Technology

Application

• sealing, renovation and regeneration of corroded concrete and brick structures,
• drying of old and new concrete and brick structures,
• protecting buildings and construction sites from the penetration of ground water and moisture,
• structural repairs of bridges, roads and tunnels,
• implementation of protective coatings,
• restoration of monuments.

Properties

• waterproof up to 14 atm at 10 mm layer,
• 100% resistance to effects of fresh, sea and ground water,
• regenerates and stops corrosion in old concrete and brick structures by penetrating into the depth of the presence of moisture,
• reproduces the strong properties of concrete and bricks increasing their resistance to compression and crushing,
• reduces the cost and time of realising the investment,
• the majority of the works are carried out from within the building and there is no need to dig up the foundations,
• is excellently resistant to aggressive environments (moisture, fire to 700°C, acids of PH 3-12, oils, sea water, frost),
• reduces heat loss and the transfer of heat,
• creates an environment which is hostile to the growth of mould and fungi,
• protects from the corrosion of reinforcement structures and has corrective action on corroded steel,
• can be used in negatives temperatures (up to -5°C),
• Increases the density of concrete and resistance to cracking,
• Surfaces made with Oxydtron Technology can be tiled, plastered, fused or painted on directly,
• possesses international approvals and certificates.

Key parameters

• Average compressive strength above 40.0 N / mm2,
• Average bending strength of more than 8.0 N / mm2,
• Adhesion after 7 days above 1.2 N / mm2; after 14 days above 1,7 N/mm2; after 28 days above 3,8 N/mm2,
• Adhesion to reinforcing steel (study on a rod of diameter 14 mm): smooth above 8 MPa - PB-TM-X2 procedure; ribbed above 10 MPa - PB-TM-X2 procedure,
• Wear resistant grade: A9 - 6,1 ± 0,1 cm3/cm2 according to PN-EN 13813:2003,
• Resistance to sulphates - meets the requirements according to Badao nr: 37938-003/EA/2009 for the Paks Atomic Power Plant in Hungary,
• Resistance to the absorption of chloride ions - meets the requirements according to Badao nr: 37938-003/EA/2009 for the Paks Atomic Power Plant in Hungary,
• Tensile strength of 3.45 N, Young’s module - 23,2 Gpa.
• Waterproof up to 14 atm at 10 mm layer.

Ecology

Oxydtron Technology can be applied:

• in food establishments,
• in equipment which is used for food production or comes in contact with food,
• in tanks or containers which come in contact with standing drinking water, as well as pipelines and ducts for flowing drinking water.

Oxydtron technology perfectly fulfils its purpose in the repair of sewage treatment plants and sewage systems. It uses completely inorganic based on Portland cement and mineral fillers.

• It possesses a European hygienic certificate.
• Working with it does not require any additional measures in the field of health and safety.
• It is non-toxic, odourless, non-flammable and non-explosive.
• There is a possibility of mixing the mortar and creating concrete with the addition of seawater.
• This is one of the few materials approved for the repair of concrete in nuclear power plants.

Advantages

Oxydtron technology:

• can be used directly on wet and damp structures
• repairing is possible from the inside , no need to dig out the foundation
• reduces execution time and costs of the investment

How it operates

Thanks to its unique properties OXYDTRON Technology has very wide applications both in newly built and already functioning buildings. It is ideal for use in extreme conditions such as sewage treatment plants, airports, roads and bridges. This technology has been proven to work over the last 10 years in Europe, Asia and North America.

Oxydtron Mineral Cement Technology is a new school of engineering thought, of high quality and low cost, as well as increasing the longevity of buildings.

Nano-Technology

Molecular concrete and corrosion resistant mortars manufactured using OXYDTRON technology are world-class material engineering solutions that reach the atomic structures, rebuilding the molecular relationships of traditional building materials, giving them new, noble qualities. They are completely new materials, only by appearance resembling traditional concrete and mortar. At first glance, they do not differ at all. However, they behave differently.

Oxydtron reacts actively with thermodynamically unstable compounds on the surface of concrete or brick structures as well as on the boundaries of crystal grains and fillers in so-called interfacial zones, creating new thermodynamically stable structures.

It reproduces the strength properties of masonry and concrete structures, improves them by increasing their resistance to cracking, penetrates deep into the structure stopping corrosion processes, and hardens the construction against the effects of aggressive chemicals in the process of environmental impact. Penetration of the inside takes place in every direction and ends where there is no medium, that being water.

It is an inorganic compound based on Portland cement and capillary mineral fillers, ensuring watertight concrete, cement-sand mortars and other porous materials (e.g. old bricks).

A short introduction to concrete created from nano-cement Oxydtron

Zoltán J. Kiss, independent quantum energy researcher

The binding of the wet concrete made from nano-cement Oxydtron (hereinafter referred to as Oxydtron) is close to an equilibrium in its structural state. The structure of the unified elementary process at equilibrium has exactly the same amount of “consumed” energy as “produced” energy. Concrete made from nano-cement Oxydtron is characterised by this state.

The structure of concrete using Oxydtron allows for the integrated binding close to equilibrium because:

• the mineral components (listed below) contained within it are connected with lots of connections;
• the greater the number of selected mineral components the stronger the binding, as the elementary internal workings are far-reaching;

SiO2 (silicon dioxide) and CaCO3 (calcium carbonate) mixed with water are able to form concrete and the consolidated binding will be solid. However, it can easily be penetrated by liquids and react and thus cannot be referred to as stable - even if during production the plain cement contains the necessary calcium aluminates containing iron.

For really well binding concrete which is resistant to not only the effects of atmospheric conditions but also resistant to the effects of water, fire and chemical compounds, which protects from the ozone and is considered stable in other adverse conditions, requires a structure such as Oxydtron. The multi-ingredient and close to equilibrium state has the necessary passivity due to the characteristics of the internal structure.

Water initiates the process whilst the far-reaching system of elementary connections of Oxydtron, containing many mineral components, creates the bond.

The Oxydtron concrete composition contains the first 22 most active elements of the Periodic Table of Elements for elementary co-operation in the primary process, whose “binding order” is as follows: Fe-Ti-Ca-K-Cl-S-Si-Al-Mg-Na-O-N-C-H.

The Oxydtron concrete mixed with water contains the following, co-operating with each other elementary groups:

• First category: O, N, H,
• Second category: Ca, S, Si, C,
• Third category: Fe, Ti, K, Cl, Al, Mg, Na.

Under the effect of water, the components within the minerals communicate externally and internally based on their ‘binding order’ and form a superstructure close to equilibrium.

There also is / was a certain state of equilibrium in the original structures of the co-operating minerals, but this state loosens as a result of the elementary communication and decays and the structure is formed anew. The basic principle of this process is that in place of the structure of the elementary mineral component communicating externally, a new component joins with a lower communication potency.

The key elements of communication are: Oxygen, Hydrogen, Calcium and Silicon. The strongest elementary processes which commence communication under the effect of water are Iron and Titanium. Integrating elementary communication lasts until the most optimal elementary equilibrium states are formed. The intense communication creates an internal conflict which is why the binding of concrete is accompanied by intense heat generation.

The proportion of the mineral components depends on the intensity of the elements taking part in the communication. Silica and calcium carbonate are present in the largest proportions whilst titanium dioxide and iron oxide in the smallest proportions.

Traditional concrete should have water poured over it so that the communicating elements form adequate strength. In traditional concrete the process of binding must again and again be induced with water.

In the case of concrete using Oxydtron the process is self-regulating, and though the pouring of water over it does not disrupt the process, the adequate bonds will form even without it as a large amount of components are “searching for their place” in the structure. The formation of the complete bond can take even a couple of weeks depending on the mass and shape of the structure. In the case of a concrete structure of higher mass, the temperature of the surface will fall to that of the surroundings more or less after a week, whereas the temperature within the inner regions of the concrete will remain higher for longer and the heat communicates with the surroundings through the surface.

The compressive strength of the most commonly used normal concrete is 42.5 Mpa. The equivalent compressive strength of nano-cement Oxydtron used in concrete Oxydtron is min. 75 Mpa.

Nano-cement Oxydtron is a good addition to construction and prevents the penetration of water into the concrete as the formation of the state close to equilibrium protects the structure. The external effect of water will not find a structural point enabling decay on the surface and those that it does find, it enters into a repelling conflict. This is why Oxydtron concrete is waterproof. Oxydtron concrete also provides protection from the impact of the ozone as it does not have free radical electrons to which extremely active ozone could adhere causing decay. Between the existing free radicals, the inner balance is so strong that these do not communicate but repel. Thus the structure or coating provides adequate protection from the effect of the ozone. Concrete made from nano-cement Oxydtron provides good thermal insulation as the resulting passive structure stops heat exchange between the inside and the outside.

The wide range of elementary components and the emerging communications from them allow the concrete made from Oxydtron to provide solutions for other, particular problems also.