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HURRICANE INDUSTRIAL TURBINE VENTILATOR
Widely recognised as the most efficient industrial ventilator available in the world today. Hurricane was the first industrial ventilator to incorporate vertical vane design which tests at University of Technology Sydney have shown to be superior in air handling capacity to the traditional horizontal vane design ventilators.
Hurricane is designed and manufactured in Australia for harsh operating conditions. It is suitable for industrial, commercial and community buildings, including schools. Throat sizes available include 100mm, 150mm, 300mm, 400mm, 450mm, 500mm, 600mm, 700mm, 800mm, and 900mm.
The wind driven Hurricane ventilator exhausts hot, stale air from buildings and allows it to be replaced at low level with fresh air at ambient temperature. The result is a much more pleasant and healthier working environment.
Meets the highest of standards
Manufactured from 505 grade aluminium, the Hurricane has been tested by Construction Research Laboratories Inc, Miami, Florida and withstood a continuous gusting wind of 240km/hr without damage. It has also passed the requirements of the Low Speed Dynamic Rain Penetration Test (3L/m at 57.4km/hr).
Special Features
- All aluminium construction.
- A varipitch base that suits all roof slopes to 45° for vent sizes up to 700mm. Ridge mounting or square to round bases available.
- Tandaco prepacked double row ball bearing system.
- Vertical vanes for improved torque at low wind speed.
- Large range of colours. Hurricane is available in an extensive range of colours including - Mill, Night Sky™, Woodland Grey™, Windspray®, Shale Grey™, Dune®, Paperbark™, Surfmist®, Classic Cream™, Pink Buff, Pale Terracotta, Claypot, Headland®, Manor Red™, Brown, Cottage Green™, Wilderness®, Sandbank, Bushland, Jasper, Ironstone, Blue Ridge, Plantation, Pale Eucalypt™, Stromboli, Deep Ocean®. (Click here for Colour Chart)
- Ten throat sizes.
- Cord, remote control, manual, or electric dampers available.
- A 15 year performance warranty.
The exhausted air is replaced with fresh air at ambient temperature, which is drawn into the building via low level louvres and doorways, thus providing vertical air movement, which is the most natural, efficient and predictable way to ventilate buildings.
Vertical air movement occurs due to lower density, warm air rising as it expands becoming more buoyant. As cool air, which is dense and therefore heavier, enters the building at low level it pushes the warm air upwards thus developing a convection current.
The rate at which warm air rises depends on two factors:
-
The temperature difference between the rising column of warmer air and the surrounding cooler air; and
-
The height through which the temperature difference is generated is called the “stack height”. This is the vertical distance between the point of entry of fresh air and the point of exhaust at the roof ventilators.
These two thermodynamic forces were used by early man to ventilate primitive buildings.
Early development of natural ventilation
The Indian Teepee is a classic example of structure employing these forces to ensure adequate ventilation by the provision of a doorway to allow entry of fresh air, and a hole at the top to exhaust stale air.
During the industrial revolution manufacturing buildings were frequently full of smoke, fumes
or steam.
The moist air condensed on the inside of the roof and precipitated onto the workers below, which led to the development of elementary ventilation devices in an attempt to overcome these problems.
These devices were either holes in the roof with some type of elevated covering to keep the weather out, or new styles of roof systems called Lantern or jack roofs.
They were very inefficient by modern standards as they allowed wind to enter on the windward side causing turbulence in the opening and preventing ANY exhaust of air from building.
The importance of wind
A well-designed turbine ventilator, like the Hurricane, takes advantage of the wind to create a positive flow through the throat of the ventilator.
The wind influences the performance of the ventilator in two ways:
-
As the wind approaches and strikes the ventilator, it jumps, creating an area of low pressure on the leeward side of the turbine, causing a continuous extraction of air from the building.
-
As the turbine rotates, the centrifugal forces associated with the rotation fling air outwards across the surface of the vanes. Replacement air is drawn into the throat of the ventilator from the building causing continuous ventilation.
The Hurricane will even rotate and exhaust in the absence of wind using thermal currents developed within the building.
The action of wind is an important factor in the development of calibrated natural ventilation devices and is the third factor or force used in the calculation of ventilation schemes to provide a given number of air changes per hour.
The application of louvres
The most common fault in the development of natural ventilation systems is the poor use of louvres. Air cannot be drawn out of a building unless openings in the perimeter walls allow replacement air to enter. Weatherproof louvres are designed for this purpose and should be considered for use whenever access openings such as doors and windows are inadequate or not evenly distributed.
Louvres should be located near to floor level so as to introduce fresh air at ambient temperature into the “Zone of Occupation”. Louvres installed high in the walls above the zone of occupation will virtually ‘short circuit’ the ventilation system resulting in no air movement in the zone of occupation.
A properly designed ventilation system requires exhaust outlets to be at the highest point possible and inlets for fresh air to be at the lowest point possible. This ensures that full advantage is taken of natural convection currents within the building.
It is important to note however, that the installation of louvres will not, on their own, provide adequate ventilation by the so-called action of “cross flow”. In reality this horizontal movement of air, or “cross ventilation”, does not happen.
A cardinal rule of natural ventilation is that you cannot expect airflow through an opening in which wind can blow. A lower pressure inside the building is required for fresh air to enter; this being created through a continuous extraction of air from roof mounted ventilators.
Therefore, it is essential that louvres be used in conjunction with roof mounted ventilators, such as the Hurricane, to ensure a positive flow of fresh air and create vertical air movement.
Efficient natural ventilation
No ventilation
Absence of roof ventilators prevents hot and stale air escaping building.
Minimum ventilation
Poorly designed ridge ventilators do not promote adequate ventilation or air movement in building
Good ventilation
Efficient turbine ventilators exhaust hot and stale air and provide a given number of air changes per hour for the building.
What can be achieved
The installation of Hurricane™ Turbine Ventilators on a building will ensure that air is exhausted at a predetermined rate provided that replacement air can enter the building.
The calculations to determine a ventilation scheme for a particular building take into account the volume of the building, the height of the ventilator above the inlet areas and the desirable temperature difference between ambient air and air at the point of discharge.
The formula used assumes a temperature difference of 10°C between inlet air at close to floor level and exhaust air at the ventilator. The incoming air would be at ambient temperature, which is the best that can be achieved without introducing cooling equipment. This air will rise as it is warmed by the various heat sources (persons, machinery, solar, etc.) and will leave the building a maximum of 10°C above ambient temperature. The zone of occupation from ground level to say 3 meters high would be maintained at close to ambient temperatures if the inlet areas are correctly positioned. Obviously, if air is introduced at a high level, much of the benefit of the ventilators will be lost in the zone of occupation.
It is safe to assume that with a well designed scheme, the zone of occupation of the building will be maintained at a comfortable temperature.
Dimensions:
| MODEL | A (mm) | B (mm) | ÆC (mm) | ÆD (mm) | Throat Area (m2) | Weight (kg) |
|---|---|---|---|---|---|---|
| H100 | 253 | 100 | 107 | 290 | 0.0090 | 1.3 |
| H150 | 283 | 125 | 155 | 332 | 0.0189 | 1.9 |
| H300 | 384 | 175 | 308 | 477 | 0.0745 | 3.7 |
| H400 | 389 | 205 | 410 | 561 | 0.1320 | 4.5 |
| H450 | 443 | 230 | 462 | 648 | 0.1676 | 6.2 |
| H500 | 459 | 265 | 511 | 702 | 0.2051 | 6.9 |
| H600 | 484 | 275 | 602 | 766 | 0.2846 | 9.1 |
| H700 | 556 | 320 | 705 | 876 | 0.3904 | 11.6 |
| H800 | 590 | 345 | 799 | 1003 | 0.5014 | 14.9 |
| H900 | 643 | 400 | 897 | 1096 | 0.6319 | 18.1 |
Tolerances: Size +/- 2mm
Weight +/- 0.1kg
Specifications:
| MATERIAL: | Turbine & throat: Aluminium 5005 H34 |
|---|---|
| Shaft: Aluminium 2011 T3 | |
| Dome & skirt: Aluminium 1200 H0 | |
| Brackets: Aluminium 6060 T591 | |
| Spider (H600-H900 only): Zinc passivate plated mild steel | |
| Shaft (H900 only): 303 Stainless Steel | |
| ROTATION BEARINGS: | Main bearing: Double row ball bearing - BWF30-119Z |
| Spider bearing (H600-H900 only): Single row ball bearing - UB204-12S | |
| WIND SPEED RATING: | 205.2km/h (57m/s) – Performance Level 1 |
| (As per AS 4740:2000 Natural ventilators-Classification and performance) |
Test Results by CSIRO:
- Dynamic Wind Load & Rain Penetration Testing to AS2428.1
- Fire-Rated Testing Of Hurricane™ H900FR to AS:1668.1-1998 4.8.1
Test Results by University of Technology - UTS:
Avalailable Colours:
-ALSO AVAILABLE IN MILLFINISH
-COLOURS ARE SHOWN AS AN APPROXIMATE GUIDE ONLY.
® COLOUR NAMES ARE REGISTERED TRADE MARKS OF BHP STEEL LIMITED.
™ COLOUR NAMES ARE TRADE MARKS OF BHP STEEL LIMITED.