Evidence required to demonstrate competence in this unit must be relevant to and satisfy all of the requirements of the elements, performance criteria and range of conditions on at least one occasion and include:

developing outlines of alternative designs

developing the design within the safety, regulatory, functional requirements and budget limitations

documenting and presenting design effectively

successfully negotiating design alteration requests

obtaining approval for final design

dealing with unplanned events

applying relevant work health and safety (WHS)/occupational health and safety (WHS/OHS) requirements, including using risk control measures

designing complex commercial refrigeration system

preparing to design complex air conditioning system.

Evidence required to demonstrate competence in this unit must be relevant to and satisfy all of the requirements of the elements, performance criteria and range of conditions and include knowledge of:

complex heating, ventilation and air conditioning (HVAC) system design, safe working practices and relevant standards, codes and regulations, including:

HVAC load estimating of multiple zone and multi-storey buildings:

system design parameters:

human comfort

system requirements in accordance with AS 1668 The use of ventilation and air conditioning in buildings SAA refrigeration code

heat transfer calculations for complex structures and building components

heat and radiation transfer calculations through complex glass structures including various internal and external shading devices

indoor air quality

olfs and decipols

complex shading:

solar data, azimuth and altitude angles

shading from adjacent structures

computer software:

heat load estimating

building thermal performance analysis and simulation software

advanced psychrometrics:

complex psychrometric processes:

revise sensible cooling and heating and evaporative (adiabatic) cooling

cooling and dehumidification

cooling and dehumidification with high latent load

cooling and dehumidification all outdoor air

cooling and dehumidification all outdoor air with dehumidified air requirements less than supply air

cooling with evaporative humidification

cooling with near isothermal humidification

spray process to include cooling and dehumidification, cooling and humidification with heated spray water, heating and humidification

partial load processes

reheat

bypass of, RA only and mix of RA and OA

variable air volume

variable coil effective surface temperature

split coil, horizontal, vertical and intertwined

system performance:

saturation efficiency of sprayers

system capacity calculated from air quantity and enthalpy change

required plant capacity and airflow rates:

effects of coil bypass factor and ADP

calculation of dehumidified air quantity, using both TSH and ERSH methods

recap on psychrometrics formulae and charts:

properties of air

gas constants

derivation of air constants

combined gas laws

Dalton’s law of partial pressures

carrier’s equation

psychrometric property tables

psychrometric charts

air mixing equations

air quantity equations

indirect evaporative coolers

analysis of cooling coil selection and performance

psychrometric analysis of:

air conditioning in tropics

all outdoor air

LCV/HWF systems

psychrometric analysis using equations and tables

air conditioning system design:

design parameters for multi-storey building:

customer and objective

customer concept of environment desired

economic

client brief

relevant design criteria:

building purpose, location, orientation and shape

external environment ambient conditions

internal load diversity

thermal capacity behaviour

thermal load (full and partial)

zoning and building usage:

space and building

occupancies, single purpose and multi-purpose

system selection criteria:

economics

environment

control requirements

existing structures

new structures

system components

space for equipment and system

selection of appropriate system

system and applications:

design features, engineering procedures and controls

direct expansion - self-contained room/zone, heat pump, multi-zone fan-coils and central station

all water - room fan-coil

all-air - constant volume variable temperature, face and bypass, reheat, constant temperature variable volume, constant volume induction, dual-duct and dual-conduit

air water - induction unit and primary air fan-coil

HVAC energy conversation techniques:

heat recovery systems

night cycle

optimum stop/start

purge cycles

chiller/boiler/cooling tower sequencing

economy cycles (based on temperature or enthalpy)

supply air reset

supply water reset

condenser water temperature reset

power demand control

load limiting

load shedding

set point relaxation

ventilation cycles

plant - fixed OA to economy, boiler to electric reheat and constant volume to variable air volume (VAV)

cost-benefit (payback)

problem-solving techniques

relevant job safety assessments or risk mitigation processes

relevant manufacturer specifications

relevant WHS/OHS legislated requirements

relevant workplace budget, quality, policies and procedures

relevant workplace documentation.

Range is restricted to essential operating conditions and any other variables essential to the work environment.

Non-essential conditions may be found in the UEE Electrotechnology Training Package Companion Volume Implementation Guide.

Designing a complex air conditioning system must include at least the following:

one major component, including:

air handling plant

compressors

condenser

evaporators

circuits and/or systems

associated components and controls