Terry Manja
FAQ
FAQ
Terry Manja
THE INCREDIBLE DROP OF RAIN

Our blue planet’s hydrologic cycle has three main components (evaporation, condensation, and precipitation). Precipitation can be either liquid (drizzle, rain) or solid (snow, hail). The universally accepted definition of rain is that it is a form of liquid precipitation that comprises drops greater than 0.5 mm in diameter. Liquid precipitation less than 0.5 mm diameter is classified as drizzle.

During a given storm event, rainfall comprises an array of drop sizes. Storms of high intensity can carry the large rain drops (5 mm or larger). Large drops of rain (greater than 6 mm diameter) loose stability and disintegrate while travelling through the atmosphere. It is interesting to note that terminal velocities of raindrops are approximately 10 meters per second (36 km/hr) for the largest drop size and around 2 meters per second (7 km/hr) for the smallest drop of rain.

The interaction between the particles within the rain drop and the surrounding environment (surface tension) keeps the rain drops spherical; however, rain drops greater than 2 mm diameter have greater forces acting on them which result in them assuming a flatter shape. For rain drops with a diameter greater than 6 mm, the excessive aerodynamic forces result in their undersurface becoming concave. Eventually, the large raindrop assumes a bubble shape and bursts into numerous micro-droplets.

As mentioned above, the terminal velocity of large raindrops can approach 36 km/hr. Therefore, it is not difficult to imagine the resultant impact of a raindrop as it exerts significant erosive and compaction forces on bare soil. The damaging impact of raindrops can be mitigated through vegetation or other appropriate erosion protection measures and techniques. Typically, varying percentages of the total rain volume infiltrate into the soil (unless the soil is sealed by a synthetic erosion control blanket or an impermeable liner), evaporate and transform into surface runoff. The surface runoff causes the secondary damage to unprotected soil by dislodging and washing away nutrient rich topsoil. Excessive runoff volume can also cause drainage problems by flooding of the low-lying areas.

The two basic flow patterns for runoff are sheet flow and concentrated flow. Sheet flow occurs when runoff flows overland in a uniform sheet pattern whereas concentrated flow occurs when runoff flows through defined pathways (rills, catch drains, drainage channels, waterways etc.). Both sheet and concentrated flow present a significant risk of erosion and scour to unprotected surfaces.

In case of sheet flow, a layer of organic matter and nutrient rich topsoil (dislodged by rain drop impact) is carried downstream in an even manner resulting in significant soil loss. During a storm event, several tons of soil can be lost due to sheet erosion. Sheet erosion is common in areas which have poor soil structure and / or are not managed as per the established principles of erosion and sediment control.

Runoff on uneven surfaces or areas where soils are dispersive can result in rill erosion. Rill erosion occurs when channelized runoff flows in an uncontrolled manner. These small channels can transform into larger gullies. Rill erosion also has a tremendous potential to move soil material in a given storm event as it exposes the underlying subsoil which are often significantly more unstable than the topsoil.

It is not uncommon to observe sheet and rill erosion on the same site. Together they can transport several hundred tons of material in a single storm event and result in breach of license conditions, penalty infringement notices, significant clean-up costs and reputation damage. The cumulative harm resulting from rain drop impact, sheet erosion and rill erosion can be mitigated through effective source control measures and techniques designed by an appropriately qualified professional in erosion and sediment control

THE INCREDIBLE DROP OF RAIN

FAQ

What does Nyasha Gardens do:

  • Nyasha specializes in large-scale revegetation, dust suppression and erosion control projects nation-wide. We service many industries including mining, civil and infrastructure amongst others.

Are your products safe for the environment?

  • All product ingredients used in our solutions are environmentally compliant, scientifically analysed and tested before use. Safety for our team and the environment in which we operate is our upmost priority

What seeds do you use for revegetation?

  • Depending on project requirements, we offer both native seeds and a wide selection of introduced species as part of a tailored revegetation plan. A full site analysis by our highly experienced soil scientist will provide the optimal seed advice possible for your project.

Are you fully mine compliant?

  • Yes. Our fleet of state of the art HydroTruck equipment is fully mine specified for the highest level of quality and safety requirements. Our team of highly trained technicians each hold relevant certifications to operate on mine sites safely and effectively.

What is a Supply Apply Guarantee?

  • Due to the extremely high level of care and attention taken to understand each and every project, we can offer a site-specific solution with a guaranteed outcome to suit your project requirements

What preparation is needed before spraying?

  • Every one of our projects starts and finishes with a scientific approach. Depending on the service you are receiving, topsoil may need to be applied on top of existing soil and raked to ensure that the soil is loose, to encourage and support rapid growth. If your project involves hydromulching, a soil analysis may be undertaken and interpreted before revegetation works commence. Such analysis will determine the properties of the soil to ensure we get the best strike rate and increased longevity of seedlings. We will provide you with professional and credible advice about how to set up your site for success the first time.

How long does it take to revegetate land?

  • The time it takes for vegetation to grow and be sustainable is determined by the regional rainfall, nutrient density of the soil and the amount of sunlight for that area. Typically, you can expect to see growth after 2 to 3 weeks in ideal conditions. For areas that have depleted soils which cannot sustain growth, we offer a cost-effective topsoil alternative that is hydraulically applied to help rejuvenate the soil using a tailored blend of micro-nutrients,

    minerals, and fertilisers.

Do you only work with mining and civil?

  • Not at all, we provide solutions for many industries such as the rail industry, defence, energy and many more.

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THE INCREDIBLE DROP OF RAIN

THE INCREDIBLE DROP OF RAIN

Our blue planet’s hydrologic cycle has three main components (evaporation, condensation, and precipitation). Precipitation can be either liquid (drizzle, rain) or solid (snow, hail). The universally accepted definition of rain is that it is a form of liquid precipitation that comprises drops greater than 0.5 mm in diameter. Liquid precipitation less than 0.5 mm diameter is classified as drizzle.

During a given storm event, rainfall comprises an array of drop sizes. Storms of high intensity can carry the large rain drops (5 mm or larger). Large drops of rain (greater than 6 mm diameter) loose stability and disintegrate while travelling through the atmosphere. It is interesting to note that terminal velocities of raindrops are approximately 10 meters per second (36 km/hr) for the largest drop size and around 2 meters per second (7 km/hr) for the smallest drop of rain.

The interaction between the particles within the rain drop and the surrounding environment (surface tension) keeps the rain drops spherical; however, rain drops greater than 2 mm diameter have greater forces acting on them which result in them assuming a flatter shape. For rain drops with a diameter greater than 6 mm, the excessive aerodynamic forces result in their undersurface becoming concave. Eventually, the large raindrop assumes a bubble shape and bursts into numerous micro-droplets.

As mentioned above, the terminal velocity of large raindrops can approach 36 km/hr. Therefore, it is not difficult to imagine the resultant impact of a raindrop as it exerts significant erosive and compaction forces on bare soil. The damaging impact of raindrops can be mitigated through vegetation or other appropriate erosion protection measures and techniques. Typically, varying percentages of the total rain volume infiltrate into the soil (unless the soil is sealed by a synthetic erosion control blanket or an impermeable liner), evaporate and transform into surface runoff. The surface runoff causes the secondary damage to unprotected soil by dislodging and washing away nutrient rich topsoil. Excessive runoff volume can also cause drainage problems by flooding of the low-lying areas.

The two basic flow patterns for runoff are sheet flow and concentrated flow. Sheet flow occurs when runoff flows overland in a uniform sheet pattern whereas concentrated flow occurs when runoff flows through defined pathways (rills, catch drains, drainage channels, waterways etc.). Both sheet and concentrated flow present a significant risk of erosion and scour to unprotected surfaces.

In case of sheet flow, a layer of organic matter and nutrient rich topsoil (dislodged by rain drop impact) is carried downstream in an even manner resulting in significant soil loss. During a storm event, several tons of soil can be lost due to sheet erosion. Sheet erosion is common in areas which have poor soil structure and / or are not managed as per the established principles of erosion and sediment control.

Runoff on uneven surfaces or areas where soils are dispersive can result in rill erosion. Rill erosion occurs when channelized runoff flows in an uncontrolled manner. These small channels can transform into larger gullies. Rill erosion also has a tremendous potential to move soil material in a given storm event as it exposes the underlying subsoil which are often significantly more unstable than the topsoil.

It is not uncommon to observe sheet and rill erosion on the same site. Together they can transport several hundred tons of material in a single storm event and result in breach of license conditions, penalty infringement notices, significant clean-up costs and reputation damage. The cumulative harm resulting from rain drop impact, sheet erosion and rill erosion can be mitigated through effective source control measures and techniques designed by an appropriately qualified professional in erosion and sediment control

DRONE TECHNOLOGY: PROVIDING REVOLUTIONARY ENVIRONMENTAL SOLUTIONS

With global populations systematically jumping on board, Nyasha has never been far behind in adapting cutting edge approaches to company operations. Inherently the ideology presented in the form of an unmanned aerial vehicle, more commonly referred to as a drone, has become an innovation and concept no longer fit for the future. Instead streamlined into various industries to help improve systematic approaches to professional procedures.   Nyasha is dedicated to maintaining a market-leading position in the environmental solutions sector, with an upwards of 25 years of experience in providing superior dust suppression, erosion control and revegetation projects across some of the most complex issues in environmental projects Australia wide. The foundation of our approach is underpinned by innovation and cutting edge technologies that enable successful environmentally sustainable solutions.   Due to the large scope of projects that we undertake regularly, we must continually keep up to date with the large spectrum of highly sophisticated and effective equipment currently within our asset line-up. It is not by choice but by necessity that we maintain our market-leading position, not based on status, but pure retrospect that our customers deserve unprecedented project results.   Since the implementation of drones into our equipment range, we have been able to significantly underpin our client projects with greater detail of information, assisting in time and cost efficiency for solution-driven results. We utilise this technological platform as a basis for all of our company operations, from an initial assessment through to post-application reviews.   Along with the precision and accuracy of the information that is obtainable upon each drone mission, as listed below there is a substantial list of other benefits that support our need to have them as a core equipment apparatus in our company procedures  

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