in position for a period of not more than one year may be designed with wind pressures of not less than what percent of pressure?
Correct
Wind pressures should not less than 70%. (Code of Practice on Wind Effects in Hong Kong 2004 – 4 – Design wind pressure).
Incorrect
Wind pressures should not less than 70%. (Code of Practice on Wind Effects in Hong Kong 2004 – 4 – Design wind pressure).
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Question 15 of 30
15. Question
If wind load does not govern, stability should be checked for a minimum notional horizontal force acting at each floor level equals to what percent of the characteristic dead load between mid-heights of the story under and above or the roof surface, as appropriate?
Correct
If wind load does not govern, stability should be checked for a minimum notional horizontal force acting at each floor level equals to 1.5% of the characteristic dead load between mid-heights of the story under and above or the roof surface. (Code of Practice for Precast Concrete Construction 2016 – 2.3.1 Stability – General).
Incorrect
If wind load does not govern, stability should be checked for a minimum notional horizontal force acting at each floor level equals to 1.5% of the characteristic dead load between mid-heights of the story under and above or the roof surface. (Code of Practice for Precast Concrete Construction 2016 – 2.3.1 Stability – General).
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Question 16 of 30
16. Question
Which of these statement are true in Static Structures?
(A) The natural wind is to be modeled to account for the variation with height of hourly mean wind speed and turbulence intensity appropriate to the site.
(B) The instrumentation and its response characteristics are to be appropriate to the loads required.
(C) The measurements should enable peak wind loads consistent with the intentions of this code to be properly determined.Correct
All of the above. A, B and C are all necessary provision for wind tunnel testing on static structures. (Code of Practice on Wind Effects in Hong Kong 2004 – Appendix A1).
Incorrect
All of the above. A, B and C are all necessary provision for wind tunnel testing on static structures. (Code of Practice on Wind Effects in Hong Kong 2004 – Appendix A1).
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Question 17 of 30
17. Question
For matching purposes, the peak gust wind pressure in the wind tunnel shall be calculated as
q = 1/2 ρ ⊽² (1+3.7 I)². What does “I” stands for?Correct
In calculating the peak gust wind pressure in the wind tunnel, q = 1/2 ρ ⊽² (1+3.7 I)². “I” stands for Turbulence Intensity. (Code of Practice on Wind Effects in Hong Kong 2004 – Appendix A6).
Incorrect
In calculating the peak gust wind pressure in the wind tunnel, q = 1/2 ρ ⊽² (1+3.7 I)². “I” stands for Turbulence Intensity. (Code of Practice on Wind Effects in Hong Kong 2004 – Appendix A6).
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Question 18 of 30
18. Question
Tests physically simulate the dynamic characteristics of the prototype building.
Correct
Aero-elastic tests physically simulate the dynamic characteristics of the prototype building. (Explanatory Materials to the Code of Practice on Wind Effects in Hong Kong 2004 – Section 5 Wind tunnel test – Dynamic Structures).
Incorrect
Aero-elastic tests physically simulate the dynamic characteristics of the prototype building. (Explanatory Materials to the Code of Practice on Wind Effects in Hong Kong 2004 – Section 5 Wind tunnel test – Dynamic Structures).
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Question 19 of 30
19. Question
A very large column, typically used for outrigger or externally braced tube in high rise structures.
Correct
Mega column is a very large column, typically used for outrigger or externally braced tube in high rise structures. (Code of practice for the structural use of steel 2011 – 1.4.2 Structural element definitions).
Incorrect
Mega column is a very large column, typically used for outrigger or externally braced tube in high rise structures. (Code of practice for the structural use of steel 2011 – 1.4.2 Structural element definitions).
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Question 20 of 30
20. Question
Part of a larger frame segment a portion of the length of a member, between adjacent points that are laterally restrained.
Correct
Sub-frame part of a larger frame segment a portion of the length of a member, between adjacent points that are laterally restrained. (Code of practice for the structural use of steel 2011 – 1.4.2 Structural element definitions).
Incorrect
Sub-frame part of a larger frame segment a portion of the length of a member, between adjacent points that are laterally restrained. (Code of practice for the structural use of steel 2011 – 1.4.2 Structural element definitions).
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Question 21 of 30
21. Question
What is the height above site-ground level of the design wind pressure qz (kPa) of 2.01?
Correct
10 m is the height above site-ground level of the design wind pressure qz (kPa) of 2.01. This is for intermediate values of height, linear interpolation is permitted. (Code of Practice on Wind Effects in Hong Kong 2004 – 4 – Design wind pressure Table 1).
Incorrect
10 m is the height above site-ground level of the design wind pressure qz (kPa) of 2.01. This is for intermediate values of height, linear interpolation is permitted. (Code of Practice on Wind Effects in Hong Kong 2004 – 4 – Design wind pressure Table 1).
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Question 22 of 30
22. Question
Ordinary float glass commonly manufactured by floating the molten glass on a bed of molten tin until it sets. It can be cut by scoring and snapping. It will break into large fragments with sharp edges.
Correct
Glass annealed glass, ordinary float glass commonly manufactured by floating the molten glass on a bed of molten tin until it sets. It can be cut by scoring and snapping. It will break into large fragments with sharp edges. (Code of Practice for the Structural Use of Glass 2018 – 1.3 Glossary of terms and condition).
Incorrect
Glass annealed glass, ordinary float glass commonly manufactured by floating the molten glass on a bed of molten tin until it sets. It can be cut by scoring and snapping. It will break into large fragments with sharp edges. (Code of Practice for the Structural Use of Glass 2018 – 1.3 Glossary of terms and condition).
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Question 23 of 30
23. Question
It is authorized code in defining of dynamic sensitive structure that the height exceeds 5 times the least plan dimension, and the natural frequency in the first mode of vibration is less than 1.0 Hz.
Correct
Australia/New Zealand Standard AS/NZS 1170.2-1989. Height exceeds 5 times the least plan dimension, and the natural frequency in the first mode of vibration is less than 1.0 Hz. (Explanatory Materials to the Code of Practice on Wind Effects in Hong Kong 2004 – Section 3 Table 3.1 Various Signposts for Dynamically Sensitive Structures).
Incorrect
Australia/New Zealand Standard AS/NZS 1170.2-1989. Height exceeds 5 times the least plan dimension, and the natural frequency in the first mode of vibration is less than 1.0 Hz. (Explanatory Materials to the Code of Practice on Wind Effects in Hong Kong 2004 – Section 3 Table 3.1 Various Signposts for Dynamically Sensitive Structures).
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Question 24 of 30
24. Question
Length between adjacent lateral restraints against buckling about a given axis, multiplied by a factor that allows for the effect of the actual restraint conditions compared to pinned ends.
Correct
Effective length for a compression member length between adjacent lateral restraints against buckling about a given axis, multiplied by a factor that allows for the effect of the actual restraint conditions compared to pinned ends. (Code of practice for the structural use of steel 2011 – 1.4.3 Structural behavior definitions).
Incorrect
Effective length for a compression member length between adjacent lateral restraints against buckling about a given axis, multiplied by a factor that allows for the effect of the actual restraint conditions compared to pinned ends. (Code of practice for the structural use of steel 2011 – 1.4.3 Structural behavior definitions).
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Question 25 of 30
25. Question
Stability of overall structure against buckling.
Correct
Global stability, stability of overall structure against buckling, overturning, uplift and sliding. (Code of practice for the structural use of steel 2011 – 1.4.3 Structural behavior definitions).
Incorrect
Global stability, stability of overall structure against buckling, overturning, uplift and sliding. (Code of practice for the structural use of steel 2011 – 1.4.3 Structural behavior definitions).
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Question 26 of 30
26. Question
Restraint that prevents lateral movement of the member in a given plane.
Correct
Lateral restraint for a compression member restraint that prevents lateral movement of the member in a given plane. (Code of practice for the structural use of steel 2011 – 1.4.3 Structural behavior definitions).
Incorrect
Lateral restraint for a compression member restraint that prevents lateral movement of the member in a given plane. (Code of practice for the structural use of steel 2011 – 1.4.3 Structural behavior definitions).
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Question 27 of 30
27. Question
Structural analysis that allows for redistribution of moments in a continuous member or frame due to plastic hinge rotation.
Correct
Plastic analysis, structural analysis that allows for redistribution of moments in a continuous member or frame due to plastic hinge rotation. (Code of practice for the structural use of steel 2011 – 1.4.3 Structural behavior definitions).
Incorrect
Plastic analysis, structural analysis that allows for redistribution of moments in a continuous member or frame due to plastic hinge rotation. (Code of practice for the structural use of steel 2011 – 1.4.3 Structural behavior definitions).
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Question 28 of 30
28. Question
What is the height above site-ground level of the design wind pressure qz (kPa) of 3.05?
Correct
150 m is the height above site-ground level of the design wind pressure qz (kPa) of 3.05. This is for intermediate values of height, linear interpolation is permitted. (Code of Practice on Wind Effects in Hong Kong 2004 – 4 – Design wind pressure Table 1).
Incorrect
150 m is the height above site-ground level of the design wind pressure qz (kPa) of 3.05. This is for intermediate values of height, linear interpolation is permitted. (Code of Practice on Wind Effects in Hong Kong 2004 – 4 – Design wind pressure Table 1).
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Question 29 of 30
29. Question
The effective length divided by the radius of gyration.
Correct
Slenderness, the effective length divided by the radius of gyration. (Code of practice for the structural use of steel 2011 – 1.4.3 Structural behavior definitions).
Incorrect
Slenderness, the effective length divided by the radius of gyration. (Code of practice for the structural use of steel 2011 – 1.4.3 Structural behavior definitions).
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Question 30 of 30
30. Question
Ability of a material to undergo plastic deformations.
Correct
Ductility, ability of a material to undergo plastic deformations. (Code of practice for the structural use of steel 2011 – 1.4.4 Material behavior definitions).
Incorrect
Ductility, ability of a material to undergo plastic deformations. (Code of practice for the structural use of steel 2011 – 1.4.4 Material behavior definitions).