DE202007002621U1 - Infrared radiator for use in e.g. medical field, has independent carbon fiber wires alloyed in silicon sheathing, where applied length of wire is computed based on heat formation and efficiency in infrared wave region - Google Patents

Abstract

The radiator has independent carbon fiber wires alloyed in silicon sheathing. The applied length of each fiber wire is computed according to the heat formation and efficiency in the infrared wave region and according to the light emittance. An epoxy mass is used as a heat conducting mass and a selective filter, and an aluminum layer is used as a reflection mirror. A housing made of C- steel is painted or coated from inside and outside.

Description

Of the Inventor presents an improved invention Technology for the construction of a heating system, creating a complex unit, the infrared ray generating element is. As an energy source here is a newly introduced on the market infrared radiation generating element used where the carbon fiber lines in Siliconummantelung alloyed are. The silicone layer is temperature resistant up to 400 ° C and protects the mikrodünnen Carbon fibers from external influences and breaks. The lines are used as an infrared radiation source, the is characterized by a purity and radiation efficiency of 99.9%.

Of the Manufacturer of carbon fiber lines supplies with its product range the Space Technology Center and medical supplies. The specially developed technology of assembly and manufacture the heat conduction plate enable Constructions of heating elements of any type, of flat plates up to columns or pyramids. The achieved values allow a very wide field of application and are economical, healthy as well as enormously energy-saving.

The Invention relates to improved production technology of heating elements, where all components strictly according to the effectiveness of infrared radiation are adjusted. This is especially true: laying the pipes, Application of an epoxy adhesive, mixture of components for manufacturing the radiation plate, reflection and temperature insulation layers, mechanical and electrical connections, surface coating and Spectral light source composition for light therapy is recognized.

The Field of application of the technology according to the invention extends generally on warming of surfaces, Inventory and the human and animal body. Of special interest are the effects of the radiated energy in the range of 2.5μm-3.5μm, which has a particularly good effect on the human body. Infrared radiation in the area penetrates deeply into the tissue. The effects, confirmed by medical examinations, have a positive influence on circulation (promotion of microcirculation in the body) and generally on the strengthening of the immune system. Particularly interesting applications arise from the effect on the environment of bacteria, viruses or molds. The entire sphere of influence has the inventor for optimized construction of the product for the special field of application in agriculture in particular of animal breeding moves.

State of technology

Numerous embodiments of flat panels using carbon fiber conduits or foils are known in the art. In general, they consist of films or heating wires, which are applied to a carrier layer or constructed in layers with housings. The publications: EP 0 899 777 B1 . DE 102 02 809 A1 . DE 196 52 614 A1 , WO 2006/054846 A1, WO 90/09085, WO 2006 / 037596A1 or DE 100 25 469 B4 describe constructions and applications in which the power of far-infrared radiation is exploited exclusively by the carbon fiber constructions used, such as pipes, foils or coating.

such Heaters are used, for example, in the heating of Living spaces and Buildings. The application met the task, the surface temperature of walls and inventory to a value that can be set as needed, to heat. The known heaters are designed so that the Energy generated in the carbon fibers as quickly as possible, without consideration is radiated on spent energy. The thermally conductive material is made in the described constructions mostly glued or pressed marble or other stone, paper, plastic and Fulfills only the task of a carrier for the heating elements to disposal to put the heat to store and derive or create a specific isolation.

at However, these constructions of the heating system, it has a disadvantage proved that the inserted carbon fibers exclusively in flat-shaped heat conducting plates can be used, wherein by milling the necessary ones Grooves for the lines are incorporated, resulting in very high production costs leads. Furthermore the infrared radiation is over the bandwidth of 1μm up to 100μm exclusively from emitted carbon fibers. The inserted elements The design cause no amplification of the radiation, since the used Materials partially absorb the rays. This will not be directional radiation achieved. The constructions affect the Infrared radiation and thus cause significant electricity costs.

further Tasks of the heat conduction plate and other components are not given in the prior art. In particular, the known heating systems as art objects and energy-saving objects only limited suitable.

For the heating of living spaces one therefore uses today usually heating systems that with fossil fuels (oil, gas, wood) or elektri schem electricity are operated. With predictable current and future fuel costs and maintaining the functionality of the system, conventional heating techniques can be considered very costly and time-consuming. It is a common fact that these sources will be exhausted in the near future. With today's wage and material costs, the costs for heating a detached house amount to about 2,000; Euro / year (excluding costs of acquisition and maintenance, which are about 10,000-20,000 euros for fossil fuels or geothermal energy).

task

In front In this background, the inventor has set the task, a improved technology of a mobile heating system under application to construct carbon fibers, without the existing state to include existing disadvantages of the technique. Furthermore the system is universally applicable and in particular for cost-effective warming of living spaces, Buildings, in animal breeding and heat therapy used. The technology is on selected products with the additional health-giving Element of recognized light therapy associated in different Forms composed with our objects. Together with the health-promoting effect the infrared rays that are in our objects in the area 2.5μm to 3.5μm, we can the invention of the state of the art as the most advanced describe. Particularly noteworthy is that the heater as a mobile system is constructed, which can also be used as a supplementary heating.

• – Die Länge der Kohlefasern ist nach der Wärmebildung und Effizienz im Infrarotwellenbereich entsprechend der Strahlungsdichte berechnet, d.h. abhängig von der Größe des Heizelements wird die maximale Länge der Leitungen angebracht, die die Wärme- und Strahlungsbedingungen erfüllt (4.).
• – Drei bis sechs unabhängige Strahlungskreise (4 Pkt. 2) sorgen für optimale und perfekte Verteilung der Strahlung auf der Oberfläche und im Raum.
• – Es befindet sich eine Schicht Epoxidmasse auf der Gehäuseinnenseite (4. Pkt.2 und 2. Pkt.2)
• – Kohlefaserleitungen sind auf die Epoxidmasse verlegt (4. Pkt.2)
• – Eine weitere Schicht der Epoxidmasse gewährleistet die Thermoleitung zur Wärmeleitplatte (4. Pkt.2 und 2. Pkt.4.)

According to the invention this object is achieved as follows:

• - The length of the carbon fibers is calculated according to the heat density and efficiency in the infrared wave range according to the radiation density, ie depending on the size of the heating element, the maximum length of the lines is applied, which meets the heat and radiation conditions ( 4 .).
• - Three to six independent radiation circuits ( 4 Pts. 2 ) ensure optimal and perfect distribution of radiation on the surface and in the room.
• - There is a layer of epoxy compound on the inside of the housing ( 4 , Pts. 2 and 2 , Pts. 2 )
• - Carbon fiber cables are laid on the epoxy mass ( 4 , Pts. 2 )
• - Another layer of epoxy compound ensures the thermal conduction to the heat conducting plate ( 4 , Pts. 2 and 2 , Pts. 4 .)

• – Die Zusammensetzung der Wärmeleitschicht besteht nach wissenschaftlichen Ergebnissen, wie zahlreiche Proben ergeben haben, aus folgenden chemischen Verbindungen: Al₂O₃, SiO₂, Fe₂O₃, CaO, MgO, C. Die Mischung ist prozentual so angepasst worden, dass die Eigenschaften der Mischung folgende Eigenschaften aufweisen:
• – Eine Dichte von bis 3,5g/cm³
• – Schnelle Temperaturerwärmung des gesamten Körpers
• – Die Mischung und Dichte, sowie die energetischen Reaktionen im Kern des Gebildes, beeinflussen die energetische Effektivität der Platte. Durch das physikalische Prinzip der orbitalen Verteilung der Elektronen und somit der Ligandenfeldtheorie ist erklärbar, dass das zehnfache der zugeführten Energie erreicht wird. Es ist die quantenmechanische Behandlung der in den Molekülen bzw. Komplexionen von Koordinationsverbindungen bestehenden Wechselwirkungen und chemischen Bindungen zwischen dem Zentralatom und den Liganden. Das heißt, die organischen Schichten, die in unserer Mischung eingesetzt werden, haben die Fähigkeit, empfangene Energie in Infrarotstrahlen in einem bestimmten Wellenlängenbereich umzuwandeln und abzustrahlen.
• – Die entwicklungsgemäße Mischung aus verschiedenen organischen Verbindungen führt zur Abstrahlung der Infrarotwellen mit hohem Wirkungsgrad. Das heißt, dass die abgestrahlte Wellenlänge der Strahlung auf die Zusammensetzung der Mischung zurückzuführen ist und die Aktivierung durch die Wärme- und Infrarotstrahlung der Kohlefasern zu erhöhter Strahlungsdichte fuhrt.
• – Die physikalischen und chemischen Bindungen zwischen Aluminium-, Magnesium- und Eisenoxiden mit weiteren organischen Komponenten, wie Quarz und Kohlenstoff ergeben ein Material, dessen Struktur stark von dem Herstellungsprozess, beziehungsweise dessen Reaktionstemperatur, beeinflusst ist. Die erreichte Temperaturbeständigkeit kann ohne strukturelle Veränderungen bis 1750°C gemessen werden. In der Chromatographie werden ähnliche Materialien als Adsorbens verwendet. Weiterhin dient gesintertes α-Al₂O₃ (Sinterkorund) als feuerfestes Material in Ofenauskleidungen oder Laborgeräten. Die besondere Fähigkeit von Elektronen sich zwischen Orbitalen zu bewegen, ergibt hier eine erweiterte Energiebildung durch Energieumwandlung im Langwellenbereich und Resonanz der zugeführten Energie, die hier als Infrarotwellen ausgestrahlt werden. Die Strahlung von Infrarotwellen durch Kohlefaserleitungen wird hier um ein Vielfaches verstärkt.

The object of the invention, with regard to the mixture ( 2 , Pts. 3 .) Of metal oxides and other components, such as quartz and carbon, as well as the attachment to increase the radiation in the infrared range and to achieve an even higher efficiency is achieved by the following process steps:

• According to scientific results, the composition of the heat conducting layer consists of the following chemical compounds: Al ₂ O ₃ , SiO ₂ , Fe ₂ O ₃ , CaO, MgO, C. The mixture has been adjusted proportionally such that the Properties of the mixture have the following properties:
• - A density of up to 3.5g / cm ³
• - Fast temperature warming of the entire body
• - The mix and density, as well as energetic reactions in the core of the structure, influence the energetic efficiency of the plate. Due to the physical principle of the orbital distribution of the electrons and thus of the ligand field theory, it can be explained that ten times the energy supplied is reached. It is the quantum mechanical treatment of the interactions and chemical bonds between the central atom and the ligands in the molecules or complexions of coordination compounds. That is, the organic layers used in our blend have the ability to convert and radiate received energy into infrared rays in a particular wavelength range.
• - The developmental mixture of different organic compounds leads to the radiation of infrared waves with high efficiency. This means that the radiated wavelength of the radiation is due to the composition of the mixture and the activation by the heat and infrared radiation of the carbon fibers leads to increased radiation density.
• - The physical and chemical bonds between aluminum, magnesium and iron oxides with other organic components, such as quartz and carbon yield a material whose structure is strongly influenced by the manufacturing process, or its reaction temperature. The achieved temperature resistance can be measured without structural changes up to 1750 ° C. In chromatography similar materials are used as adsorbent. Furthermore, sintered α-Al ₂ O ₃ (sintered corundum) serves as a refractory material in furnace linings or laboratory equipment. The special ability of electrons to move between orbitals, gives here an extended energy production by energy conversion in the long wave range and resonance of the supplied energy, which are broadcast here as infrared waves the. The radiation of infrared waves through carbon fiber cables is amplified here many times over.

One casting and curing process is enabled in any form by the method described above.

The technology according to the invention makes it possible to lay and form the heat conducting plate in any form ( 1 . 5 - 11 ).

The further layer of aluminum sheet or aluminum foil, (reflection plate) is used from further studies for the reflection of the reflection of the long-range spectrum ( 2 , Pts. 1 ). Our research, as well as other scientific studies, have shown that the atomic structure of aluminum is a mirror for the infrared waves, which prevents energy losses in the back wall direction (reflectance nearly 100%). This results in our execution up to 30% energy.

The further layer of polymer composition, ( 2 , Pts. 2 ) represents in the invention a layer that does not affect the reflective effect of the aluminum wall.

The layers: polymer composition, aluminum and phenolic resin paper, form a convection element ( 2 , Pts. 1 . 2 . 8th ), which turns the heat towards the core of the element, resulting in further savings of the primary energy (heating of the heat conduction plate by carbon fibers).

The Sealing the radiating elements with a silicone-like Mass granted safe use in humid areas and especially in agriculture, where washing and disinfecting are necessary.

The epoxy compound ( 2 , Pts. 4 . 5 ), feels three aspects of the application: substrate, thermal interface and filters for a wavelength from 6μm. Numerous samples of the inventor have confirmed that the blanket first layer of black epoxy is a perfect resonant mass and enhancer of radiant energy.

The housing, which is constructed of C-plate ( 2 , Pts. 6 ), proves optimal permeability values of infrared waves after many studies. The housing serves as a carrier for the entire construction. The support material made of C-sheet gives the object on the one hand the necessary stability and on the other hand mediates the selected radiation to the outside as a medium.

• – Die Benutzte Folie ist hochtemperaturbeständig und die Beschichtung macht sie gegen Außenwirkungen robust.
• – Die auf Epoximasse aufgetragenen natürlichen Komponenten, wie Sand, Keramik oder Metalloxyde beeinflussen die abgestrahlte Energie äußerst positiv.

The applied artistic coating of the support element ( 2 , Pts. 9 ) is consequently used according to the invention and the latest technologies:

• - The used film is resistant to high temperatures and the coating makes it robust against external effects.
• - The natural components applied to epoxy paint, such as sand, ceramics or metal oxides, have a very positive influence on the radiated energy.

A core idea of the invention is based on the finding that carbon fibers have high infrared radiation and thermal conductivity (99.9%). The proposed design of the heating element therefore leads to the energy generated being distributed directly and rapidly over the entire surface and the entire structure by the Epoxidleitmasse quickly and well. All components are used not only as a carrier of heat, but also act as a multiplicative factor of radiation. The "symbiosis" of all elements ensures optimal production as well as optimum distribution of heat and radiation.The common task of all elements with different physical and chemical structures has proven to be optimal in this respect ( 2 , Pts. 1 - 9 ). The construction technology according to the invention fulfills the requirement in particular for a cost-effective and artistic production of heating elements.

With Look at the problems presented in today's manufacturing technology and energy utilization, as in "Stand the technique "was explained let yourself recognize that the heating systems according to the invention especially for the medical and wellness area, as well as for the animal breeding and for Veterinary clinics are suitable. In general, the spotlight with the Embodiments described above effectively used for radiant heater and body warming. The Peculiarity of the depth penetration of the radiation and development of Heat plays in the construction industry a special role in drying of new buildings and old houses, Use in mold and fungus control.

The required electrical energy needed for our heating systems can be fully covered with solar panels.

The use of heating systems according to the invention provides a drastic reduction of costs compared to today's methods. The proposed method essentially involves only costs for procurement. However, these expenses are amortized after only a few years (2-3 years). The costs incurred are limited to the electricity costs, which are much lower than with heating systems according to the current state of the art. Elements mentioned in pts. [003] and [004] consume up to 400% more energy for the same effectiveness.

The illustrated embodiments allow us the amount of radiant energy in the infrared range to increase, without that the surface temperature elevated becomes.

clear can one compare the effect of the radiated infrared waves with the solar radiation, with the difference that our technology radiates selected wavelengths. The waves influence and warm so not the air directly, as classic radiators do, but all bodies, the water and carbon molecules include. The energy brings in the irradiated molecules of the body Movement, which increases your own temperature. That way all objects in the radiation area in the heat generator converted to the secondary to warm the air.

A further advantage of the technology according to the invention of constructions in any form can also be seen in the fact that the objects serve as artistic spatial design ( 5 - 11 ). Numerous models and constructional modalities are available for optimizing the technology and adapting it to individual requirements. Since every object is manufactured according to the customer's request, it is processed with special care and artistic sense. All objects combine the modern art, the latest technical and technological developments and energetic and health-promoting effectiveness. Particularly worth mentioning is the connection with the light radiation technology ( 5 - 9 ), which is medically recognized as health promoting. The projecting light spectrum encompasses nearly five million colors, which particularly influence the healing processes of the attacked psyche. The peculiarity of these compositions is that they can be used in all areas where support for well-being is required.

From the point of view of environmental protection, the technology of the proposed system has significant advantages. It eliminates the use of fossil fuels that emit CO, CO ₂ , S and other pollutants.

According to the invention the elements are also for existing heating systems can be used, (eg stove and night storage, which consume up to 5,000 watts of energy), causing significant reductions, up to 80% of the previous costs.

Summary of applied Elements:

• 1. Fixing dowel, "embedded in concrete" ( 1 , Pts. 2 ).
• 2. Thermostat 90 ° C ( 4a Pts. 5 )
• 3. steel plate ( 2 , Pts. 6 )
• 4. Aluminum sheet or aluminum foil ( 2 , Pts. 1 )
• 5. Powder coating of the steel sheet ( 2 , Pts. 7 )
• 6. Decoration (foil, minerals, metal, sand, etc.) ( 2 , Pts. 9 ).
• 7. Mounting device in the steel plate ( 1 , Pts. 2 . 3 ).
• 8. Thermal insulation board made of phenolic resin paper ( 2 , Pts. 1 ).
• 9. Optical variations (outer shape)
• • plates - square, triangular, round, etc.
• • Columns - round and angular, different variants of diameter and height
• • pyramids - three or four-walled
• • Integration our technology into existing equipment, (e.g. etc.).
• 10. Integration of light therapy elements, light radiation generators ( 5 - 9 ).

The presented detailed and detailed description of the invention shows the way to the efficient use of energy. Many possible modifications are therefore possible without departing from the scope of the invention.

1.

Außengehäuse aus C-Stahl

2.

Durchführungshülsen aus Alu

3.

Montagesteilen

1 casing

1.

Outer housing made of carbon steel

Second

Bushings made of aluminum

Third

mounting hardware

1.

Aluminiumblech- oder Aluminiumfolienschicht

2.

Polymermasse (kleben und abdichten)

3.

Wärmeleitende Schicht aus organischen Komponenten

4.

Epoxidmasse

5.

Kohlefasern in Silikonummantelung

6.

C-Stahlblech

7.

Lackschicht

8.

Phenolharz – Hartpapier

9.

Folie oder organische Beschichtung

2 building structure

1.

Aluminum sheet or aluminum foil layer

Second

Polymer compound (stick and seal)

Third

Thermally conductive layer of organic components

4th

epoxy compound

5th

Carbon fibers in silicone coating

6th

Carbon steel plate

7th

paint layer

8th.

Phenolic resin - kraft paper

9th

Foil or organic coating

1.

Kohlefasernleitung

2.

Abisolierte Kohlefasern

3.

Abisolierte Kupferleitung

4.

Aluminium- oder Kupfermuffe

5.

PVC Hülse

6.

Kupferleitung

3 Summary of the carbon fiber cable with a copper cable

1.

carbon fiber line

Second

Stripped carbon fibers

Third

Stripped copper wire

4th

Aluminum or copper sleeve

5th

PVC sleeve

6th

copper wire

1.

Elektromantageschacht

2.

Kohlefasern eingebetet in Epoxidmasse

3.

Montagelöcher

4.

Wärmeleitende Schicht

4 laying

1.

Elektromantageschacht

Second

Carbon fibers embedded in epoxy compound

Third

mounting holes

4th

Thermally conductive layer

1.

Maseeeitung

2.

Kabelschuh

3.

Masseverbindung

4.

Phasenleitung

5.

Thermosicherung

6.

Verbindungsmuffe

7.

Kupferleitung

8.

Verbindungsmuffe s. 3

9.

Kohlefasern

10.

Wärmeleitende Schicht

11.

Netzkabel

12.

Zugentlastung

13.

Phasenleitung

4a Mounting shaft

1.

Maseeeitung

Second

lug

Third

ground connection

4th

phase line

5th

thermal fuse

6th

coupling sleeve

7th

copper line

8th.

Connecting sleeve s. 3

9th

carbon fibers

10th

Thermally conductive layer

11th

power cable

12th

Strain relief

13th

phase line

1.

Lichtstrahler

2.

Wärme- und IR- Strahler

3.

Bodenplatte aus Stein oder Metall

5 Pillar pyramid with light emitter

1.

spotlights

Second

Heat and IR emitters

Third

Base plate of stone or metal

1.

Lichtstrahler

2.

Wärme- und IR- Strahler

3.

Wärme- und IR- Strahler

4.

Optische Elemente

5.

Verbindungssäulen

6.

Bodenplatte aus Stein oder Metall

6 Pillar - art with optical elements

1.

spotlights

Second

Heat and IR emitters

Third

Heat and IR emitters

4th

Optical elements

5th

connecting columns

6th

Base plate of stone or metal

1.

Lichtstrahler

2.

Steinplatte

3.

Wärme- und IR- Strahler

4.

Bodenplatte aus Stein oder Metall

7 Square pillar with lighting elements

1.

spotlights

Second

stone slab

Third

Heat and IR emitters

4th

Base plate of stone or metal

1.

Lichtstrahler

2.

Steinplatte

3.

Wärme- und IR- Strahler

4.

Bodenplatte aus Stein oder Metall

8th Round pillar with light elements

1.

spotlights

Second

stone slab

Third

Heat and IR emitters

4th

Base plate of stone or metal

1.

Wärme- und IR- Strahler

2.

Verglaste Lichtstrahler

3.

Bodenplatte aus Stein oder Metall

4.

Sockel aus Plexiglas

9 Square pillar with light element

1.

Heat and IR emitters

Second

Glazed light emitters

Third

Base plate of stone or metal

4th

Plexiglass base

1.

Wärme und IR Strahler

2.

Bodenplatte aus Stein oder Metall

3.

Sockel

10 Square column coated with paint, foil or minerals

1.

Heat and IR emitters

Second

Base plate of stone or metal

Third

base

1.

Glasbruch mit Lichtstrahler

2.

Steinplatte

3.

Wärme- und IR- Strahler

4.

Sockel

11 Round column with broken glass and light

1.

Glass breakage with light emitter

Second

stone slab

Third

Heat and IR emitters

4th

base

Claims (12)

The infrared radiator is characterized in that it consists of several independent in carbon steel alloy alloyed carbon fiber cables. The applied length of the carbon fibers is calculated after the heat generation and efficiency in the infrared wave range and the radiation density. The epoxy compound is characterized in that they are thermally conductive Mass and selective filter is used. The housing Made of carbon steel is characterized by being painted inside and out or powder coated. Different forms of the system are thereby marked as plates, pyramids, columns, spheres etc. are constructed. The heat-conducting layer is characterized in that it consists of selected materials: Al ₂ O ₃ , SiO ₂ , Fe ₂ O ₃ , CaO, MgO, C. The aluminum layer is characterized that it is used as a reflection mirror. The hard paper back wall is characterized in that it is used as a thermal insulation layer. The polymer composition is characterized in that they as glue and as heat-insulating compound is used. The silicone-like Mass is characterized in that it is used for sealing and stabilization becomes. The fasteners for mounting are characterized characterized in that they are firmly connected to the entire body or directly incorporated into the body become. The connectivity our system is characterized in that the products in existing objects, such as a fireplace used can be. The integration of light therapy elements in different Shapes is characterized in that the system is used as heat, infrared and light emitter can be used.