DE102013012514A1 - Method for manufacturing inductor, involves transferring solid material in fluid state by chemical and/or physical bending of material, and removing solid material from induction coil - Google Patents

Abstract

The method involves forming an induction coil (3) by bending of a tube, where the tube is filled with a solid material. The solid material is transferred in a fluid state by chemical and/or physical bending of the material. The soluble material is dissolved after bending and converted into a liquid form. The solid material is removed from the induction coil.

Description

The invention relates to a method for producing an inductor according to the preamble of claim 1.

From the German utility model DE 298 04 574 U1 For example, an inductor is known which comprises a hollow section inductor. In particular, the induction coil of electrically conductive tubes, such as copper tubes, is formed, wherein during operation of the inductor, a coolant can be passed through the hollow cross-section of the induction coil. The induction coil of such an inductor is made by bending a tube. In order to prevent cracks or fractures from forming, the pipe is filled with a solid material, in particular sand, before being bent. If the tube is bent only slightly or if an induction coil with a simple geometric shape is produced, it is readily possible to remove the sand from the induction coil after the bending process. However, there is a need for complicated shapes for induction coils, in particular induction coils are preferred, which have a tortuous shape, in particular a spiral or meandering shape. If a pipe is bent in such a complicated shape, it is after the bending process only extremely difficult or no longer possible to remove the sand in particular without residue from the tube.

The invention has for its object to provide a method for producing an inductor, which does not have the disadvantages mentioned. In particular, it should be possible using the method to produce even complicated, in particular spiral, coil or meandering induction coils, whereby a risk of cracking or breakage avoided and at the same time provided for this purpose material can be removed as residue-free.

The object is achieved by providing a method with the steps of claim 1. The method is characterized in that a material introduced into the tube before bending to prevent cracks or fractures after being bent is chemically and / or physically transferred to a fluid state and removed from the induction coil in this state. It turns out that it is possible even with very complicated bending forms to remove the material in the fluid state easily from the induction coil. Thus, in the context of the method complicated, in particular coil, spiral or meandering induction coils can be produced with a hollow cross-section, without on the one hand cracks or fractures during bending of a tube from which the induction coil is produced, occur, and without the other hand to avoid Cracks or fractures filled, solid material after the bending process can not be removed from the induction coil.

Preferably, the material is chemically and / or physically converted into a liquid or gaseous form and removed from the induction coil in the liquid or gaseous state. It is possible that the material is chemically dissolved, chemically reacted, melted, sublimed or evaporated.

A method is preferred which is characterized in that a soluble material is used which, after being bent, is dissolved by means of a solvent and thus converted into a liquid form. As a soluble material, in one embodiment of the method, a salt or other substance which is soluble in a polar solvent, especially in water, may be used. Alternatively, it is possible that in one embodiment of the method a material is used which is soluble in a non-polar solvent. By dissolving the soluble material in a suitable solvent, the material is converted into a fluid form, namely a solution in which it is dissolved in the solvent. It can thus be readily poured together with the solvent from the induction coil. In this way, it is readily possible to remove the material even from very complicated bending forms of the induction coil.

A method is also preferred, which is characterized in that a fusible material is used, which is melted after bending by supplying heat and thus converted into a liquid state. It is therefore preferable to choose a material which is solid at room temperature or at the temperature at which the tube is bent. At the same time, the material is chosen so that its melting point is at a temperature at which the induction coil made by bending is not thermally stressed in a manner that could lead to damage. After bending, therefore, the induction coil can be heated without damage, whereby the solid material arranged in it is melted and thus converted into a liquid form, and thus into a fluid state. It is then possible to easily pour the material from very complicated bending forms of the induction coil.

Alternatively, it is possible to use a vaporizable material which evaporates after being bent by heat supply and thus becomes a gaseous state. Also in this case a material is used which is at room temperature or when bending the tube prevailing temperature, wherein a boiling point or a sublimation point of the material is selected so that the material boils or sublimates at a temperature at which the induction coil formed by bending is not damaged. It is then possible to convert the solid material in the induction coil after bending - without damaging it - by boiling or sublimation in the vapor phase, thus in a gaseous state, wherein the gaseous material easily removed even from very complicated bending shapes of the induction coil can be. If the material in the gaseous state has a density which is greater than that of air, it can be poured out of the induction coil. If, on the other hand, the material has a density which is less than the density of air, it escapes readily from the induction coil, this optionally being rotated in order to completely remove the material even from internal turns. Alternatively or additionally, it is possible, in particular if the material has a density which is close to the density of air, to expel the material from the induction coil by a fluid flow, in particular an air flow sent through the hollow cross section. Also in this way it is readily possible to remove the material without residue from the induction coil.

A method is preferred which is characterized in that an adhesive-bonded material is used as the material. This material is preferably dissolved by a water-sodium chloride solution as a solvent. Alternatively, it is possible to dissolve such a material by a polar, in particular organic solvent and thus to convert it into a fluid form.

A method is also preferred which is characterized in that ice is used as the material. The term "ice" refers to a material which is solid at a temperature below room temperature, while it is liquid at room temperature. In this case, the tube is bent at a temperature at which the material is solid, so that the solid material arranged in the hollow cross-section can effectively prevent cracking or breakage. Water ice, ie frozen water, is particularly preferably used as the material.

Alternatively, it is possible to use a material which is solid at room temperature but melts above room temperature, especially at a temperature at which the induction coil is not damaged. As such material, wax is preferably used. This is sufficiently strong at room temperature to effectively prevent cracking or breakage when bending the tube to make the induction coil. At the same time wax is easily melted at a not too high temperature above the room temperature, so that it can be converted into a liquid state and in this easily removed from the hollow section of the induction coil, which is not damaged.

A method is also preferred which is characterized in that the material is free-flowing in the solid state. In particular, this indicates that the material in the solid state, by being introduced into the pipe before bending, has a high degree of distribution, so that it can be poured into the pipe. The fact that the material is pourable, it adapts its shape readily to the bending of the tube in the manufacture of the induction coil, while it exerts sufficient support forces on a pipe wall to prevent the formation of cracks or fractures. As a free-flowing material in the solid state is preferably used finely divided ice, a finely divided wax, a salt or in particular a crystalline organic material which is soluble in polar or nonpolar solvents. In particular sugar, above all glucose, in particular conventional edible sugar, comes into consideration as free-flowing organic material. As the inorganic material, for example, common salt may be used.

To increase the solubility of the material in the solvent, this is preferably introduced at elevated temperature, in particular hot, in the induction coil. This makes it possible to accelerate the dissolution of the material.

Finally, a method is preferred which is characterized in that the material is removed without residue after bending in liquid or gaseous form. In particular, residues of the material are preferably blown out of the hollow cross-section of the induction coil. Alternatively or additionally, it is possible, in particular to dry residues of a solvent by hot air is preferably passed through the hollow cross-section. A residue-free removal of the material is particularly important for a subsequent passage of coolant through the hollow cross section of the induction coil when using the inductor. Residues of the material could in this case damage elements of a coolant circuit or lead to clogging of the hollow section or other parts of the coolant circuit.

The invention will be explained in more detail below with reference to the drawing. The single figure shows a schematic representation of an embodiment of an inductor.

The figure shows an embodiment of an inductor 1 in a cut off Detailed display. The inductor 1 includes a curved induction coil 3 , which is bent from a tube and thus a hollow cross-section 5 has, therefore, is hollow inside. The pipe or the induction coil 3 has a substantially square cross-section in the illustrated embodiment. It is alternatively also possible that the induction coil 3 has a rectangular cross section, an oval cross section, a circular cross section or another, suitable cross-sectional shape.

It is obvious that the induction coil 3 in the area of a curvature 7 is bent. Overall, the induction coil shown here only partially 3 preferably coil-shaped, spirally or meandering bent. Other, in particular complicated bending forms are for the induction coil 3 possible.

It is preferably made from a straight tube by bending, wherein prior to bending a solid material in the hollow cross-section 5 is filled to prevent the formation of cracks or breaks in bending. The solid, preferably free-flowing material adapts when bending the resulting shape of the induction coil 3 while at the same time supporting forces on a wall 9 of the tube, so that in particular in the area of the curvature 7 do not break or crack.

The solid, preferably free-flowing material is chosen so that it can be converted after bending chemically and / or physically in a fluid state, in particular in a liquid or gaseous form. In this way it is possible, the material also from complicated bending forms of the inductor 1 remove again without residue.

Overall, it can be seen that it is possible by means of the method, any, even very complicated forms of an induction coil 3 by bending, on the one hand cracks and fractures are avoided, and on the other hand, a to support the wall 9 provided, solid and preferably free-flowing material after bending residue free from the hollow cross-section 5 can be removed.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 29804574 U1 [0002]

Claims (7)

Method for producing an inductor ( 1 ) with a hollow cross-section ( 5 ) induction coil ( 3 ), wherein the induction coil ( 3 ) is produced by bending a tube, wherein the tube is filled before bending with a solid material, characterized in that the material after bending chemically and / or physically transferred to a fluid state and in this from the induction coil ( 3 ) Will get removed. A method according to claim 1, characterized in that a soluble material is used, which is dissolved after bending by means of a solvent and thus converted into a liquid form. Method according to one of the preceding claims, characterized in that a fusible or vaporizable material is used, which is melted or evaporated after bending by supplying heat and thus converted into a liquid or gaseous state. Method according to one of the preceding claims, characterized in that a bonded material by means of adhesive material is used, wherein the bonded material by means of adhesive is preferably dissolvable by a water-sodium chloride solution as a solvent. Method according to one of the preceding claims, characterized in that ice, in particular water ice, or wax is used as the material. Method according to one of the preceding claims, characterized in that the material is free-flowing in the solid state. Method according to one of the preceding claims, characterized in that the material is removed without residue after bending in liquid or gaseous form.

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