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Rise and shine Elegant simplicity rules at 177 Pacific Highway.
PRINT POST APPROVAL NUMBER PP352532/00001
JUNE 2018 · VOLUME 17.5RRP $14.95
Ecolibrium
ECOLIBRIUM • JUNE 201822
F E A T U R E
Net-zero homes are often viewed as expensive. Yet by adopting a simple design approach and doing it themselves, Jonathan and Robyn Rich have managed to both build at below the average per square metre construction cost, and create a lovely home that is comfortable year-round. It also boasts a large energy surplus.
Built in the Melbourne bayside suburb of Frankston, the home has two bedrooms, a total area of 150m2, and was built with an 8-star home energy rating.
Costs have been minimised by using a simple square design, a single-pitch roof, an exposed slab, recycled red brick walls
internally and in much of the exterior, and the use of second-hand materials where available.
Construction required focused hard work over a six-month period.
PASSIVE DESIGNPassive design elements include uPVC double-glazed windows and doors, less than 1m2 of glazing on the west and east sides of the house, with most of the glazing on the north side. Summer sun is kept out with a shading element, while winter sun streams onto the exposed slab.
Walls are a mixture of cavity brick and reverse brick veneer, insulated to R4.6 with 100mm polystyrene foam.
The roofing system is insulated to R6, with an R1.5 heavy-duty foil blanket immediately under the metal roof sheeting, the wrap, then R4.5 batts underneath. A conventional slab is used with waterproofing and sealing at ground level.
ACTIVE ELEMENTSFrom an HVAC&R perspective, what is most interesting about this house is the use of a ground loop to precondition air from outside entering the heat recovery ventilator (HRV).
A loop of 40mm poly pipe buried at a depth of 1.2m, and with a length of 65m running up and down the driveway and under the slab recirculates a water-glycol brine at 8 litres/minute through a coil in the HRV, with the pump motor and HRV fans drawing a combined maximum of 70W.
A glycol/water mix has been used to prevent fouling of the water.
“We were the first to commission such a unit in Australia,” Jonathan says.
Rich harvestIn days of yore, building a sustainable family residence meant spending substantially more than for a regulation dwelling. Yet an engineer and an artist have constructed a positive-energy home at less than the usual cost of construction. By Bruce Rowse, M. AIRAH, with Jonathan Rich.
23JUNE 2018 • ECOLIBRIUM
F E A T U R E
“We had to base our implementation on European experience, where glycol is also used to prevent freezing.”
In winter this system is preheating the outside air to between 15 to 16°C before it enters the HRV. In summer it pre-cools air down to around 25°C (pre-HRV), with a 30°C ambient. By doing this the HRV has enhanced heat recovery.
The HRV also has a bypass, which essentially enables an economy cycle.
The HRV operates all the time. The unit is operated at low speed overnight and medium during the day (around 50L/sec). It’s configured to deliver 0.5 air changes per hour to the living and sleeping areas, and two air changes/hour to the kitchen and bathroom at medium speed.
Power draw when the HRV is on low speed is 11W, and 44W on medium. Although it has EC motors, and the controller enables fan speeds to be
changed in increments of 1 per cent, for practical operation just three speeds have been configured. Acoustic isolation is achieved via dampers.
A standard in-line acoustic damper is also used on the exhaust-air duct adjacent to the main bedroom.
Both the bathroom and kitchen vent air to the HRV. A rangehood discharging to the internal kitchen space is fitted with activated carbon filters to capture grease to minimise fouling of the heat exchanger element in the HRV.
The internal temperature has a variation of 2 or 3°C most days. It is warmer in summer and cooler in winter (based on seven months of temperature logging, refer to Table 1).
The small reverse-cycle split system (3.2/2.5kW heating/cooling capacity) is only switched on for heating on cloudy winter days, and in summer only during a heatwave.
A 5kW solar PV system more than offsets the energy used by the home. The square shape of the building and simple roof construction means that the solar system blends in well with overall design of the building.
The heat pump domestic hot water unit, dishwasher and washing machine are all set to run during daylight hours when the solar system is operating.
All lighting is LED.
What is most
interesting about
this house is the use
of a ground loop
to precondition
air from outside
30
25
20
15
10
5
—
45403530252015105
—
0 13 2 15 4 17 6 19 8 21102312 1 14 3 16 5 18 7 20 9 2211 0 13 2 15 4 17 6 19 8 21102312 1 14 3 16 5 18 7 20 9 2211 0 13 2 15 4 17 6 19 8 21
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31
0 13 2 15 4 17 6 19 8 21102312 1 14 3 16 5 18 7 20 9 2211 0 13 2 15 4 17 6 19 8 21102312 1 14 3 16 5 18 7 20 9 2211 0 13 2 15 4 17 6 19 8 21
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31
Tem
per
atu
re °
CTe
mp
erat
ure
°C
Day of month, time
Inside and outside temperature, July 2016
Inside and outside temperature, December 2016
Tin (°C) Tout (°C)
Tin (°C) Tout (°C)
Day of month, time
Note: the outdoor temperature sensor wasn’t shaded at all times, and temperature rose above ambient when the sun hit the sensor (as can be seen in the June temperature log).
Temperatures are stable and the house comfortable in winter and summer.
Winter early morning light warming the slab.
ECOLIBRIUM • JUNE 201824
F E A T U R E
ENERGY PERFORMANCEThe house uses electricity only; annual energy exported to the grid is about 2.5 times energy imported. The energy surplus over the first 12 months of having the solar system connected is expected to be around 3,000kWh.
Should Jonathan and Robyn choose to purchase an electric car in the future, this sort of annual surplus would be enough to power the car for around 17,000km, more than they would normally drive.
The solar system was installed in October 2016 but only connected by the distributor in January 2017, (as shown in the graph). Without the solar system, annual energy use would be around 4,000kWh, corresponding to an average daily energy consumption of about 13 kWh/day. This is low considering that no gas is used.
MonthAverage
Temperature (°C)
Minimum Temperature
(°C)
Maximum Temperature
(°C)
5 18.6 17.3 22.9
6 18.4 15.7 22.1
7 19.7 17.4 22.4
8 20.0 17.4 23.2
9 20.3 17.5 23.2
10 19.6 17.2 23
11 20.1 17.8 23.8
12 21.7 19 26.1
1 22.7 20.8 25.4
25
20
15
10
5
0Tem
per
atu
re °
C
Time of day
Graph showing conditioning of supply air by time of day; July 30, 2016
Outside air After subsoil coil After HRV
Time of dayOutside air After subsoil coil After HRV
0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23
35302520151050Te
mp
erat
ure
°C
Graph showing conditioning of supply air by time of day; February 5, 2017
0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20
Air temperatures through the HRV system, cold and hot day.
Table 1: Internal temperatures.
The HRV also
has a bypass,
which essentially
enables an
economy cycle
1
3
2
4
ECOLIBRIUM • JUNE 201826
F E A T U R E
LESSONS LEARNTThe simple industrial-type design approach adopted by Jonathan and Robyn made the house both cheaper and faster to build than it otherwise would have been. Putting effort into achieving good levels of insulation and sealing has paid off in terms of comfort.
The acoustically isolated HRV is extremely quiet, and inaudible at low speed, warranting the effort to achieve this. The addition of the ground loop has
made it extremely efficient, and with a lot of thermal mass the house is stable in temperature.
On the other hand, there have been a couple of things Jonathan and Robyn would do differently if they were building again. The house was built with a split-level roof; making the roof a single level would have further simplified the build. And although the wall-mounted split system isn’t obtrusive, a cleaner solution would have been to include this into the ventilation system.
The design focused on four key areas: simplicity and ease of construction; no compromises with insulation and sealing; a high-efficiency HRV made even more efficient with the ground loop; and high-efficiency heat pump units for hot water, as well as space heating and cooling.
This home and the approach taken by its owners is a great example of comfortable and affordable sustainable housing. ❚
PROJECT AT A GLANCE
The equipment
■ Heat-recovery ventilator:Zehnder Comfoflow 350
■ Hot water heat pumpSanden 250 litre
■ Sub-soil heat exchanger:Zehnder ComfoFond-L-Eco 350
■ Ventilation ducts and registers:Zehnder
■ Split system:Daikin Zena (smallest unit made)FTXJ25PVMAW/RXJ25PVMA
■ Windows and doors:uPVC Certainteed
■ Wrap: Pro Clima
Annual energy
exported to the grid
is about 2.5 times
energy imported
IMAGES
1 Detail of wall wrap at the roof/wall joint.
2 Subsoil heat exchanger showing the water/glycol coil connected to the ground loop; entering outside air is coming in from the right, air off the coil is going into the HRV on the left. Vertical insulated duct on left at the back is the exhaust to outside, acoustic damper fitted on discharge to minimise noise next to the master bedroom.
3 Air-to-air heat exchange module in the HRV.
4 Inside the HRV, showing the space occupied by the air-to-air heat exchanger module. Incoming outside air comes through the red filter on the right, into the fan suction on the left. Air leaving the room is coming through the filter on the left, and into the exhaust fan suction on the right.
5 Detail of fan suction and filter in HRV.
6 Duct detail: supply air leaving the HRV (Bedrooms, Study, Lounge, Studio) to right, return air flowing in the HRV (4 ducts, from bathroom and kitchen) on left.
COOKING APPLIANCE
COOKING APPLIANCE
EXHAUST HOOD
AIR DISCHARGE
PRE FILTER
INTERMEDIATE FILTER
FINAL FILTER
UL1046 APPROVED HOOD FILTER
GREASE PARTICLE 0.5 - 150 micron (solid/liquid phase)
SMOKE PARTICLE 0.1 - 1.0 micron (solid phase)
ODOUR MOLECULE 0.0003 - 0.0007 micron (gas phase)
1 granule shown
ph: 1300 886 353 www.airepure.com.au
Multi-Staged Combination Filtration System
a.k.a Multi-Staged Filter Pack
Airepure KAIRE® UNITFANPARTICLE COLLECTION ODOUR REMOVAL
ADSORBENT/CHEMISORBENT MEDIACOMMONLY ACTIVATED CARBON
Fantech In-Line FanFully Integrated
RELIABLE, COST EFFECTIVEKITCHEN EXHAUST FILTRATION
AIRFLOW
Airepure’s Kaire® Unit is a multi-staged, combination filtration system designed and tailored to control kitchen exhaust emissions of all types of cooking applications except for solid fuel exhaust.
Three stages of particle filtration, including an E11 final filter, deliver minimum 0.3 micron particulate removal efficiency of 95% (EN1822.5:2009).
Final odour removal stage, including minimum 35kg of activated carbon media per 650l/s of air, provide an initial contact efficiency of 99%+ with odours when operated at 1.85m/s.
Quality Airepure filters ensure reliability, high performance and low operating costs. Fantech integrated in-line fan maintains constant airflow volume via pressure sensor and pre-configured VSD.
• Low capitol cost turn key solution
• 3 stage sequential particulate filtration
• Static pressure monitoring of mechanical filters
• Final stage of custom odour control
• Fully integrated in-line fan
DESIGNED AND MANUFACTURED IN AUSTRALIA
5 6