DE102005038816B3 - Electro heating tube of nanometer-silicon-carbon complex fibers e.g., for heating purposes and healthcare appliances, includes component with micro-particles of nanometer carbon - Google Patents

Abstract

An electro-heating tube of nanometer-silicon-carbon complex fibers, in which the material of the heating body consists of silicon-carbon complex fibers, a component with micro-particles of nanometer carbon and nanometer tourmaline and with uniformly distributed micro pores, in nanometer range. The material of the tubular body (1) consists of quartz glass with micro-particle of nanometer tourmaline, and its shape matches that of the heating body (2).

Description

Of the Subject of the invention belongs to the genus of electrothermal devices. He concerns an electric heating pipe for the Heating, health care and / or physical therapy.

Previous used in space or in heating facilities electrothermal Equipment, such as. Halogen lights, consist essentially of one pipe body made of glass, a heating wire inside and two at both Ends of the heating wire lying electrodes, their connections off the glass tube body be led out. The material of such heating wires is usually made of metal, e.g. Tungsten, Ni-Cr alloys etc. These electrothermal devices have the maximum energy distribution the radiated heat not in the infrared range. They rather emit visible light with a low heat effect out. The metal heating wire and the two at his Ends lying electrodes oxidize relatively quickly and tend easy to break. The lifetime of these devices is therefore relatively short.

With the DE 44 38 870 A1 An infrared radiator with an elongate resistance body has also already become known as a radiation source, wherein the carbon fiber fiber resistance body is located in a capillary cavity of a quartz glass envelope which is evacuated or filled with inert gas. With a slit-shaped flat quartz glass capillary tube, a high reaction rate of the infrared radiation source is desired.

These essentially radiating only in the medium-wave infrared range However, the radiation source does not radiate or only very slightly in the shorter wavelength range of 0.7-9 μm, which for sterilization, mold destruction or to improve the Microcirculation is needed in the human body. Against the risk of breakage when heated of the resistance body This known radiation source are consuming contact pins their ends as a spiral Spring elements formed. These are the same as the thermal expansion largely but cause additional costs in their manufacture and increase the space required for the unused non-radiating end portions of the quartz glass cladding and thus the longitudinal extent of the entire infrared radiator.

Furthermore, with the DE 102 59 498 A1 conductive thermoplastics have become known with carbon black and carbon nanofibrils. These can be used in addition to their main prevention of anti-static charges or their electromagnetic shielding properties, including when using their electrical conductivity, eg for heating elements.

such conductive Thermoplastics with carbon nanofibrils and particulate carbon compounds But essentially have property profiles where it is on good flowability with low surface resistance and very good surface quality with high toughness arrives. Your use and use as an infrared radiation source also in the shorter wavelength range of 0.7-9 μm is from the main item belonging to another genus as radiation sources this publication does not appear.

Finally, with the DE 44 12 389 A1 a method for producing a curved radiator, in particular a halogen incandescent lamp, and thus produced radiator and a device suitable therefor has become known, in which a rod-shaped radiator is bent to a full circle.

This Procedure is for Quartz glass and for fused quartz suitable but can not be higher heat effects and increased it Energy savings, e.g. through other material combinations, than achieve previously known spotlights. This curved to a full circle Spotlight made of quartz glass radiates as well as the one above Inboard emitters, little or no infrared in the 0.7-9 μm wavelength range and therefore emits only a few or no anions, the for sterilization, mold destruction or to improve the Microcirculation can be meaningfully used in the human body could.

task The invention is an infrared-radiating electric heating tube with higher heat yield and a longer one To provide life not only for heating purposes, but also for the Health care and physical therapy with increased benefits can be used.

to solution This task is the material of the radiator of silicone-carbon complex fibers each with a component microparticles of nanometer carbon and one out of nanometer tourmaline, the evenly distributed Having micropores in the nanometer range, wherein the material of the tubular body consists of quartz glass with microparticles of nanometer tourmaline and its shape the radiator is adjusted.

The radiator of a fabric-like silicone-carbon complex fiber has a longer life than the previously known heating wires. He emits infrared in the 0.7-9 μm wavelength range and emits anions. As a result, he is in particular for. Sterilization, mold eradication and improve micro-circulation in the human body.

to Heat radiation, Health care and physical therapy, the device can be beneficial be applied. Compared to the previously known heating devices has the electric heating tube according to the invention a higher one Heat effect. It a more than 30% energy saving is achieved.

advantageously, can the radiator linear, circular or be formed in any other form. He can therefore be spatially well adapted to the respective field of application.

ever according to the desired Application and the associated design, the electrical connections the at both ends of the radiator lying electrodes advantageously one or both sides arranged out of the tubular body be.

Furthermore can the electrodes wire or plate made of tungsten-molybdenum to a longer one To achieve lifetime.

The Electric heating pipe can alternatively with both change and with Be operated DC. The hermetically sealed in the tubular body Antioxidant consists of a noble gas,

In The following figures illustrate four embodiments of the invention explained in more detail. Show it

image 1 a radiator in linear form,

image 2 a radiator in a circle,

image 3 an electric heating tube with one side led out of it terminals of Electrodes and

image 4 a radiator in omega form.

In picture 1 is with 1 denotes a linear tube body having a Heizpörper in its interior 2 made of nanometer-silicone-carbon complex fibers. At the ends of the radiator 2 are the electrodes 3 and 3 ' , These may consist of a wire or a plate of tungsten-molybdenum. In the tube body 1 is hermetically sealed as an antioxidant 4 a noble gas. The material of the radiator 2 Silicon-carbon complex fiber has a microparticle nanoparticle nanoparticle component and nanometer-scale nanometer-sized tourmaline micropore.

The material of the pipe body 1 consists of quartz glass with microparticles of nanometer tourmaline and its shape is the radiator 2 customized.

In picture 2 is the radiator 2 circular shaped. The electrodes 3 and 3 ' are on opposite sides of the circular radiator 2 arranged and their connections are from a radiator 2 likewise flat enveloping flat tubular body 1 brought out, with 4 is a hermetic inside the flat tubular body 1 denoted antioxidant.

In Figure 3 is an electric heating tube with one side of a tubular body 1 led out terminals 3 and 3 ' which is at both ends of a radiator 2 arranged electrodes, shown. A quartz capillary 5 gets off the radiator 2 envelops. Both ends of the radiator 2 are each made by a tungsten molybdenum wire electrode 3 and 3 ' fixed. The tungsten molybdenum wire electrode 3 is directly via a connecting line from the tubular body 1 led out while the tungsten molybdenum wire electrode 3 ' centered via a connecting cable through the quartz capillary 5 through at the same end of the tubular body 1 is led out.

In picture 4 is the radiator 2 formed in omega form. This shape fits the likewise omega-shaped tubular body 1 completely on. With 3 and 3 ' are the electrodes at the ends of the radiator 2 and with 4 is the antioxidant, eg a noble gas.

Depending on the requirements and field of application, the mode of operation of the electric heating pipes illustrated in Figures 1 to 4 can be up to a surface temperature of 900 ° C on the tubular body made of quartz glass 1 respectively. Both AC and DC power can be used for operation. At a temperature above 800 ° C radiates the radiator 2 infrared in the 0.7-9 micron wavelength range and emits anions.

In comparison to conventional known filament materials, the radiator according to the invention 2 a 4-fold infrared radiation intensity and a 2-fold thermal effect. The thermal efficiency is therefore high and the saving effect of electric energy is more than 30%.

Claims (5)

Electric heating tube made of nanometer silicone Koh lenstoff complex fibers with - a tubular body ( 1 ), - a radiator ( 2 ) in the tubular body, - at the ends of each electrode ( 3 . 3 ' ) and - a hermetically sealed in the tubular body antioxidant ( 4 ), characterized in that - the material of the radiator ( 2 ) of silicone-carbon complex fibers has a component with microparticles of nanometer carbon and one of nanometer tourmaline with uniformly distributed micropores in the nanometer range, and - that the material of the tubular body ( 1 ) consists of quartz glass with microparticles of nanometer tourmaline and its shape the radiator ( 2 ) is adjusted. Electric heating tube according to claim 1, characterized in that the radiator ( 2 ) is formed in a linear or in a circular shape. Electric heating tube according to claim 1 or 2, characterized in that the connections of the at both ends of the radiator ( 2 ) lying electrodes ( 3 . 3 ' ) one or both sides of the tubular body ( 1 ) are herausführbar. Electric heating tube according to claim 1 to 3, characterized in that the electrodes ( 3 . 3 ' ) are in the form of a wire or plate of tungsten-molybdenum. Electric heating tube according to claim 1 to 4, characterized in that the antioxidant ( 4 ) consists of a noble gas.