UNSW Sunswift

Last updated

Sunswift Racing is the solar car racing team of the University of New South Wales in Sydney, Australia. The team currently holds a number of world records and is best known for its participation in the World Solar Challenge (WSC). Since its founding in 1996 by Byron Kennedy, the Sunswift team has built a total of 7 cars, the most recent of which is Sunswift 7.

Contents

Sunswift Team

The team primarily consists of undergraduate students from various disciplines including business, engineering and industrial design. Despite its team members being largely engaged in full-time study, Sunswift has remained competitive in all participated solar car challenges, earning prestige and recognition on the world stage as well as training young engineers to be on the cutting edge of their profession. A number of former Sunswift team members have moved on to establishing their own companies and others have attained highly sought-after positions in the workforce; for example, working as part of well-established racing teams such as those in Formula 1. Some of these team members remain in contact with Sunswift even after graduation, and act as mentors or advisors to the newer recruits, thus helping to continue the standard of excellence that has been embodied in the team since its founding in 1996.

Outreach program

The Sunswift team also plays an active role in the local community by educating the general public about the advantages of solar versus conventionally powered vehicles. To this end, they regularly showcase the series of Sunswift cars at exhibitions and hold information days open to the public. In addition, Sunswift also visits schools in order to teach and inspire young children about implementing solar power technology whilst demonstrating how it can be a fun and effective method of powering a car.

How it works

All solar cars have at least five main parts to their power system: the solar array, maximum power point tracker (MPPT), battery, motor controller and electric motor. These cars rely on converting the electromagnetic energy of the sun into electrical energy, through the use of photovoltaic cells, and then converting that electrical energy into mechanical energy to drive the car, through the use of some form of electric motor. Maximum power point trackers act as an interface between the solar array and the battery, while motor controllers act as an interface between the battery and the electric motors

As sunlight shines on the solar array, it transfers energy to the electrons within the photovoltaic cells, thus allowing them to conduct electricity and causing a current to flow. This current then travels to the MPPTs which alter the load across the solar array in order to ensure that it is generating electricity as efficiently as possible. The MPPTs have to constantly monitor the output of the photovoltaic cells because that output depends on the light intensity which can change rapidly if some cells become shaded. The electricity then flows into the battery where it can be stored for later use such as to drive the car while there is no sunlight. Although the battery is primarily charged by the solar panels, it can also be externally charged by the conventionally generated electricity at your home or workplace. The battery then discharges the current into the motor controllers which converts it into a form that can be used to power the electric motor. Motor controllers are also used to manage things like speed regulation, cruise control and regenerative braking. Regenerative braking is using the existing motors as generators by converting the rotational energy of the wheels back into electrical energy, slowing the car down and recharging the battery at the same time, instead of just using conventional mechanical brakes. Lastly, the energy that was once in the sunlight shining on the car, reaches the electric motors which operate on the principles of electromagnetism to turn that electrical energy into rotational energy that spins the wheels and drives the car forward.

Sunswift 7 (2020–present)

Sunswift 7 (SR7) is the third vehicle manufactured by Sunswift designed to compete in the Bridgestone World Solar Challenge Cruiser Class. The design began in 2020, with intentions of running in the cancelled 2021 World Solar Challenge.

In December 2022, Sunswift achieved a Guinness World Record for the Fastest EV over 1,000 km (621 mi) on a single charge. [1] It achieved this in 11 hours and 52.08 minutes, at an average speed of almost 85 km/h (53 mph).

In October 2023, Sunswift won the 2023 World Solar Challenge, Cruiser Class. [2] An on-road score of 109.4, practicality score of 83.3%, and a final score of 91.1 was achieved. [3] They placed first for both the on-road score and practicality score.

Technical Specifications for Sunswift 7
Dimensions
  • Length: 4,990 mm (196.5 in)
  • Width: 2,050 mm (80.7 in)
  • Height: 1,200 mm (47.2 in)
  • Wheel Base: 3,120 mm (122.8 in)
Weight680 kg (1,500 lb)
Aerodynamics
  • Cd: 0.095
  • Frontal Area: 1.86 m2 (20.0 sq ft)
  • CdA: 0.177
ChassisCarbon fibre monocoque with foam and aramid honeycomb core
BodyworkCustom Dihedral Synchro Helix Doors. Audi A7 Headlights
Suspension
  • Generatively designed, SLM 3D-printed uprights with carbon fibre wishbones and pushrods
  • Front: Double wishbone with pushrod activated shock
  • Rear: Multi link
Battery38kWh, 151.2V
Solar Array4.4 m2 (47 sq ft)
Seats4
MotorsTwin, rear wheel, in hub, synchronous DC motors, both of which are brushless and have permanent magnets
Top Speed130 km/h (81 mph)
Range1,500 km (930 mi)
Sunswift 7 in its BWSC Race Livery Sunswift 7.jpg
Sunswift 7 in its BWSC Race Livery

Sunswift VI (VIolet) (2017–2019)

VIolet is the sixth vehicle designed and manufactured by Sunswift. It was the second vehicle manufactured by Sunswift that is built to compete in the Cruiser Class. Design of VIolet began in 2016 and manufacture was completed in late 2017. In comparison to previous generations of Sunswift vehicles, VIolet is Sunswift's first four-seat, four-door vehicle with a 5-square-metre solar array consisting of 318 monocrystalline silicon cells with an approximate efficiency of 22%. VIolet was designed with a greater focus on practicality, with the aim of resembling a more comfortable family vehicle in comparison to previous generations of Sunswift vehicles. New features have been implemented in VIolet such as live monitoring and fault detection, entertainment systems, air conditioning, navigation, wifi, reverse camera, adjustable seating, parking sensors, front and back boot-space, and ergonomic dashboard. As a result of this, the vehicle competed in the 2017 World Solar Challenge and placed third in practicality.

In December 2018, the team had driven from Perth to set a Guinness World Record for the lowest energy consumption while driving across Australia in an electric car. VIolet was then further tested and refined for reliability and efficiency, leading to an all-time highest Sunswift ranking of 2nd Place Overall in the 2019 Bridgestone World Solar Challenge and finishing first across the line in Adelaide.

Appearance of the Violet Violet Apperance.jpg
Appearance of the Violet
Technical specifications for VIolet
DimensionsLength: 5.0 metres (16 ft 5 in)

Width: 2.2 metres (7 ft 2 in)

Height: 1.2 metres (3 ft 11 in)

Weight700 kilograms (no driver)
Solar Cells/Array5.00-square-metre (53.7 sq ft) array consisting of 318 monocrystalline silicon cells with an approximate efficiency of 22%
Seats4
ChassisCarbon fibre monocoque with foam and an aramid honeycomb core
MotorsTwin, rear wheel, in hub, synchronous DC motors, both of which are brushless and have permanent magnets
Maximum speed140 kilometres/h (87 mph)
Maximum speed solely on solar power60 kilometres/h
Maximum range1000 km at a speed of 100 kilometres/h
Battery PowerModular 10-20 kilowatt-hours (36-72 MJ) lithium ion at a nominal voltage between 90 and 153V
TelemetryCustom Controlled Area Network (CAN) including GPS, barometric pressure, motor speeds, motor temperatures, tilt, and various voltages and currents

Sunswift V (eVe) (2012–2016)

The design and construction of eVe began in early 2012 and was completed within 18 months in time for the 2013 World Solar Challenge. The car cost approximately $500,000 and was built to compete in the new Cruiser Class in the WSC. This class focused on more practical solar cars with passenger seats, greater safety and more efficient batteries. To reflect its focus on practicality, the team also designed it to resemble a modern-day sports car, rather than the typical space aged style of most other solar vehicles. The car was the fastest vehicle in the Cruiser Class, achieving Line Honours and overall third place for the Cruiser class while also attaining the highest top speed of 128 kilometres per hour (80 mph).

On a single charge of its batteries, eVe can travel up to 500 kilometres (310 mi) or over 800 kilometres (500 mi) if powered by its own solar cells. Once fully depleted, the batteries can be completely recharged in 10 hours using a standard household power socket or in under 7 hours using a commercial power socket. In terms of cost and efficiency, for every 100 km the solar car would cost approximately $0.20 compared to the average $15 for conventional petrol powered cars.

In July 2014 The Sunswift team broke an FIA World Record which was overseen by the Confederation of Australian Motorsport, for the fastest electric vehicle capable of travelling 500 kilometres (310 mi) on a single battery charge. [4] The team beat the previous record 73 kilometres per hour (45 mph) – set in 1988 – with an average speed of 107 kilometres per hour (66 mph) over the 500-kilometre (310 mi) distance, which was done at the Australian Automotive Research Centre in Victoria. This record was not an exclusive Solar car record, but was open to any Electric vehicle weighing under 500 kilograms (1,100 lb). Consequently, for this record the Solar cells were disconnected from the electrical systems, and the car was allowed to only run on its lithium-ion battery pack.

The team is currently progressing with eVe's road legality status and plans to officially register eVe as Australia's first road legal Solar car. This would make eVe one of the only road legal solar cars in the world and the first to adhere to the strict Australian Design Rules.

Technical specifications for eVe
DimensionsLength: 4.5 metres (15 ft)
Width: 1.8 metres (5 ft 11 in)
Height: 1.1 metres (3 ft 7 in)
Weight430 kilograms (950 lb)
Solar Cells/Array4-square-metre (43 sq ft) array. All cells are monocrystalline silicon with an approximate efficiency of >23%
Seats2 made of carbon fibre, each with a 3-point safety harness
ChassisCarbon fibre monocoque with foam and an aramid honeycomb core
MotorsTwin, rear wheel, in hub, synchronous DC motors, both of which are brushless and have permanent magnets
Maximum speedAchieved: 132 kilometres per hour (82 mph)
Theoretical: 140 kilometres per hour (87 mph)
Battery Power16 kilowatt-hours (58 MJ)
TelemetryCustom Controlled Area Network (CAN) including GPS, barometric pressure, motor speeds, motor temperatures, tilt, and various voltages and currents

Sunswift IV (IVy) (2009–2011)

Sunswift IVy during the Guinness World Record speed attempt. Sunswift IVy.jpg
Sunswift IVy during the Guinness World Record speed attempt.
Sunswift IV (IVy) during the 2009 Global Green Challenge from Darwin to Adelaide Sunswift IV (IVy) during the 2009 Global Green Challenge from Darwin to Adelaide.jpg
Sunswift IV (IVy) during the 2009 Global Green Challenge from Darwin to Adelaide

As with eVe, IVy was built to compete in the World Solar Challenge, specifically for the 2009 race. However, unlike eVe, IVy raced as part of the Challenger Class and Challenger Class Silicon, ending up finishing 4th overall despite being the first silicon powered car across the line. Overall, the entire project took approximately 18 months and $250,000 to complete. On 7 January 2011, at the Royal Australian Navy airbase, HMAS Albatross, IVy broke the Guinness World Record for the fastest solar powered vehicle. Australian racing driver Barton Mawer brought IVy to a top speed of 88.5 kilometres per hour (55.0 mph), beating the previous record of 22 years by over 10 kilometres per hour (6.2 mph). The rules of the record required that IVy be powered solely by the sun and with the entire battery pack removed, the car weighed only 140 kilograms (310 lb). [5]

Technical specifications for Sunswift IV
DimensionsLength: 4.6 metres (15 ft)
Width: 1.8 metres (5 ft 11 in)
Height: 0.93 metres (3 ft 1 in)
Weight165 kilograms (364 lb)
Solar Cells/Array5.99-square-metre (64.5 sq ft) permanent array consisting of 397 A300's at 22% efficiency and 56 UNSW TopCells at 16% efficiency
SeatsNo conventional seat. The driver's compartment is part of the chassis
ChassisCarbon fibre monocoque with pre-preg carbon fibre and a nomex honeycomb, as well as a fibreglass canopy
MotorsSingle, rear wheel, brushless, synchronous DC motor with permanent magnets
Maximum speed110 km/h (88.7 km/h on solar alone)
Battery Power4.85 kilowatt-hours (17.5 MJ) at a voltage between 89.1 and 138.6 V
TelemetryCustom Controlled Area Network (CAN) including GPS, tyre pressure, motor speeds, motor temperatures, brake temperature, and various voltages and currents

Sunswift III (2005–2008)

Sunswift III UNSWSunswiftIII rear.jpg
Sunswift III

Sunswift III was designed for the 2005 WSC. Mechanical problems caused a crash before the race, and the car completed the course unofficially. In 2006, the mechanics were improved. In January 2007, Jaycar Sunswift III broke the world transcontinental record, completing the drive from Perth to Sydney in 5.5 days. In September, the team successfully completed the WSC in ninth place overall, and was also awarded the CSIRO technical innovation award, out of an initial field of 41 international entrants. The same year, the Sunswift team was awarded the 2007 Engineers Australia Engineering Excellence Award for Education and Training.

Technical specifications for Sunswift III
DimensionsLength: 6.0 metres (19.7 ft)
Width: 2.0 metres (6 ft 7 in)
Height: 0.9 metres (2 ft 11 in)
Solar Array11.5-square-metre (124 sq ft) of 20% efficient solar cells
Power output of 1.8 kilowatts (2.4 hp)
ChassisCarbon fibre monoconque
Battery2.5 kilowatt-hours
Maximum Speed120 km/h
Weight220 kilograms (490 lb)

Sunswift II (1998–2005)

UNSW Sunswift II UNSWSunswiftII.jpg
UNSW Sunswift II

Between 1997 and 2003, the team developed, refined and raced four versions of UNSW Sunswift II. In 2000-2001, the team embarked on the TopCell project to manufacture buried contact solar cells to construct a new solar array. This makes the UNSW SRT the first and only team to have made their own solar cells. Along the way, the team achieved a new world record efficiency for this type of solar cell. The remaining cells on UNSW Sunswift II are the world's highest efficiency "PERL" silicon solar cells, made at UNSW. The team also pioneered a cell encapsulation technique which allowed the moulding of solar panels to the curved shape of the car.

Technical specifications for Sunswift II
DimensionsLength: 4.4 metres (14 ft)
Width: 2.0 metres (6 ft 7 in)
Height: 0.9 metres (2 ft 11 in)
Weight180 kilograms (400 lb)
Solar Array8-square-metre at 19.5% efficiency

BP "Saturn" cells, laminated using epoxy resins and fibreglass
Power output ~1 kilowatt (1.3 hp)

ChassisChromoly space frame with structural carbon fibre seat
MotorUNSW/CSIRO developed electric wheel motor
Maximum output 3 kilowatts (4.0 hp)
SuspensionAluminium double wishbone front trailing arm and rear Ohlins Motorcycle shock absorbers
Battery102 Sony Lithium Ion Batteries
Total weight 30 kilograms (66 lb)
Battery Power3 kilowatt-hours (11 MJ) at 20 V
Maximum Speed120 km/h
TelemetryFluke Hydra data logger/radio modem

Sunswift I (1996)

UNSW Sunswift I Solarcar with crew. Sunswift I with crew.jpg
UNSW Sunswift I Solarcar with crew.

The original Sunswift vehicle was purchased from the Aurora Vehicle Association in 1996. The car, Aurora Q1, was significantly upgraded and improved by the UNSW SRT and renamed Sunswift, under team leader Byron Kennedy. A new motor and controller, roll cage, chassis and batteries were added. Sunswift I then went on to race in the 1996 World Solar Challenge. The car was still a competitive entry despite its age, placing 9th out of over 46 entries. The experience gained from racing Sunswift I inspired the development of Sunswift II starting in 1997.

Technical specifications for Sunswift I
Total cost$95,000 + $200,000 for purchase of the Aurora Q1
DimensionsLength: 4.46 metres (14.6 ft)
Width: 2.0 metres (6 ft 7 in)
Height: 1.01 metres (3 ft 4 in)
Weight255 kilograms (562 lb)
Solar Cells/Array7.88-square-metre (84.8 sq ft) permanent array (1923 cells). All cells were PERL mono (FZ) silicon with an average efficiency of 18.5%
ChassisAluminium rigid A-frame/glass fibre reinforced Nomex honeycomb (upper). Carbon fibre reinforced Nomex honeycomb (lower).
MotorT-Flux TF406 permanent magnet DC, Brushless
Maximum speedExperimental: 63 kilometres per hour (39 mph)
Theoretical: 70 kilometres per hour (43 mph)
Battery58 Gates Cyclone-G12C Pb/acid cells in series
Battery Power3 kilowatt-hours (11 MJ) at 116 V

Achievements

YearRecord
1996 World Solar Challenge – Sunswift finished 9th out of 46 entries. This was the University's first entry in a solar car event amongst the prestigious and competitive entries from Honda Motors Corporation, the Swiss entry from Biel, and Mitsubishi Materials Corporation.
1999 NRMA Transcontinental Record Attempt – with the car NRMA Sunswift II completed 4,012 kilometres (2,493 mi) in ten days, despite five days of bad weather. Even though the record of 8½ days was not broken, the attempt was still regarded to be a success with $2.4 million worth of publicity generated.
1999CitiPower SunRace – three days after completing the Perth-Sydney record attempt the team entered this event. NRMA Sunswift II obtained third place in a highly competitive field of five entries, proving the car's reliability and the team's dedication after five continuous weeks on the road.
1999NRMA Sunswift II participated in a trade exhibition in Taipei, on request from the Federal Government.
1999World Solar Challenge – NRMA Sunswift II finished a respectable 18th out of 48 international entries.
2001World Solar Challenge – UNSW Sunswift II was the 11th car to cross the line.
2002SunRace – 2nd Place
2003SunRace – 2nd Place
2005World Solar Challenge – UNSW Sunswift III was the 9th car (and the first with silicon solar cells) to cross the line, arriving in 5 days.
2007 Jaycar Sunswift III broke the world record for a solar car journey from Perth to Sydney. The team finished the journey in 5.5 days, breaking the previous record by 3 days.
2007World Solar Challenge – Jaycar Sunswift III finished 4th in the Adventure class and 9th overall at 4:11 pm on 26 October. The team was awarded with the prestigious Freescale Technical Innovation Award for the high efficiency of the vehicle.
2007The UNSW Solar Racing Team was awarded the Engineers Australia Engineering Excellence Award, for education and training.
2009Global Green Challenge (World Solar Evolution) – Sunswift IV finished 1st in the Silicon Challenge Class and 4th overall at 3:08 pm on 29 October.
2011Guinness World Record: Fastest Solar Powered Vehicle: 88.8 kilometres per hour (55.2 mph)
2011World Solar Challenge – Sunswift IVy finished 1st in the Production Challenge Class and 6th overall
2013World Solar Challenge – Sunswift eVe Line Honours and 3rd overall in Cruiser Class, including a top speed of 128 kilometres per hour (80 mph)
2014FIA Land Speed Record – Sunswift eVe breaks the record for the fastest electric car over 500 kilometres (310 mi), with an average speed of 107 kilometres per hour (66 mph). [6] The previous record of 73 kilometres per hour (45 mph) was set in 1988
2015World Solar Challenge – Sunswift eVe finished 3rd across the line and 4th overall.
2018Guinness World Record – Lowest Energy Consumption Driving Trans-Australia (Perth to Sydney) – Electric Car [7]
2023World Solar Challenge - Sunswift 7 finished 1st in Cruiser Class [2]

See also

Related Research Articles

<span class="mw-page-title-main">World Solar Challenge</span> Solar-powered car race event

The World Solar Challenge (WSC), since 2013 named Bridgestone World Solar Challenge, is an international event for solar powered cars driving 3000 kilometres through the Australian outback.

<span class="mw-page-title-main">Solar vehicle</span> Electric vehicle powered by solar energy

A solar vehicle or solar electric vehicle is an electric vehicle powered completely or significantly by direct solar energy. Usually, photovoltaic (PV) cells contained in solar panels convert the sun's energy directly into electric energy.

Shell Eco-marathon is a world-wide energy efficiency competition sponsored by Shell. Participants build automotive vehicles to achieve the highest possible fuel efficiency. There are two vehicle classes within Shell Eco-marathon: Prototype and UrbanConcept. There are three energy categories within Shell Eco-marathon: battery-electric, hydrogen fuel cell, and internal combustion engine. Prizes are awarded separately for each vehicle class and energy category. The pinnacle of the competition is the Shell Eco-marathon Drivers' World Championship, where the most energy-efficient UrbanConcept vehicles compete in a race with a limited amount of energy.

<span class="mw-page-title-main">Nuna</span> Name of several race cars that have won the World Solar Challenge

Nuna is the name of a series of crewed solar powered race cars that have won the World Solar Challenge in Australia seven times: in 2001, 2003, 2005, 2007, 2013, 2015 and 2017. The vehicles are built by students who are part of the "Brunel Solar Team" at the Delft University of Technology in the Netherlands, sponsored by Brunel.

<span class="mw-page-title-main">American Solar Challenge</span> Solar car race

The American Solar Challenge (ASC), previously known as the North American Solar Challenge and Sunrayce, is a solar car race across the United States. In the race, teams from colleges and universities throughout North America design, build, test, and race solar-powered vehicles in a long distance road rally-style event. ASC is a test of teamwork, engineering skill, and endurance that stretches across thousands of miles of public roads.

<span class="mw-page-title-main">University of Calgary Solar Car Team</span> Solar car racing team at the University of Calgary

The University of Calgary Solar Car Team is a multi-disciplinary student-run solar car racing ("raycing") team at the University of Calgary, based in Calgary, Alberta, Canada. It was established to design and build a solar car to compete internationally in the American Solar Challenge (ASC) and the World Solar Challenge (WSC). The team is primarily composed of undergraduate students studying Engineering, Business, Science, Arts and Kinesiology. The mission of the University of Calgary Solar Car Team is to educate the community about sustainable energy and to serve as an interdisciplinary project through which students and faculty from various departments can collaborate in supporting sustainable energy.

<span class="mw-page-title-main">Stanford Solar Car Project</span>

The Stanford Solar Car Project (SSCP) is a student group at Stanford University that designs, builds, tests, and races solar-powered vehicles. The SSCP, a student-run, donation-funded organization, has been building and racing solar-powered vehicles since 1986. It has competed and placed at The World Solar Challenge, the Global Green Challenge, and American Solar Challenge.

<span class="mw-page-title-main">University of Minnesota Solar Vehicle Project</span> University solar vehicle team

The University of Minnesota Solar Vehicle Project, or UMNSVP, is a team of undergraduate students from the University of Minnesota that designs and constructs solar-powered cars. In its 31 years, it has established itself as one of the world's top solar racing teams, and the top Cruiser/Multi-Occupant Vehicle team in the Western Hemisphere, with top-two finishes in eighteen of thirty-four events entered.

Durham University Solar Car, formerly Durham University Electric Motorsport, is a student-run team in the United Kingdom that designs and constructs solar powered cars to compete in international competitions. It is the longest running solar car team in the UK and is financed entirely by third party donations and sponsorship.

The Sunraycer was a solar-powered race car designed to compete in the World Solar Challenge, the world's first race featuring solar-powered cars. The Sunraycer was a joint collaboration between General Motors, AeroVironment, and Hughes Aircraft.

<span class="mw-page-title-main">Solar car</span> Type of vehicle powered by solar energy

A solar car is a solar vehicle for use on public roads or race tracks. Solar vehicles are electric vehicles that use self-contained solar cells to provide full or partial power to the vehicle via sunlight. Solar vehicles typically contain a rechargeable battery to help regulate and store the energy from the solar cells and from regenerative braking. Some solar cars can be plugged into external power sources to supplement the power of sunlight used to charge their battery.

Solar car racing refers to competitive races of electric vehicles which are powered by solar energy obtained from solar panels on the surface of the car. The first solar car race was the Tour de Sol in 1985 which led to several similar races in Europe, US and Australia. Such challenges are often entered by universities to develop their students' engineering and technological skills, but many business corporations have entered competitions in the past. A small number of high school teams participate in solar car races designed exclusively for high school students.

<span class="mw-page-title-main">Midnight Sun Solar Race Team</span>

The Midnight Sun Solar Rayce Car Team is a Canadian solar car race team affiliated with the University of Waterloo of Waterloo, Ontario. Founded in 1988, the Midnight Sun team is a student-run organization which designs and builds a solar vehicle every two to three years to compete in two solar challenges; the World Solar Challenge, held in Australia, and the American Solar Challenge, held in the United States.

<span class="mw-page-title-main">UNSW School of Computer Science and Engineering</span>

The UNSW School of Computer Science and Engineering (CSE) is part of the UNSW Faculty of Engineering and was founded in 1991 out of the former Department of Computer Science within the School of Electrical Engineering and Computer Science. It is the highest ranked and largest School of its kind in Australia. The academic staff have research focus in areas such as Artificial Intelligence, Biomedical Image Computing, Data Knowledge, Embedded Systems, Networked Systems and Security, Programming Languages and Compilers, Service Oriented Computing, Theoretical Computer Science and Trustworthy Systems.

The Aurora Vehicle Association is a group of volunteers who are dedicated to achieving and demonstrating extreme efficiency in transport. Aurora was started in 1980 by building high-fuel-efficiency petrol-powered vehicles. Between 1983 and 1985 Aurora held the world record for fuel economy at 1808 km per litre. In 1987, when Hans Tholstrup devised the first trans-Australian World Solar Challenge, Aurora turned to solar car development and has been a contestant in every World Solar Challenge and has achieved 1 win, 4 second places, 1 third place, 1 fifth place, 1 sixth place and 1 crash.

<span class="mw-page-title-main">Solar bus</span>

A solar bus or solar-charged bus is a bus that is powered exclusively or mainly by solar energy. Solar-powered bus service is referred to as a solar bus service. The use of the term "solar bus" normally implies that solar energy is used not only for powering electric equipment on the bus, but also for the propulsion of the vehicle.

<span class="mw-page-title-main">PowerCore SunCruiser</span> Motor vehicle

The PowerCore SunCruiser is a solar-powered road vehicle. It was created at the Bochum University of Applied Sciences to compete at the World Solar Challenge in 2013. The PowerCore SunCruiser is the fifth vehicle built by the University of Bochum and categorized as an EC vehicle class L7e, which includes full road approval. The car was presented to the public on 25 July 2013. It offers space for three persons, can reach a top speed of over 100 km/h, and is driven by two wheel-hub motors in the back wheels. Its maximum power is 8.5 kW. The vehicle's empty weight is around 340 kg, of which the batteries take around 63 kg.

<span class="mw-page-title-main">Stella (solar vehicles)</span> Solar-powered family car

Stella and its successors Stella Lux, Stella Vie and Stella Era are a series of solar racing family cars, built for the World Solar Challenge in Australia, sofar winning its Cruiser Class all four times it was held – in 2013, 2015, 2017 and in 2019. Stella is considered the world’s first solar-powered family car and was given the 'Best Technology Development' Award at the 8th annual Crunchies in San Francisco in 2015. Being the only competing vehicle with a license plate, the road registration of Stella contributed to the winning score in the races. The vehicles are designed and built by "Solar Team Eindhoven" (STE) — some 26 students of different faculties of the Eindhoven University of Technology (TU/e) in the Netherlands. The group have set up a non-profit foundation to promote their concepts for practical solar vehicles for adoption on a broader scale.

<span class="mw-page-title-main">Sonnenwagen Aachen</span> German solar car development project

Sonnenwagen Aachen is a current project by students from RWTH Aachen University and FH Aachen for the development and construction of a solar car, to participate in the World Solar Challenge in Australia. The solar car race with a length of 3022 km from Darwin in Northern Territory to Adelaide in South Australia is known to be the longest solar car race in the world and has celebrated its 30th anniversary in October 2017.

References

  1. "EV record breakers! Sunswift 7 goes 1000km on a single charge in world's best time". UNSW Newsroom. 19 December 2022. Retrieved 12 November 2023.
  2. 1 2 "Sun sets on 2023 challenge – Australia's Sunswift top cruiser | World Solar Challenge 2023". worldsolarchallenge.org. Retrieved 12 November 2023.
  3. "World Solar Challenge 2023". worldsolarchallenge.org. Retrieved 12 November 2023.
  4. Crozier, Ry (14 October 2014). "It's official: Electric car world record smashed by UNSW Sunswift".
  5. "Aussie car breaks a world speed record". AAP. 7 January 2011. Retrieved 7 January 2011.
  6. "Motorsport Australia".
  7. "UNSW student solar car sets new efficiency world record". 8 December 2018.
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.