Describe with annotated sketches the process you obtained the horizontal angular measurements on-site using a Total Station from your allocated instrument position.

Surveying assignment

Using the rise and fall method sheet in Appendix 2, conduct a levelling survey of the identified observation/stake points around the development site (Refer to practical survey Risk Assessment in Appendix 4).

Record the data obtained from the various line of sights (intermediate sights and fore sights) in your booking sheet.

Evaluate the Reduced Levels (RL) on the booking sheet and carry out the mathematical check.

Verify the accuracy of the levelling survey and comment accordingly.

Produce a sketch of the vertical section along the line of levelling survey and explain the process/procedures you have taken to accurately carry out the levelling survey (Note: the sketch should not be hand-drawn but produced with applications such as CAD, Excel etc.).

Using a Total station, the horizontal angular measurement of some identified target points are required to be taken from specific station positions within the K-block site (Refer to practical survey Risk Assessment in Appendix 4).

Record the horizontal circle readings for the target points in the booking sheet shown in Appendix 3.

Determine the mean horizontal circle readings for the identified target points from your allocated instrument position.

Evaluate the mean horizontal angles for the target points.

Describe with annotated sketches the process you obtained the horizontal angular measurements on-site using a Total Station from your allocated instrument position.

 

Determine the temperature of the fluid by using a heat balance.Calculate the logarithmic mean temperature difference (∆Tm,l og ).

Math/Physic/Economic/Statistic Problems

Determine the temperature of the fluid by using a heat balance.

Calculate the logarithmic mean temperature difference (∆Tm,l og ).

Propose a design of the air HEX by proposing a number and size of banks along with a number of tubes and passes as well as the number and size of fins to establish the surface area of the tubes (At ) and fins (A f ).

Calculate the heat transfer coefficient for the stream of propane and air (αp and αa respectively).

Calculate the fin efficiency for heat transfer, and determine the effective heat exchange area AH E X .

Find the minimum overall heat transfer coefficient (Umi n ) and compare with acceptable values
from literature.

Calculate the overall heat transfer coefficient (U ), allowing for fouling factors.

Check pressure drop in both streams, the pressure drop inside the tubes should be no larger than 0.3 bar for propane and should be no larger than 150 Pa for air.

Accept or recalculate the design of the air HEX by suitably varying the parameters.

 Identify and discuss the various types of Additive manufacturing materials and processing machines and their suitability and limitations of being used within the wind turbine manufacturing processes.

Investigate and develop the use of Additive and Direct Digital Manufacturing with Vestas Blades.

Identify and discuss the various types of Additive manufacturing materials and processing machines and their suitability and limitations of being used within the wind turbine manufacturing processes.

Critically evaluate the specified manufacturing capabilities of the selected machine(s) against a quality criterion that fulfils the manufacturing requirements of parts and components.

Design a system and global network that enables the printing of parts and components at number of global locations within the Vestas network, these components being localised in a central database.

Write a technical report to key stake holders supporting the introduction of additive manufacturing as technology with growth potential within Vestas, including the potential for upscaling to larger parts and the associated risks.

Describe the use of zero-finding methods and integration techniques in analysis of complex systems. Describe the significance of numerical methods. Describe the algorithms used and show code that you’ve written to highlight these solving methods.

Zero-finding methods and integration techniques in analysis of complex systems

Describe the use of zero-finding methods and integration techniques in analysis of complex systems. Describe the significance of numerical methods. Describe the algorithms used and show code that you’ve written to highlight these solving methods. Use the example equation below as motivation in your description.

 

Why is only the concrete mentioned? How about soft cover materials such as polyethylene, poly carbonate, etc???Are you sure that significantly higher relative to the Asia Pacific??

IOT and greenhouses

Why is only the temperature mentioned? There are many other aero-environmental factors.

There are same images in Figure 1. What is the difference?

Future uncertainties, there are many contents not related to uncertainties.

Are you sure that significantly higher relative to the Asia Pacific??

Why is only the concrete mentioned? How about soft cover materials such as polyethylene, poly carbonate, etc???

How well do project managers in the UK understand current health and safety policies in the UK construction industry? To what extent do project managers in the UK apply national policies in setting health and safety guidelines for construction project stakeholders?

In achieving the above-listed objectives, the proposed research will seek to answer the following questions:

How well do project managers in the UK understand current health and safety policies in the UK construction industry?

To what extent do project managers in the UK apply national policies in setting health and safety guidelines for construction project stakeholders?

How successful have project managers been in ensuring health and safety in their project by following national health and safety policies?

Identify a green building material or product and analyse how sustainable the material is while considering the following factors: first costs versus life cycle costs, natural resource consumption, recyclability, and the embodied energy.

Sustainable construction

Based on the design of the zero-carbon house, identify a green building material
or product and analyse how sustainable the material is while considering the following
factors: first costs versus life cycle costs, natural resource consumption, recyclability,
and the embodied energy.

In your report, discuss the positive and negative sustainability factors and provide an answer to the question “how sustainable is this material or product.”

What are the values of id and iq if d-axis is leading the phase A axis by 90 degrees at time zero? Calculate the result using SIMULINK and explain it.

Dq0 transform(Park’s Transformation)

What are the values of id and iq if d-axis is leading the phase A axis by 90 degrees at time zero? Calculate the result using SIMULINK and explain it.

The calculation results of simulink are as follows;

Consider the following three-phase positive sequence currents with frequency of 60 Hz:

Calculate the corresponding values of id and iq if the rotating dq0 frame’s d-axis is aligned with phase A axis at time zero

How is this shown in the RQD assessment of rock strength?Explain the difference in strength between rock mass and the same material taken out of a quarry.

Geotechnics & Soil Mechanics

State the three main classes of rock and outline the main features of their formation
Give one example of how each type of rock is used in construction
Briefly outline the Bowen Series of rock classification and indicate to what extent this can explain the
weathering characteristics of rocks

d) What are the most important mechanical characteristics of rocks used in the following situations:
i) as foundations for roads
ii) as facings for structures
iii) as aggregate for concrete
HNC/HND Construction and the Built Environment 3
iv) as building stone.

e) Outline where soil is used as a construction material and compare this with alternative materials that could
be used such as in a dam

f) Explain the difference in strength between rock mass and the same material taken out of a quarry.

g) How is this shown in the RQD assessment of rock strength?

h) Analyze case studies involving tunneling and the problems posed by the discontinuous nature of rock mass
Task 2

a) Briefly explain what a brownfield site is and how this differs from other sites.

b) How would you approach a ground survey in a brown filed site and show how this might differ from a
ground survey on other sites.

c) Explain the difference between a disturbed and an undisturbed soil sample

d) Outline the laboratory tests that can be done only on undisturbed samples

e) Outline how soils are classified

f) How is plasticity used in the classification of soils?

g) Discuss the sampling of soil in situ giving an example of the measurement of bulk density and also of shear
strength.

h) Discuss the relative merits of in situ testing and laboratory

i) Evaluate how much soil sampling is needed in a soil survey on a site and what are the dangers of too little or
too much sampling?

a) Outline briefly how you would measure the following from an in-situ sample:
Soil moisture content
Dulk density and
Specific gravity

b) Outline briefly a method of measuring shear strength in-situ and one method used in the laboratory. Discuss
the limitations of this test with respect to the type of soil under test

c) Briefly outline how soil compressibility is measured in the laboratory and discuss the importance of time in
this measurement.

d) Outline the principle behind the California Bearing Test

e) State how the liquid limit and the plastic limit are measured in the laboratory and state the results we
obtained from the laboratory tests carried out.

f) The following results were obtained during a test of the liquid limit of a clay rich soil. Calculate the liquid
limit and compare the reliability and reproducibility of this test to the standard test for plastic limit.
Cone
penetration
mm
Moisture
content
g
Mass of
dry soil
g
Moisture
percent

15 3.46 10.58
19 3.86 10.71

HNC/HND Construction and the Built Environment 4
21 4.49 11.79
26 3.94 11.9731 5.93 10.57

Task 4 Address the problem of keeping the logistic area dry even during the highest tides. Occasionally tides as
high as 7m above mean sea level area experienced here when there is a Spring tide (a very high tide) together with a
strong on shore wind.

a) Outline your solution and

b) Outline what the geotechnical weaknesses are within the logistics area

c) Briefly suggest the site survey needed

d) show what foundations are needed to support and protect the area.

Identify the roots of an equation using two different iterative techniques. Determine the numerical integral of construction functions using two different methods.

Further Mathematics for Construction

Apply addition and multiplication methods to numbers that are expressed in different base
systems.

Solve engineering problems using complex number theory.

Perform arithmetic operations using the polar and exponential form of complex numbers.

Deduce solutions of problems using de Moivre’s Theorem.

Test the correctness of a trigonometric identity using de Moivre’s Theorem.

Solve systems of linear equations relevant to construction applications using matrix
methods
Ascertain the determinant of a 3×3 matrix.

Solve a system of three linear equations using Gaussian elimination.

Determine solutions to a set of linear equations using the inverse matrix method.

Validate all analytical matrix solutions using appropriate computer software.

Approximate solutions of contextualised examples with graphical and numerical
methods

Estimate solutions of sketched functions using a graphical estimation method.

Identify the roots of an equation using two different iterative techniques.

Determine the numerical integral of construction functions using two different methods.

Solve construction problems and formulate mathematical models using first-order differential
equations.

Critique the use of numerical estimation methods, commenting on their applicability and the
accuracy of the methods.

Review models of construction systems using ordinary differential equations

Determine first-order differential equations using analytical methods.

Determine second- order homogeneous and non-homogenous differential equations using
analytical methods.

Calculate solutions to linear ordinary differential equations using Laplace transforms.

Evaluate how different models of construction systems use first-order differential equations
to solve structural or environmental problems.

Evaluate first- and second-order differential equations when generating the solutions to