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Oberflächen- und Durchhärtung von Stahlteilen
- Schweissen und Glühen von Rohren
- Hartlöten, Weichlöten
- Blockerwärmung für Warmverformung
- Erwärmen und Schmelzen von Eisenmetallen, Nichteisenmetallen und anderen Materialien wie z.B. Glas
- Spannungsfrei Glühen
- Rekristallisationsglühen
- Epitaxie- Anlagen für die Halbleiterfabrikation
induktion, induktiv, drahterwärmung, blechbläuen, glühen, anlassen, auftauen, trocknen, verleimen, hochfrequenz, mittelfrequenz, erwärmung, induktionsheizung, induktionserwärmung, schmelzen, härten, induktionshärten, induktionsschmelzen, kabelerwärmung, rohrschweissen, löten, induktionslöten, dielektrische erwärmung, kapazitive erwärmung, hochfrequenzgenerator, induktor, induktoren, leistungselektronik, spannungsversorgung, stromversorgung
Induction, dielectric, heating, power electronics, RF, frequency, high power, high current, high voltage, sources, inductive, capacitive, heat, ovenDifferent cables and wires must be heated before the isolation process (extruding) according to the used material from 80-200°C.
For this application the induction heating is very common as a careful and pollution free solution. hardening, heating, induction hardening, coating,
induction heating, tube welding, Annealing technology,
Stirring, induction welding, induction hardening machines, induction heating machines, tube heating machines, tube annealing,
tube welding machines, hardening machines, barstock heating, crankshaft hardening machines, hot cropping, mills,Frequency Converter, Transistor Generator, Induction Power-source, Induction Hardening, Induction Brazing, Induction Welding, Induction, Induction Coil. Induction heating is used since more than 50 years for comercial applications, but nevertheless it is not well known to the wide public.
For induction heating the working piece must be electrically conductive such as metal or semiconductive as silicon. The highfrequency-energy is transmitted by way of an induction coil to the workpiece. The induction coil or simple "inductor" is geometrically adapted to the shape of the workpiece, in most applications it consists of a bent cupperpipe and is water-cooled.
Due to technical advances (semiconductors, transistors) the size and weight of present-day equipment could be minimized about to about 10% (with respect to previous models). The compact design, small weight and flexibility of the equipment and its advantageous price makes it possible to use induction heating for many applications.
In the following we try to show you some of the most frequently used ranges of activities, and at the same time help you to imagine the use of induction heating for your own purposes. There are a lot of various possible applications, and with the advances of induction heating many existing processes could also be improved with this technique!Induction heating is used since more than 50 years for comercial applications, but nevertheless it is not well known to the wide public.
For induction heating the working piece must be electrically conductive such as metal or semiconductive as silicon. The highfrequency-energy is transmitted by way of an induction coil to the workpiece. The induction coil or simple "inductor" is geometrically adapted to the shape of the workpiece, in most applications it consists of a bent cupperpipe and is water-cooled.
Due to technical advances (semiconductors, transistors) the size and weight of present-day equipment could be minimized about to about 10% (with respect to previous models). The compact design, small weight and flexibility of the equipment and its advantageous price makes it possible to use induction heating for many applications.
In the following we try to show you some of the most frequently used ranges of activities, and at the same time help you to imagine the use of induction heating for your own purposes. There are a lot of various possible applications, and with the advances of induction heating many existing processes could also be improved with this technique! Induction heating is used since more than 50 years for comercial applications, but nevertheless it is not well known to the wide public.
For induction heating the working piece must be electrically conductive such as metal or semiconductive as silicon. The highfrequency-energy is transmitted by way of an induction coil to the workpiece. The induction coil or simple "inductor" is geometrically adapted to the shape of the workpiece, in most applications it consists of a bent cupperpipe and is water-cooled.
Due to technical advances (semiconductors, transistors) the size and weight of present-day equipment could be minimized about to about 10% (with respect to previous models). The compact design, small weight and flexibility of the equipment and its advantageous price makes it possible to use induction heating for many applications.
In the following we try to show you some of the most frequently used ranges of activities, and at the same time help you to imagine the use of induction heating for your own purposes. There are a lot of various possible applications, and with the advances of induction heating many existing processes could also be improved with this technique!
What is induction heating?
Induction heating is basically different with respect to most other heating processes. The heat develops in the workpiece itself, there is no need for a transmission medium (such as air, water or a mechanical connection) The electrical energy is transmitted to the workpiece trough a magnetic field. Induction heating is used since more than 50 years for comercial applications, but nevertheless it is not well known to the wide public.For induction heating the working piece must be electrically conductive such as metal or semiconductive as silicon. The highfrequency-energy is transmitted by way of an induction coil to the workpiece. The induction coil or simple "inductor" is geometrically adapted to the shape of the workpiece, in most applications it consists of a bent cupperpipe and is water-cooled.
Due to technical advances (semiconductors, transistors) the size and weight of present-day equipment could be minimized about to about 10% (with respect to previous models). The compact design, small weight and flexibility of the equipment and its advantageous price makes it possible to use induction heating for many applications.
In the following we try to show you some of the most frequently used ranges of activities, and at the same time help you to imagine the use of induction heating for your own purposes. There are a lot of various possible applications, and with the advances of induction heating many existing processes could also be improved with this technique!
What is induction heating?
Induction heating is basically different with respect to most other heating processes. The heat develops in the workpiece itself, there is no need for a transmission medium (such as air, water or a mechanical connection) The electrical energy is transmitted to the workpiece trough a magnetic field. Induction heating is used since more than 50 years for comercial applications, but nevertheless it is not well known to the wide public.For induction heating the working piece must be electrically conductive such as metal or semiconductive as silicon. The highfrequency-energy is transmitted by way of an induction coil to the workpiece. The induction coil or simple "inductor" is geometrically adapted to the shape of the workpiece, in most applications it consists of a bent cupperpipe and is water-cooled.
Due to technical advances (semiconductors, transistors) the size and weight of present-day equipment could be minimized about to about 10% (with respect to previous models). The compact design, small weight and flexibility of the equipment and its advantageous price makes it possible to use induction heating for many applications.
In the following we try to show you some of the most frequently used ranges of activities, and at the same time help you to imagine the use of induction heating for your own purposes. There are a lot of various possible applications, and with the advances of induction heating many existing processes could also be improved with this technique!
What is induction heating?
Induction heating is basically different with respect to most other heating processes. The heat develops in the workpiece itself, there is no need for a transmission medium (such as air, water or a mechanical connection) The electrical energy is transmitted to the workpiece trough a magnetic field. Induction heating is used since more than 50 years for comercial applications, but nevertheless it is not well known to the wide public.For induction heating the working piece must be electrically conductive such as metal or semiconductive as silicon. The highfrequency-energy is transmitted by way of an induction coil to the workpiece. The induction coil or simple "inductor" is geometrically adapted to the shape of the workpiece, in most applications it consists of a bent cupperpipe and is water-cooled.
Due to technical advances (semiconductors, transistors) the size and weight of present-day equipment could be minimized about to about 10% (with respect to previous models). The compact design, small weight and flexibility of the equipment and its advantageous price makes it possible to use induction heating for many applications.
In the following we try to show you some of the most frequently used ranges of activities, and at the same time help you to imagine the use of induction heating for your own purposes. There are a lot of various possible applications, and with the advances of induction heating many existing processes could also be improved with this technique!
What is induction heating?
Induction heating is basically different with respect to most other heating processes. The heat develops in the workpiece itself, there is no need for a transmission medium (such as air, water or a mechanical connection) The electrical energy is transmitted to the workpiece trough a magnetic field. Induction heating is used since more than 50 years for comercial applications, but nevertheless it is not well known to the wide public.For induction heating the working piece must be electrically conductive such as metal or semiconductive as silicon. The highfrequency-energy is transmitted by way of an induction coil to the workpiece. The induction coil or simple "inductor" is geometrically adapted to the shape of the workpiece, in most applications it consists of a bent cupperpipe and is water-cooled.
Due to technical advances (semiconductors, transistors) the size and weight of present-day equipment could be minimized about to about 10% (with respect to previous models). The compact design, small weight and flexibility of the equipment and its advantageous price makes it possible to use induction heating for many applications.
In the following we try to show you some of the most frequently used ranges of activities, and at the same time help you to imagine the use of induction heating for your own purposes. There are a lot of various possible applications, and with the advances of induction heating many existing processes could also be improved with this technique!
What is induction heating?
Induction heating is basically different with respect to most other heating processes. The heat develops in the workpiece itself, there is no need for a transmission medium (such as air, water or a mechanical connection) The electrical energy is transmitted to the workpiece trough a magnetic field.Induction heating is used since more than 50 years for comercial applications, but nevertheless it is not well known to the wide public.For induction heating the working piece must be electrically conductive such as metal or semiconductive as silicon. The highfrequency-energy is transmitted by way of an induction coil to the workpiece. The induction coil or simple "inductor" is geometrically adapted to the shape of the workpiece, in most applications it consists of a bent cupperpipe and is water-cooled.
Due to technical advances (semiconductors, transistors) the size and weight of present-day equipment could be minimized about to about 10% (with respect to previous models). The compact design, small weight and flexibility of the equipment and its advantageous price makes it possible to use induction heating for many applications.
In the following we try to show you some of the most frequently used ranges of activities, and at the same time help you to imagine the use of induction heating for your own purposes. There are a lot of various possible applications, and with the advances of induction heating many existing processes could also be improved with this technique!
What is induction heating?
Induction heating is basically different with respect to most other heating processes. The heat develops in the workpiece itself, there is no need for a transmission medium (such as air, water or a mechanical connection) The electrical energy is transmitted to the workpiece trough a magnetic field. Induction heating is used since more than 50 years for comercial applications, but nevertheless it is not well known to the wide public.For induction heating the working piece must be electrically conductive such as metal or semiconductive as silicon. The highfrequency-energy is transmitted by way of an induction coil to the workpiece. The induction coil or simple "inductor" is geometrically adapted to the shape of the workpiece, in most applications it consists of a bent cupperpipe and is water-cooled.
Due to technical advances (semiconductors, transistors) the size and weight of present-day equipment could be minimized about to about 10% (with respect to previous models). The compact design, small weight and flexibility of the equipment and its advantageous price makes it possible to use induction heating for many applications.
In the following we try to show you some of the most frequently used ranges of activities, and at the same time help you to imagine the use of induction heating for your own purposes. There are a lot of various possible applications, and with the advances of induction heating many existing processes could also be improved with this technique!
What is induction heating?
Induction heating is basically different with respect to most other heating processes. The heat develops in the workpiece itself, there is no need for a transmission medium (such as air, water or a mechanical connection) The electrical energy is transmitted to the workpiece trough a magnetic field. Induction heating is used since more than 50 years for comercial applications, but nevertheless it is not well known to the wide public.For induction heating the working piece must be electrically conductive such as metal or semiconductive as silicon. The highfrequency-energy is transmitted by way of an induction coil to the workpiece. The induction coil or simple "inductor" is geometrically adapted to the shape of the workpiece, in most applications it consists of a bent cupperpipe and is water-cooled.
Due to technical advances (semiconductors, transistors) the size and weight of present-day equipment could be minimized about to about 10% (with respect to previous models). The compact design, small weight and flexibility of the equipment and its advantageous price makes it possible to use induction heating for many applications.
In the following we try to show you some of the most frequently used ranges of activities, and at the same time help you to imagine the use of induction heating for your own purposes. There are a lot of various possible applications, and with the advances of induction heating many existing processes could also be improved with this technique!
What is induction heating?
Induction heating is basically different with respect to most other heating processes. The heat develops in the workpiece itself, there is no need for a transmission medium (such as air, water or a mechanical connection) The electrical energy is transmitted to the workpiece trough a magnetic field. Induction heating is used since more than 50 years for comercial applications, but nevertheless it is not well known to the wide public.For induction heating the working piece must be electrically conductive such as metal or semiconductive as silicon. The highfrequency-energy is transmitted by way of an induction coil to the workpiece. The induction coil or simple "inductor" is geometrically adapted to the shape of the workpiece, in most applications it consists of a bent cupperpipe and is water-cooled.
Due to technical advances (semiconductors, transistors) the size and weight of present-day equipment could be minimized about to about 10% (with respect to previous models). The compact design, small weight and flexibility of the equipment and its advantageous price makes it possible to use induction heating for many applications.
In the following we try to show you some of the most frequently used ranges of activities, and at the same time help you to imagine the use of induction heating for your own purposes. There are a lot of various possible applications, and with the advances of induction heating many existing processes could also be improved with this technique!
What is induction heating?
Induction heating is basically different with respect to most other heating processes. The heat develops in the workpiece itself, there is no need for a transmission medium (such as air, water or a mechanical connection) The electrical energy is transmitted to the workpiece trough a magnetic field. Induction heating is used since more than 50 years for comercial applications, but nevertheless it is not well known to the wide public.For induction heating the working piece must be electrically conductive such as metal or semiconductive as silicon. The highfrequency-energy is transmitted by way of an induction coil to the workpiece. The induction coil or simple "inductor" is geometrically adapted to the shape of the workpiece, in most applications it consists of a bent cupperpipe and is water-cooled.
Due to technical advances (semiconductors, transistors) the size and weight of present-day equipment could be minimized about to about 10% (with respect to previous models). The compact design, small weight and flexibility of the equipment and its advantageous price makes it possible to use induction heating for many applications.
In the following we try to show you some of the most frequently used ranges of activities, and at the same time help you to imagine the use of induction heating for your own purposes. There are a lot of various possible applications, and with the advances of induction heating many existing processes could also be improved with this technique!
What is induction heating?
Induction heating is basically different with respect to most other heating processes. The heat develops in the workpiece itself, there is no need for a transmission medium (such as air, water or a mechanical connection) The electrical energy is transmitted to the workpiece trough a magnetic field. Induction heating is used since more than 50 years for comercial applications, but nevertheless it is not well known to the wide public.For induction heating the working piece must be electrically conductive such as metal or semiconductive as silicon. The highfrequency-energy is transmitted by way of an induction coil to the workpiece. The induction coil or simple "inductor" is geometrically adapted to the shape of the workpiece, in most applications it consists of a bent cupperpipe and is water-cooled.
Due to technical advances (semiconductors, transistors) the size and weight of present-day equipment could be minimized about to about 10% (with respect to previous models). The compact design, small weight and flexibility of the equipment and its advantageous price makes it possible to use induction heating for many applications.
In the following we try to show you some of the most frequently used ranges of activities, and at the same time help you to imagine the use of induction heating for your own purposes. There are a lot of various possible applications, and with the advances of induction heating many existing processes could also be improved with this technique!
What is induction heating?
Induction heating is basically different with respect to most other heating processes. The heat develops in the workpiece itself, there is no need for a transmission medium (such as air, water or a mechanical connection) The electrical energy is transmitted to the workpiece trough a magnetic field. Induction heating is used since more than 50 years for comercial applications, but nevertheless it is not well known to the wide public.For induction heating the working piece must be electrically conductive such as metal or semiconductive as silicon. The highfrequency-energy is transmitted by way of an induction coil to the workpiece. The induction coil or simple "inductor" is geometrically adapted to the shape of the workpiece, in most applications it consists of a bent cupperpipe and is water-cooled.
Due to technical advances (semiconductors, transistors) the size and weight of present-day equipment could be minimized about to about 10% (with respect to previous models). The compact design, small weight and flexibility of the equipment and its advantageous price makes it possible to use induction heating for many applications.
In the following we try to show you some of the most frequently used ranges of activities, and at the same time help you to imagine the use of induction heating for your own purposes. There are a lot of various possible applications, and with the advances of induction heating many existing processes could also be improved with this technique!
What is induction heating?
Induction heating is basically different with respect to most other heating processes. The heat develops in the workpiece itself, there is no need for a transmission medium (such as air, water or a mechanical connection) The electrical energy is transmitted to the workpiece trough a magnetic field. Induction heating is used since more than 50 years for comercial applications, but nevertheless it is not well known to the wide public.For induction heating the working piece must be electrically conductive such as metal or semiconductive as silicon. The highfrequency-energy is transmitted by way of an induction coil to the workpiece. The induction coil or simple "inductor" is geometrically adapted to the shape of the workpiece, in most applications it consists of a bent cupperpipe and is water-cooled.
Due to technical advances (semiconductors, transistors) the size and weight of present-day equipment could be minimized about to about 10% (with respect to previous models). The compact design, small weight and flexibility of the equipment and its advantageous price makes it possible to use induction heating for many applications.
In the following we try to show you some of the most frequently used ranges of activities, and at the same time help you to imagine the use of induction heating for your own purposes. There are a lot of various possible applications, and with the advances of induction heating many existing processes could also be improved with this technique!
What is induction heating?
Induction heating is basically different with respect to most other heating processes. The heat develops in the workpiece itself, there is no need for a transmission medium (such as air, water or a mechanical connection) The electrical energy is transmitted to the workpiece trough a magnetic field. Induction heating is used since more than 50 years for comercial applications, but nevertheless it is not well known to the wide public.For induction heating the working piece must be electrically conductive such as metal or semiconductive as silicon. The highfrequency-energy is transmitted by way of an induction coil to the workpiece. The induction coil or simple "inductor" is geometrically adapted to the shape of the workpiece, in most applications it consists of a bent cupperpipe and is water-cooled.
Due to technical advances (semiconductors, transistors) the size and weight of present-day equipment could be minimized about to about 10% (with respect to previous models). The compact design, small weight and flexibility of the equipment and its advantageous price makes it possible to use induction heating for many applications.
In the following we try to show you some of the most frequently used ranges of activities, and at the same time help you to imagine the use of induction heating for your own purposes. There are a lot of various possible applications, and with the advances of induction heating many existing processes could also be improved with this technique!
What is induction heating?
Induction heating is basically different with respect to most other heating processes. The heat develops in the workpiece itself, there is no need for a transmission medium (such as air, water or a mechanical connection) The electrical energy is transmitted to the workpiece trough a magnetic field. Induction heating is used since more than 50 years for comercial applications, but nevertheless it is not well known to the wide public.For induction heating the working piece must be electrically conductive such as metal or semiconductive as silicon. The highfrequency-energy is transmitted by way of an induction coil to the workpiece. The induction coil or simple "inductor" is geometrically adapted to the shape of the workpiece, in most applications it consists of a bent cupperpipe and is water-cooled.
Due to technical advances (semiconductors, transistors) the size and weight of present-day equipment could be minimized about to about 10% (with respect to previous models). The compact design, small weight and flexibility of the equipment and its advantageous price makes it possible to use induction heating for many applications.
In the following we try to show you some of the most frequently used ranges of activities, and at the same time help you to imagine the use of induction heating for your own purposes. There are a lot of various possible applications, and with the advances of induction heating many existing processes could also be improved with this technique!
What is induction heating?
Induction heating is basically different with respect to most other heating processes. The heat develops in the workpiece itself, there is no need for a transmission medium (such as air, water or a mechanical connection) The electrical energy is transmitted to the workpiece trough a magnetic field.Mittel- und Hochfrequenzgeneratoren
Für die industrielle induktive und kapazitive Erwärmung
Wir stellen induktive und kapazitive Mittel- und Hochfrequenzgeneratoren mit Leistungen von 1.5kW bis 600kW her. Die Arbeitsfrequenz liegt zwischen 5kHz und 27.12MHz.
1. Induktive Erwärmung:
Bei der induktiven Erwärmung besteht das Werkstück aus einem elektrisch leitenden Stoff wie Metall oder einem Halbleitermaterial (Silizium). Die Hochfrequenzenergie wird über einen Induktor auf das Werkstück übertragen. Er ist der goemetrischen Form der Erwärmungszone angepasst, meist aus einem Kupferhohlprofil gebogen und wassergekühlt.
Aus der breiten Palette der Anwendungsgebiete induktiver Mittel- und Hochfrequenzgeneratoren in der Industrie seinen einige typische Applikationen genannt:
bis 600kW, 5kHz .. 2.5MHz:
- Oberflächen- und Durchhärtung von Stahlteilen
- Schweissen und Glühen von Rohren
- Hartlöten, Weichlöten
- Blockerwärmung für Warmverformung
- Erwärmen und Schmelzen von Eisenmetallen, Nichteisenmetallen und anderen Materialien wie z.B. Glas
- Spannungsfrei Glühen
- Rekristallisationsglühen
- Epitaxie- Anlagen für die Halbleiterfabrikation
2. Kapazitive Erwärmung:
Bei der dielektrischen oder kapazitiven Erwärmung besteht das Werkstück aus einem elektrisch nichtleitenden Stoff, bei dem, befindet er sich im elektrischen Feld eines Kondensators, die Molekühle polarisiert werden. Handelt es sich dabei um ein Wechselfeld, so führen die so entstandenen Dipole Schwingungen aus, so dass die dem Feld zugeführte elektrische Energie im Material direkt in Wärme umgewandelt wird. Dabei ist der Erwärmungseffekt theoretisch zeitlich und örtlich gleichmässig über die gesamte Masse verteilt, in der Praxis ergibt sich über die Wärmeabfuhr an der Oberfläche eine Erwärmung von innen nach aussen. Da bei vorgegebenen Werkstoffvolumen, elektrischer Feldstärke und dem Verlustfaktor des Werkstoffes die Materialerwärmung mit der Frequenz wächst, ist dieses Verfahren nur mit Hochfrequenz durchzuführen.
Auch hierzu einige typische Anwendungsbeispiele:
(bis 200 kW, 13.56 / 27.12 MHz, stabil):
- Trocknen von Nahrungsmitteln, Textilien, Papier, chemischen Produkten, Giessereikernen, Rohtabak ...
- Holztrocknung und -verleimung
- Backen von Brot, Bisquits, ...
- Sterilisierung von Nahrungsmitteln und pharmazeutischen Produkten
- Auftauen von Tiefkühlprodukten
- Schmelzen von Schokolade ...
- Schäumen von Kunststoffen
- Aushärten von vorfabrizierten Betonbauteilen und Harz mit Glasfasern
- Schweissen von plastischen Materialien
- Vulkanisieren von verschiedenen Gummiprodukten
- Gelatinieren von Sprengstoff
Mittel- und Hochfrequenzgeneratoren
Für die industrielle induktive und kapazitive Erwärmung
Wir stellen induktive und kapazitive Mittel- und Hochfrequenzgeneratoren mit Leistungen von 1.5kW bis 600kW her. Die Arbeitsfrequenz liegt zwischen 5kHz und 27.12MHz.
1. Induktive Erwärmung:
Bei der induktiven Erwärmung besteht das Werkstück aus einem elektrisch leitenden Stoff wie Metall oder einem Halbleitermaterial (Silizium). Die Hochfrequenzenergie wird über einen Induktor auf das Werkstück übertragen. Er ist der goemetrischen Form der Erwärmungszone angepasst, meist aus einem Kupferhohlprofil gebogen und wassergekühlt.
Aus der breiten Palette der Anwendungsgebiete induktiver Mittel- und Hochfrequenzgeneratoren in der Industrie seinen einige typische Applikationen genannt:
bis 600kW, 5kHz .. 2.5MHz:
- Oberflächen- und Durchhärtung von Stahlteilen
- Schweissen und Glühen von Rohren
- Hartlöten, Weichlöten
- Blockerwärmung für Warmverformung
- Erwärmen und Schmelzen von Eisenmetallen, Nichteisenmetallen und anderen Materialien wie z.B. Glas
- Spannungsfrei Glühen
- Rekristallisationsglühen
- Epitaxie- Anlagen für die Halbleiterfabrikation
2. Kapazitive Erwärmung:
Bei der dielektrischen oder kapazitiven Erwärmung besteht das Werkstück aus einem elektrisch nichtleitenden Stoff, bei dem, befindet er sich im elektrischen Feld eines Kondensators, die Molekühle polarisiert werden. Handelt es sich dabei um ein Wechselfeld, so führen die so entstandenen Dipole Schwingungen aus, so dass die dem Feld zugeführte elektrische Energie im Material direkt in Wärme umgewandelt wird. Dabei ist der Erwärmungseffekt theoretisch zeitlich und örtlich gleichmässig über die gesamte Masse verteilt, in der Praxis ergibt sich über die Wärmeabfuhr an der Oberfläche eine Erwärmung von innen nach aussen. Da bei vorgegebenen Werkstoffvolumen, elektrischer Feldstärke und dem Verlustfaktor des Werkstoffes die Materialerwärmung mit der Frequenz wächst, ist dieses Verfahren nur mit Hochfrequenz durchzuführen.
Auch hierzu einige typische Anwendungsbeispiele:
(bis 200 kW, 13.56 / 27.12 MHz, stabil):
- Trocknen von Nahrungsmitteln, Textilien, Papier, chemischen Produkten, Giessereikernen, Rohtabak ...
- Holztrocknung und -verleimung
- Backen von Brot, Bisquits, ...
- Sterilisierung von Nahrungsmitteln und pharmazeutischen Produkten
- Auftauen von Tiefkühlprodukten
- Schmelzen von Schokolade ...
- Schäumen von Kunststoffen
- Aushärten von vorfabrizierten Betonbauteilen und Harz mit Glasfasern
- Schweissen von plastischen Materialien
- Vulkanisieren von verschiedenen Gummiprodukten
- Gelatinieren von Sprengstoff
Mittel- und Hochfrequenzgeneratoren
Für die industrielle induktive und kapazitive Erwärmung
Wir stellen induktive und kapazitive Mittel- und Hochfrequenzgeneratoren mit Leistungen von 1.5kW bis 600kW her. Die Arbeitsfrequenz liegt zwischen 5kHz und 27.12MHz.
1. Induktive Erwärmung:
Bei der induktiven Erwärmung besteht das Werkstück aus einem elektrisch leitenden Stoff wie Metall oder einem Halbleitermaterial (Silizium). Die Hochfrequenzenergie wird über einen Induktor auf das Werkstück übertragen. Er ist der goemetrischen Form der Erwärmungszone angepasst, meist aus einem Kupferhohlprofil gebogen und wassergekühlt.
Aus der breiten Palette der Anwendungsgebiete induktiver Mittel- und Hochfrequenzgeneratoren in der Industrie seinen einige typische Applikationen genannt:
bis 600kW, 5kHz .. 2.5MHz:
- Oberflächen- und Durchhärtung von Stahlteilen
- Schweissen und Glühen von Rohren
- Hartlöten, Weichlöten
- Blockerwärmung für Warmverformung
- Erwärmen und Schmelzen von Eisenmetallen, Nichteisenmetallen und anderen Materialien wie z.B. Glas
- Spannungsfrei Glühen
- Rekristallisationsglühen
- Epitaxie- Anlagen für die Halbleiterfabrikation
2. Kapazitive Erwärmung:
Bei der dielektrischen oder kapazitiven Erwärmung besteht das Werkstück aus einem elektrisch nichtleitenden Stoff, bei dem, befindet er sich im elektrischen Feld eines Kondensators, die Molekühle polarisiert werden. Handelt es sich dabei um ein Wechselfeld, so führen die so entstandenen Dipole Schwingungen aus, so dass die dem Feld zugeführte elektrische Energie im Material direkt in Wärme umgewandelt wird. Dabei ist der Erwärmungseffekt theoretisch zeitlich und örtlich gleichmässig über die gesamte Masse verteilt, in der Praxis ergibt sich über die Wärmeabfuhr an der Oberfläche eine Erwärmung von innen nach aussen. Da bei vorgegebenen Werkstoffvolumen, elektrischer Feldstärke und dem Verlustfaktor des Werkstoffes die Materialerwärmung mit der Frequenz wächst, ist dieses Verfahren nur mit Hochfrequenz durchzuführen.
Auch hierzu einige typische Anwendungsbeispiele:
(bis 200 kW, 13.56 / 27.12 MHz, stabil):
- Trocknen von Nahrungsmitteln, Textilien, Papier, chemischen Produkten, Giessereikernen, Rohtabak ...
- Holztrocknung und -verleimung
- Backen von Brot, Bisquits, ...
- Sterilisierung von Nahrungsmitteln und pharmazeutischen Produkten
- Auftauen von Tiefkühlprodukten
- Schmelzen von Schokolade ...
- Schäumen von Kunststoffen
- Aushärten von vorfabrizierten Betonbauteilen und Harz mit Glasfasern
- Schweissen von plastischen Materialien
- Vulkanisieren von verschiedenen Gummiprodukten
- Gelatinieren von Sprengstoff
Mittel- und Hochfrequenzgeneratoren
Für die industrielle induktive und kapazitive Erwärmung
Wir stellen induktive und kapazitive Mittel- und Hochfrequenzgeneratoren mit Leistungen von 1.5kW bis 600kW her. Die Arbeitsfrequenz liegt zwischen 5kHz und 27.12MHz.
1. Induktive Erwärmung:
Bei der induktiven Erwärmung besteht das Werkstück aus einem elektrisch leitenden Stoff wie Metall oder einem Halbleitermaterial (Silizium). Die Hochfrequenzenergie wird über einen Induktor auf das Werkstück übertragen. Er ist der goemetrischen Form der Erwärmungszone angepasst, meist aus einem Kupferhohlprofil gebogen und wassergekühlt.
Aus der breiten Palette der Anwendungsgebiete induktiver Mittel- und Hochfrequenzgeneratoren in der Industrie seinen einige typische Applikationen genannt:
bis 600kW, 5kHz .. 2.5MHz:
- Oberflächen- und Durchhärtung von Stahlteilen
- Schweissen und Glühen von Rohren
- Hartlöten, Weichlöten
- Blockerwärmung für Warmverformung
- Erwärmen und Schmelzen von Eisenmetallen, Nichteisenmetallen und anderen Materialien wie z.B. Glas
- Spannungsfrei Glühen
- Rekristallisationsglühen
- Epitaxie- Anlagen für die Halbleiterfabrikation
2. Kapazitive Erwärmung:
Bei der dielektrischen oder kapazitiven Erwärmung besteht das Werkstück aus einem elektrisch nichtleitenden Stoff, bei dem, befindet er sich im elektrischen Feld eines Kondensators, die Molekühle polarisiert werden. Handelt es sich dabei um ein Wechselfeld, so führen die so entstandenen Dipole Schwingungen aus, so dass die dem Feld zugeführte elektrische Energie im Material direkt in Wärme umgewandelt wird. Dabei ist der Erwärmungseffekt theoretisch zeitlich und örtlich gleichmässig über die gesamte Masse verteilt, in der Praxis ergibt sich über die Wärmeabfuhr an der Oberfläche eine Erwärmung von innen nach aussen. Da bei vorgegebenen Werkstoffvolumen, elektrischer Feldstärke und dem Verlustfaktor des Werkstoffes die Materialerwärmung mit der Frequenz wächst, ist dieses Verfahren nur mit Hochfrequenz durchzuführen.
Auch hierzu einige typische Anwendungsbeispiele:
(bis 200 kW, 13.56 / 27.12 MHz, stabil):
- Trocknen von Nahrungsmitteln, Textilien, Papier, chemischen Produkten, Giessereikernen, Rohtabak ...
- Holztrocknung und -verleimung
- Backen von Brot, Bisquits, ...
- Sterilisierung von Nahrungsmitteln und pharmazeutischen Produkten
- Auftauen von Tiefkühlprodukten
- Schmelzen von Schokolade ...
- Schäumen von Kunststoffen
- Aushärten von vorfabrizierten Betonbauteilen und Harz mit Glasfasern
- Schweissen von plastischen Materialien
- Vulkanisieren von verschiedenen Gummiprodukten
- Gelatinieren von Sprengstoff
Mittel- und Hochfrequenzgeneratoren
Für die industrielle induktive und kapazitive Erwärmung
Wir stellen induktive und kapazitive Mittel- und Hochfrequenzgeneratoren mit Leistungen von 1.5kW bis 600kW her. Die Arbeitsfrequenz liegt zwischen 5kHz und 27.12MHz.
1. Induktive Erwärmung:
Bei der induktiven Erwärmung besteht das Werkstück aus einem elektrisch leitenden Stoff wie Metall oder einem Halbleitermaterial (Silizium). Die Hochfrequenzenergie wird über einen Induktor auf das Werkstück übertragen. Er ist der goemetrischen Form der Erwärmungszone angepasst, meist aus einem Kupferhohlprofil gebogen und wassergekühlt.
Aus der breiten Palette der Anwendungsgebiete induktiver Mittel- und Hochfrequenzgeneratoren in der Industrie seinen einige typische Applikationen genannt:
bis 600kW, 5kHz .. 2.5MHz:
- Oberflächen- und Durchhärtung von Stahlteilen
- Schweissen und Glühen von Rohren
- Hartlöten, Weichlöten
- Blockerwärmung für Warmverformung
- Erwärmen und Schmelzen von Eisenmetallen, Nichteisenmetallen und anderen Materialien wie z.B. Glas
- Spannungsfrei Glühen
- Rekristallisationsglühen
- Epitaxie- Anlagen für die Halbleiterfabrikation
2. Kapazitive Erwärmung:
Bei der dielektrischen oder kapazitiven Erwärmung besteht das Werkstück aus einem elektrisch nichtleitenden Stoff, bei dem, befindet er sich im elektrischen Feld eines Kondensators, die Molekühle polarisiert werden. Handelt es sich dabei um ein Wechselfeld, so führen die so entstandenen Dipole Schwingungen aus, so dass die dem Feld zugeführte elektrische Energie im Material direkt in Wärme umgewandelt wird. Dabei ist der Erwärmungseffekt theoretisch zeitlich und örtlich gleichmässig über die gesamte Masse verteilt, in der Praxis ergibt sich über die Wärmeabfuhr an der Oberfläche eine Erwärmung von innen nach aussen. Da bei vorgegebenen Werkstoffvolumen, elektrischer Feldstärke und dem Verlustfaktor des Werkstoffes die Materialerwärmung mit der Frequenz wächst, ist dieses Verfahren nur mit Hochfrequenz durchzuführen.
Auch hierzu einige typische Anwendungsbeispiele:
(bis 200 kW, 13.56 / 27.12 MHz, stabil):
- Trocknen von Nahrungsmitteln, Textilien, Papier, chemischen Produkten, Giessereikernen, Rohtabak ...
- Holztrocknung und -verleimung
- Backen von Brot, Bisquits, ...
- Sterilisierung von Nahrungsmitteln und pharmazeutischen Produkten
- Auftauen von Tiefkühlprodukten
- Schmelzen von Schokolade ...
- Schäumen von Kunststoffen
- Aushärten von vorfabrizierten Betonbauteilen und Harz mit Glasfasern
- Schweissen von plastischen Materialien
- Vulkanisieren von verschiedenen Gummiprodukten
- Gelatinieren von Sprengstoff
Mittel- und Hochfrequenzgeneratoren
Für die industrielle induktive und kapazitive Erwärmung
Wir stellen induktive und kapazitive Mittel- und Hochfrequenzgeneratoren mit Leistungen von 1.5kW bis 600kW her. Die Arbeitsfrequenz liegt zwischen 5kHz und 27.12MHz.
1. Induktive Erwärmung:
Bei der induktiven Erwärmung besteht das Werkstück aus einem elektrisch leitenden Stoff wie Metall oder einem Halbleitermaterial (Silizium). Die Hochfrequenzenergie wird über einen Induktor auf das Werkstück übertragen. Er ist der goemetrischen Form der Erwärmungszone angepasst, meist aus einem Kupferhohlprofil gebogen und wassergekühlt.
Aus der breiten Palette der Anwendungsgebiete induktiver Mittel- und Hochfrequenzgeneratoren in der Industrie seinen einige typische Applikationen genannt:
bis 600kW, 5kHz .. 2.5MHz:
- Oberflächen- und Durchhärtung von Stahlteilen
- Schweissen und Glühen von Rohren
- Hartlöten, Weichlöten
- Blockerwärmung für Warmverformung
- Erwärmen und Schmelzen von Eisenmetallen, Nichteisenmetallen und anderen Materialien wie z.B. Glas
- Spannungsfrei Glühen
- Rekristallisationsglühen
- Epitaxie- Anlagen für die Halbleiterfabrikation
2. Kapazitive Erwärmung:
Bei der dielektrischen oder kapazitiven Erwärmung besteht das Werkstück aus einem elektrisch nichtleitenden Stoff, bei dem, befindet er sich im elektrischen Feld eines Kondensators, die Molekühle polarisiert werden. Handelt es sich dabei um ein Wechselfeld, so führen die so entstandenen Dipole Schwingungen aus, so dass die dem Feld zugeführte elektrische Energie im Material direkt in Wärme umgewandelt wird. Dabei ist der Erwärmungseffekt theoretisch zeitlich und örtlich gleichmässig über die gesamte Masse verteilt, in der Praxis ergibt sich über die Wärmeabfuhr an der Oberfläche eine Erwärmung von innen nach aussen. Da bei vorgegebenen Werkstoffvolumen, elektrischer Feldstärke und dem Verlustfaktor des Werkstoffes die Materialerwärmung mit der Frequenz wächst, ist dieses Verfahren nur mit Hochfrequenz durchzuführen.
Auch hierzu einige typische Anwendungsbeispiele:
(bis 200 kW, 13.56 / 27.12 MHz, stabil):
- Trocknen von Nahrungsmitteln, Textilien, Papier, chemischen Produkten, Giessereikernen, Rohtabak ...
- Holztrocknung und -verleimung
- Backen von Brot, Bisquits, ...
- Sterilisierung von Nahrungsmitteln und pharmazeutischen Produkten
- Auftauen von Tiefkühlprodukten
- Schmelzen von Schokolade ...
- Schäumen von Kunststoffen
- Aushärten von vorfabrizierten Betonbauteilen und Harz mit Glasfasern
- Schweissen von plastischen Materialien
- Vulkanisieren von verschiedenen Gummiprodukten
- Gelatinieren von Sprengstoff
Mittel- und Hochfrequenzgeneratoren
Für die industrielle induktive und kapazitive Erwärmung
Wir stellen induktive und kapazitive Mittel- und Hochfrequenzgeneratoren mit Leistungen von 1.5kW bis 600kW her. Die Arbeitsfrequenz liegt zwischen 5kHz und 27.12MHz.
1. Induktive Erwärmung:
Bei der induktiven Erwärmung besteht das Werkstück aus einem elektrisch leitenden Stoff wie Metall oder einem Halbleitermaterial (Silizium). Die Hochfrequenzenergie wird über einen Induktor auf das Werkstück übertragen. Er ist der goemetrischen Form der Erwärmungszone angepasst, meist aus einem Kupferhohlprofil gebogen und wassergekühlt.
Aus der breiten Palette der Anwendungsgebiete induktiver Mittel- und Hochfrequenzgeneratoren in der Industrie seinen einige typische Applikationen genannt:
bis 600kW, 5kHz .. 2.5MHz:
- Oberflächen- und Durchhärtung von Stahlteilen
- Schweissen und Glühen von Rohren
- Hartlöten, Weichlöten
- Blockerwärmung für Warmverformung
- Erwärmen und Schmelzen von Eisenmetallen, Nichteisenmetallen und anderen Materialien wie z.B. Glas
- Spannungsfrei Glühen
- Rekristallisationsglühen
- Epitaxie- Anlagen für die Halbleiterfabrikation
2. Kapazitive Erwärmung:
Bei der dielektrischen oder kapazitiven Erwärmung besteht das Werkstück aus einem elektrisch nichtleitenden Stoff, bei dem, befindet er sich im elektrischen Feld eines Kondensators, die Molekühle polarisiert werden. Handelt es sich dabei um ein Wechselfeld, so führen die so entstandenen Dipole Schwingungen aus, so dass die dem Feld zugeführte elektrische Energie im Material direkt in Wärme umgewandelt wird. Dabei ist der Erwärmungseffekt theoretisch zeitlich und örtlich gleichmässig über die gesamte Masse verteilt, in der Praxis ergibt sich über die Wärmeabfuhr an der Oberfläche eine Erwärmung von innen nach aussen. Da bei vorgegebenen Werkstoffvolumen, elektrischer Feldstärke und dem Verlustfaktor des Werkstoffes die Materialerwärmung mit der Frequenz wächst, ist dieses Verfahren nur mit Hochfrequenz durchzuführen.
Auch hierzu einige typische Anwendungsbeispiele:
(bis 200 kW, 13.56 / 27.12 MHz, stabil):
- Trocknen von Nahrungsmitteln, Textilien, Papier, chemischen Produkten, Giessereikernen, Rohtabak ...
- Holztrocknung und -verleimung
- Backen von Brot, Bisquits, ...
- Sterilisierung von Nahrungsmitteln und pharmazeutischen Produkten
- Auftauen von Tiefkühlprodukten
- Schmelzen von Schokolade ...
- Schäumen von Kunststoffen
- Aushärten von vorfabrizierten Betonbauteilen und Harz mit Glasfasern
- Schweissen von plastischen Materialien
- Vulkanisieren von verschiedenen Gummiprodukten
- Gelatinieren von Sprengstoff
Mittel- und Hochfrequenzgeneratoren
Für die industrielle induktive und kapazitive Erwärmung
Wir stellen induktive und kapazitive Mittel- und Hochfrequenzgeneratoren mit Leistungen von 1.5kW bis 600kW her. Die Arbeitsfrequenz liegt zwischen 5kHz und 27.12MHz.
1. Induktive Erwärmung:
Bei der induktiven Erwärmung besteht das Werkstück aus einem elektrisch leitenden Stoff wie Metall oder einem Halbleitermaterial (Silizium). Die Hochfrequenzenergie wird über einen Induktor auf das Werkstück übertragen. Er ist der goemetrischen Form der Erwärmungszone angepasst, meist aus einem Kupferhohlprofil gebogen und wassergekühlt.
Aus der breiten Palette der Anwendungsgebiete induktiver Mittel- und Hochfrequenzgeneratoren in der Industrie seinen einige typische Applikationen genannt:
bis 600kW, 5kHz .. 2.5MHz:
- Oberflächen- und Durchhärtung von Stahlteilen
- Schweissen und Glühen von Rohren
- Hartlöten, Weichlöten
- Blockerwärmung für Warmverformung
- Erwärmen und Schmelzen von Eisenmetallen, Nichteisenmetallen und anderen Materialien wie z.B. Glas
- Spannungsfrei Glühen
- Rekristallisationsglühen
- Epitaxie- Anlagen für die Halbleiterfabrikation
2. Kapazitive Erwärmung:
Bei der dielektrischen oder kapazitiven Erwärmung besteht das Werkstück aus einem elektrisch nichtleitenden Stoff, bei dem, befindet er sich im elektrischen Feld eines Kondensators, die Molekühle polarisiert werden. Handelt es sich dabei um ein Wechselfeld, so führen die so entstandenen Dipole Schwingungen aus, so dass die dem Feld zugeführte elektrische Energie im Material direkt in Wärme umgewandelt wird. Dabei ist der Erwärmungseffekt theoretisch zeitlich und örtlich gleichmässig über die gesamte Masse verteilt, in der Praxis ergibt sich über die Wärmeabfuhr an der Oberfläche eine Erwärmung von innen nach aussen. Da bei vorgegebenen Werkstoffvolumen, elektrischer Feldstärke und dem Verlustfaktor des Werkstoffes die Materialerwärmung mit der Frequenz wächst, ist dieses Verfahren nur mit Hochfrequenz durchzuführen.
Auch hierzu einige typische Anwendungsbeispiele:
(bis 200 kW, 13.56 / 27.12 MHz, stabil):
- Trocknen von Nahrungsmitteln, Textilien, Papier, chemischen Produkten, Giessereikernen, Rohtabak ...
- Holztrocknung und -verleimung
- Backen von Brot, Bisquits, ...
- Sterilisierung von Nahrungsmitteln und pharmazeutischen Produkten
- Auftauen von Tiefkühlprodukten
- Schmelzen von Schokolade ...
- Schäumen von Kunststoffen
- Aushärten von vorfabrizierten Betonbauteilen und Harz mit Glasfasern
- Schweissen von plastischen Materialien
- Vulkanisieren von verschiedenen Gummiprodukten
- Gelatinieren von Sprengstoff
Mittel- und Hochfrequenzgeneratoren
Für die industrielle induktive und kapazitive Erwärmung
Wir stellen induktive und kapazitive Mittel- und Hochfrequenzgeneratoren mit Leistungen von 1.5kW bis 600kW her. Die Arbeitsfrequenz liegt zwischen 5kHz und 27.12MHz.
1. Induktive Erwärmung:
Bei der induktiven Erwärmung besteht das Werkstück aus einem elektrisch leitenden Stoff wie Metall oder einem Halbleitermaterial (Silizium). Die Hochfrequenzenergie wird über einen Induktor auf das Werkstück übertragen. Er ist der goemetrischen Form der Erwärmungszone angepasst, meist aus einem Kupferhohlprofil gebogen und wassergekühlt.
Aus der breiten Palette der Anwendungsgebiete induktiver Mittel- und Hochfrequenzgeneratoren in der Industrie seinen einige typische Applikationen genannt:
bis 600kW, 5kHz .. 2.5MHz:
- Oberflächen- und Durchhärtung von Stahlteilen
- Schweissen und Glühen von Rohren
- Hartlöten, Weichlöten
- Blockerwärmung für Warmverformung
- Erwärmen und Schmelzen von Eisenmetallen, Nichteisenmetallen und anderen Materialien wie z.B. Glas
- Spannungsfrei Glühen
- Rekristallisationsglühen
- Epitaxie- Anlagen für die Halbleiterfabrikation
2. Kapazitive Erwärmung:
Bei der dielektrischen oder kapazitiven Erwärmung besteht das Werkstück aus einem elektrisch nichtleitenden Stoff, bei dem, befindet er sich im elektrischen Feld eines Kondensators, die Molekühle polarisiert werden. Handelt es sich dabei um ein Wechselfeld, so führen die so entstandenen Dipole Schwingungen aus, so dass die dem Feld zugeführte elektrische Energie im Material direkt in Wärme umgewandelt wird. Dabei ist der Erwärmungseffekt theoretisch zeitlich und örtlich gleichmässig über die gesamte Masse verteilt, in der Praxis ergibt sich über die Wärmeabfuhr an der Oberfläche eine Erwärmung von innen nach aussen. Da bei vorgegebenen Werkstoffvolumen, elektrischer Feldstärke und dem Verlustfaktor des Werkstoffes die Materialerwärmung mit der Frequenz wächst, ist dieses Verfahren nur mit Hochfrequenz durchzuführen.
Auch hierzu einige typische Anwendungsbeispiele:
(bis 200 kW, 13.56 / 27.12 MHz, stabil):
- Trocknen von Nahrungsmitteln, Textilien, Papier, chemischen Produkten, Giessereikernen, Rohtabak ...
- Holztrocknung und -verleimung
- Backen von Brot, Bisquits, ...
- Sterilisierung von Nahrungsmitteln und pharmazeutischen Produkten
- Auftauen von Tiefkühlprodukten
- Schmelzen von Schokolade ...
- Schäumen von Kunststoffen
- Aushärten von vorfabrizierten Betonbauteilen und Harz mit Glasfasern
- Schweissen von plastischen Materialien
- Vulkanisieren von verschiedenen Gummiprodukten
- Gelatinieren von Sprengstoff
Mittel- und Hochfrequenzgeneratoren
Für die industrielle induktive und kapazitive Erwärmung
Wir stellen induktive und kapazitive Mittel- und Hochfrequenzgeneratoren mit Leistungen von 1.5kW bis 600kW her. Die Arbeitsfrequenz liegt zwischen 5kHz und 27.12MHz.
1. Induktive Erwärmung:
Bei der induktiven Erwärmung besteht das Werkstück aus einem elektrisch leitenden Stoff wie Metall oder einem Halbleitermaterial (Silizium). Die Hochfrequenzenergie wird über einen Induktor auf das Werkstück übertragen. Er ist der goemetrischen Form der Erwärmungszone angepasst, meist aus einem Kupferhohlprofil gebogen und wassergekühlt.
Aus der breiten Palette der Anwendungsgebiete induktiver Mittel- und Hochfrequenzgeneratoren in der Industrie seinen einige typische Applikationen genannt:
bis 600kW, 5kHz .. 2.5MHz:
- Oberflächen- und Durchhärtung von Stahlteilen
- Schweissen und Glühen von Rohren
- Hartlöten, Weichlöten
- Blockerwärmung für Warmverformung
- Erwärmen und Schmelzen von Eisenmetallen, Nichteisenmetallen und anderen Materialien wie z.B. Glas
- Spannungsfrei Glühen
- Rekristallisationsglühen
- Epitaxie- Anlagen für die Halbleiterfabrikation
2. Kapazitive Erwärmung:
Bei der dielektrischen oder kapazitiven Erwärmung besteht das Werkstück aus einem elektrisch nichtleitenden Stoff, bei dem, befindet er sich im elektrischen Feld eines Kondensators, die Molekühle polarisiert werden. Handelt es sich dabei um ein Wechselfeld, so führen die so entstandenen Dipole Schwingungen aus, so dass die dem Feld zugeführte elektrische Energie im Material direkt in Wärme umgewandelt wird. Dabei ist der Erwärmungseffekt theoretisch zeitlich und örtlich gleichmässig über die gesamte Masse verteilt, in der Praxis ergibt sich über die Wärmeabfuhr an der Oberfläche eine Erwärmung von innen nach aussen. Da bei vorgegebenen Werkstoffvolumen, elektrischer Feldstärke und dem Verlustfaktor des Werkstoffes die Materialerwärmung mit der Frequenz wächst, ist dieses Verfahren nur mit Hochfrequenz durchzuführen.
Auch hierzu einige typische Anwendungsbeispiele:
(bis 200 kW, 13.56 / 27.12 MHz, stabil):
- Trocknen von Nahrungsmitteln, Textilien, Papier, chemischen Produkten, Giessereikernen, Rohtabak ...
- Holztrocknung und -verleimung
- Backen von Brot, Bisquits, ...
- Sterilisierung von Nahrungsmitteln und pharmazeutischen Produkten
- Auftauen von Tiefkühlprodukten
- Schmelzen von Schokolade ...
- Schäumen von Kunststoffen
- Aushärten von vorfabrizierten Betonbauteilen und Harz mit Glasfasern
- Schweissen von plastischen Materialien
- Vulkanisieren von verschiedenen Gummiprodukten
- Gelatinieren von Sprengstoff
We manufacture inductive and capacitive middle and high frequency generators with an output power ranging from 1.5 kW to 600 kW. The working frequency is between 5 kHz and 27.12 MHz.
Inductive Heating
The work piece in case of inductive heating consists of an electrically conductive matter or a semiconductor (silicon). The high frequency energy is transferred to the work piece by means of an inductor. This inductor is adapted to the geometric form of the heating zone, is in most cases made of bent copper hollow section and is cooled with water.
Some typical applications out of the wide variety of inductive medium and high frequency generators for industrial applications are listed below (up to 600 kW, 5 kHz to 2.5 MHz):
- Surface hardening and full hardening of steel components
- Welding and annealing of pipes
- Brazing, soldering
- Block heating for hot shaping
- Heating and melting of ferrous metals, non-ferrous metals and other materials, such as glass
- Unstressed annealing
- Recrystallization annealing
- Epitaxy plants for semiconductor fabrication
Capacitive Heating
The work piece in case of dielectric or capacitive heating consists of electrically non-conductive material, whereby its molecules are being polarized if it is placed within the electrical field of a capacitor. If this should be an alternating field, then the dipoles thus generated will perform oscillations, so that the electrical energy introduced in the field will be converted directly to heat within the material. In theory, the heating effect will be distributed evenly with respect to time and location over the entire mass, but in practical use the heat will flow from the inside to the outside to a certain degree due to the heat dissipation on the surface. Due to the heating-up of the material with a given work piece volume, electrical field strength and material loss factor will increase with frequency, this procedure functions only with high frequency.
Some typical applications are also listed in the following (up to 200 kW, 13.56 / 27.12 MHz, stable):
- Drying of foods, textiles, paper, chemical products, foundry cores, raw tobacco... - Drying and bonding of wood - Baking of bread, biscuitS... - Sterilization of food and pharmaceutical products - Thawing of deep-freeze products - Melting of chocolate... - Foaming of synthetic materials - Hardening of prefabricated concrete parts and fiber-reinforced resins - Welding of plastic materials - Vulcanization of various rubber products - Gelatification of explosives
We do, however, also manufacture equipment for special purposes. Please contact us, if you would like to receive detailed information.
We manufacture inductive and capacitive middle and high frequency generators with an output power ranging from 1.5 kW to 600 kW. The working frequency is between 5 kHz and 27.12 MHz.
Inductive Heating
The work piece in case of inductive heating consists of an electrically conductive matter or a semiconductor (silicon). The high frequency energy is transferred to the work piece by means of an inductor. This inductor is adapted to the geometric form of the heating zone, is in most cases made of bent copper hollow section and is cooled with water.
Some typical applications out of the wide variety of inductive medium and high frequency generators for industrial applications are listed below (up to 600 kW, 5 kHz to 2.5 MHz):
- Surface hardening and full hardening of steel components
- Welding and annealing of pipes
- Brazing, soldering
- Block heating for hot shaping
- Heating and melting of ferrous metals, non-ferrous metals and other materials, such as glass
- Unstressed annealing
- Recrystallization annealing
- Epitaxy plants for semiconductor fabrication
Capacitive Heating
The work piece in case of dielectric or capacitive heating consists of electrically non-conductive material, whereby its molecules are being polarized if it is placed within the electrical field of a capacitor. If this should be an alternating field, then the dipoles thus generated will perform oscillations, so that the electrical energy introduced in the field will be converted directly to heat within the material. In theory, the heating effect will be distributed evenly with respect to time and location over the entire mass, but in practical use the heat will flow from the inside to the outside to a certain degree due to the heat dissipation on the surface. Due to the heating-up of the material with a given work piece volume, electrical field strength and material loss factor will increase with frequency, this procedure functions only with high frequency.
Some typical applications are also listed in the following (up to 200 kW, 13.56 / 27.12 MHz, stable):
- Drying of foods, textiles, paper, chemical products, foundry cores, raw tobacco... - Drying and bonding of wood - Baking of bread, biscuitS... - Sterilization of food and pharmaceutical products - Thawing of deep-freeze products - Melting of chocolate... - Foaming of synthetic materials - Hardening of prefabricated concrete parts and fiber-reinforced resins - Welding of plastic materials - Vulcanization of various rubber products - Gelatification of explosives
We do, however, also manufacture equipment for special purposes. Please contact us, if you would like to receive detailed information.
We manufacture inductive and capacitive middle and high frequency generators with an output power ranging from 1.5 kW to 600 kW. The working frequency is between 5 kHz and 27.12 MHz.
Inductive Heating
The work piece in case of inductive heating consists of an electrically conductive matter or a semiconductor (silicon). The high frequency energy is transferred to the work piece by means of an inductor. This inductor is adapted to the geometric form of the heating zone, is in most cases made of bent copper hollow section and is cooled with water.
Some typical applications out of the wide variety of inductive medium and high frequency generators for industrial applications are listed below (up to 600 kW, 5 kHz to 2.5 MHz):
- Surface hardening and full hardening of steel components
- Welding and annealing of pipes
- Brazing, soldering
- Block heating for hot shaping
- Heating and melting of ferrous metals, non-ferrous metals and other materials, such as glass
- Unstressed annealing
- Recrystallization annealing
- Epitaxy plants for semiconductor fabrication
Capacitive Heating
The work piece in case of dielectric or capacitive heating consists of electrically non-conductive material, whereby its molecules are being polarized if it is placed within the electrical field of a capacitor. If this should be an alternating field, then the dipoles thus generated will perform oscillations, so that the electrical energy introduced in the field will be converted directly to heat within the material. In theory, the heating effect will be distributed evenly with respect to time and location over the entire mass, but in practical use the heat will flow from the inside to the outside to a certain degree due to the heat dissipation on the surface. Due to the heating-up of the material with a given work piece volume, electrical field strength and material loss factor will increase with frequency, this procedure functions only with high frequency.
Some typical applications are also listed in the following (up to 200 kW, 13.56 / 27.12 MHz, stable):
- Drying of foods, textiles, paper, chemical products, foundry cores, raw tobacco... - Drying and bonding of wood - Baking of bread, biscuitS... - Sterilization of food and pharmaceutical products - Thawing of deep-freeze products - Melting of chocolate... - Foaming of synthetic materials - Hardening of prefabricated concrete parts and fiber-reinforced resins - Welding of plastic materials - Vulcanization of various rubber products - Gelatification of explosives
We do, however, also manufacture equipment for special purposes. Please contact us, if you would like to receive detailed information.
We manufacture inductive and capacitive middle and high frequency generators with an output power ranging from 1.5 kW to 600 kW. The working frequency is between 5 kHz and 27.12 MHz.
Inductive Heating
The work piece in case of inductive heating consists of an electrically conductive matter or a semiconductor (silicon). The high frequency energy is transferred to the work piece by means of an inductor. This inductor is adapted to the geometric form of the heating zone, is in most cases made of bent copper hollow section and is cooled with water.
Some typical applications out of the wide variety of inductive medium and high frequency generators for industrial applications are listed below (up to 600 kW, 5 kHz to 2.5 MHz):
- Surface hardening and full hardening of steel components
- Welding and annealing of pipes
- Brazing, soldering
- Block heating for hot shaping
- Heating and melting of ferrous metals, non-ferrous metals and other materials, such as glass
- Unstressed annealing
- Recrystallization annealing
- Epitaxy plants for semiconductor fabrication
Capacitive Heating
The work piece in case of dielectric or capacitive heating consists of electrically non-conductive material, whereby its molecules are being polarized if it is placed within the electrical field of a capacitor. If this should be an alternating field, then the dipoles thus generated will perform oscillations, so that the electrical energy introduced in the field will be converted directly to heat within the material. In theory, the heating effect will be distributed evenly with respect to time and location over the entire mass, but in practical use the heat will flow from the inside to the outside to a certain degree due to the heat dissipation on the surface. Due to the heating-up of the material with a given work piece volume, electrical field strength and material loss factor will increase with frequency, this procedure functions only with high frequency.
Some typical applications are also listed in the following (up to 200 kW, 13.56 / 27.12 MHz, stable):
- Drying of foods, textiles, paper, chemical products, foundry cores, raw tobacco... - Drying and bonding of wood - Baking of bread, biscuitS... - Sterilization of food and pharmaceutical products - Thawing of deep-freeze products - Melting of chocolate... - Foaming of synthetic materials - Hardening of prefabricated concrete parts and fiber-reinforced resins - Welding of plastic materials - Vulcanization of various rubber products - Gelatification of explosives
We do, however, also manufacture equipment for special purposes. Please contact us, if you would like to receive detailed information.
We manufacture inductive and capacitive middle and high frequency generators with an output power ranging from 1.5 kW to 600 kW. The working frequency is between 5 kHz and 27.12 MHz.
Inductive Heating
The work piece in case of inductive heating consists of an electrically conductive matter or a semiconductor (silicon). The high frequency energy is transferred to the work piece by means of an inductor. This inductor is adapted to the geometric form of the heating zone, is in most cases made of bent copper hollow section and is cooled with water.
Some typical applications out of the wide variety of inductive medium and high frequency generators for industrial applications are listed below (up to 600 kW, 5 kHz to 2.5 MHz):
- Surface hardening and full hardening of steel components
- Welding and annealing of pipes
- Brazing, soldering
- Block heating for hot shaping
- Heating and melting of ferrous metals, non-ferrous metals and other materials, such as glass
- Unstressed annealing
- Recrystallization annealing
- Epitaxy plants for semiconductor fabrication
Capacitive Heating
The work piece in case of dielectric or capacitive heating consists of electrically non-conductive material, whereby its molecules are being polarized if it is placed within the electrical field of a capacitor. If this should be an alternating field, then the dipoles thus generated will perform oscillations, so that the electrical energy introduced in the field will be converted directly to heat within the material. In theory, the heating effect will be distributed evenly with respect to time and location over the entire mass, but in practical use the heat will flow from the inside to the outside to a certain degree due to the heat dissipation on the surface. Due to the heating-up of the material with a given work piece volume, electrical field strength and material loss factor will increase with frequency, this procedure functions only with high frequency.
Some typical applications are also listed in the following (up to 200 kW, 13.56 / 27.12 MHz, stable):
- Drying of foods, textiles, paper, chemical products, foundry cores, raw tobacco... - Drying and bonding of wood - Baking of bread, biscuitS... - Sterilization of food and pharmaceutical products - Thawing of deep-freeze products - Melting of chocolate... - Foaming of synthetic materials - Hardening of prefabricated concrete parts and fiber-reinforced resins - Welding of plastic materials - Vulcanization of various rubber products - Gelatification of explosives
We do, however, also manufacture equipment for special purposes. Please contact us, if you would like to receive detailed information.
We manufacture inductive and capacitive middle and high frequency generators with an output power ranging from 1.5 kW to 600 kW. The working frequency is between 5 kHz and 27.12 MHz.
Inductive Heating
The work piece in case of inductive heating consists of an electrically conductive matter or a semiconductor (silicon). The high frequency energy is transferred to the work piece by means of an inductor. This inductor is adapted to the geometric form of the heating zone, is in most cases made of bent copper hollow section and is cooled with water.
Some typical applications out of the wide variety of inductive medium and high frequency generators for industrial applications are listed below (up to 600 kW, 5 kHz to 2.5 MHz):
- Surface hardening and full hardening of steel components
- Welding and annealing of pipes
- Brazing, soldering
- Block heating for hot shaping
- Heating and melting of ferrous metals, non-ferrous metals and other materials, such as glass
- Unstressed annealing
- Recrystallization annealing
- Epitaxy plants for semiconductor fabrication
Capacitive Heating
The work piece in case of dielectric or capacitive heating consists of electrically non-conductive material, whereby its molecules are being polarized if it is placed within the electrical field of a capacitor. If this should be an alternating field, then the dipoles thus generated will perform oscillations, so that the electrical energy introduced in the field will be converted directly to heat within the material. In theory, the heating effect will be distributed evenly with respect to time and location over the entire mass, but in practical use the heat will flow from the inside to the outside to a certain degree due to the heat dissipation on the surface. Due to the heating-up of the material with a given work piece volume, electrical field strength and material loss factor will increase with frequency, this procedure functions only with high frequency.
Some typical applications are also listed in the following (up to 200 kW, 13.56 / 27.12 MHz, stable):
- Drying of foods, textiles, paper, chemical products, foundry cores, raw tobacco... - Drying and bonding of wood - Baking of bread, biscuitS... - Sterilization of food and pharmaceutical products - Thawing of deep-freeze products - Melting of chocolate... - Foaming of synthetic materials - Hardening of prefabricated concrete parts and fiber-reinforced resins - Welding of plastic materials - Vulcanization of various rubber products - Gelatification of explosives
We do, however, also manufacture equipment for special purposes. Please contact us, if you would like to receive detailed information.
We manufacture inductive and capacitive middle and high frequency generators with an output power ranging from 1.5 kW to 600 kW. The working frequency is between 5 kHz and 27.12 MHz.
Inductive Heating
The work piece in case of inductive heating consists of an electrically conductive matter or a semiconductor (silicon). The high frequency energy is transferred to the work piece by means of an inductor. This inductor is adapted to the geometric form of the heating zone, is in most cases made of bent copper hollow section and is cooled with water.
Some typical applications out of the wide variety of inductive medium and high frequency generators for industrial applications are listed below (up to 600 kW, 5 kHz to 2.5 MHz):
- Surface hardening and full hardening of steel components
- Welding and annealing of pipes
- Brazing, soldering
- Block heating for hot shaping
- Heating and melting of ferrous metals, non-ferrous metals and other materials, such as glass
- Unstressed annealing
- Recrystallization annealing
- Epitaxy plants for semiconductor fabrication
Capacitive Heating
The work piece in case of dielectric or capacitive heating consists of electrically non-conductive material, whereby its molecules are being polarized if it is placed within the electrical field of a capacitor. If this should be an alternating field, then the dipoles thus generated will perform oscillations, so that the electrical energy introduced in the field will be converted directly to heat within the material. In theory, the heating effect will be distributed evenly with respect to time and location over the entire mass, but in practical use the heat will flow from the inside to the outside to a certain degree due to the heat dissipation on the surface. Due to the heating-up of the material with a given work piece volume, electrical field strength and material loss factor will increase with frequency, this procedure functions only with high frequency.
Some typical applications are also listed in the following (up to 200 kW, 13.56 / 27.12 MHz, stable):
- Drying of foods, textiles, paper, chemical products, foundry cores, raw tobacco... - Drying and bonding of wood - Baking of bread, biscuitS... - Sterilization of food and pharmaceutical products - Thawing of deep-freeze products - Melting of chocolate... - Foaming of synthetic materials - Hardening of prefabricated concrete parts and fiber-reinforced resins - Welding of plastic materials - Vulcanization of various rubber products - Gelatification of explosives
We do, however, also manufacture equipment for special purposes. Please contact us, if you would like to receive detailed information.
We manufacture inductive and capacitive middle and high frequency generators with an output power ranging from 1.5 kW to 600 kW. The working frequency is between 5 kHz and 27.12 MHz.
Inductive Heating
The work piece in case of inductive heating consists of an electrically conductive matter or a semiconductor (silicon). The high frequency energy is transferred to the work piece by means of an inductor. This inductor is adapted to the geometric form of the heating zone, is in most cases made of bent copper hollow section and is cooled with water.
Some typical applications out of the wide variety of inductive medium and high frequency generators for industrial applications are listed below (up to 600 kW, 5 kHz to 2.5 MHz):
- Surface hardening and full hardening of steel components
- Welding and annealing of pipes
- Brazing, soldering
- Block heating for hot shaping
- Heating and melting of ferrous metals, non-ferrous metals and other materials, such as glass
- Unstressed annealing
- Recrystallization annealing
- Epitaxy plants for semiconductor fabrication
Capacitive Heating
The work piece in case of dielectric or capacitive heating consists of electrically non-conductive material, whereby its molecules are being polarized if it is placed within the electrical field of a capacitor. If this should be an alternating field, then the dipoles thus generated will perform oscillations, so that the electrical energy introduced in the field will be converted directly to heat within the material. In theory, the heating effect will be distributed evenly with respect to time and location over the entire mass, but in practical use the heat will flow from the inside to the outside to a certain degree due to the heat dissipation on the surface. Due to the heating-up of the material with a given work piece volume, electrical field strength and material loss factor will increase with frequency, this procedure functions only with high frequency.
Some typical applications are also listed in the following (up to 200 kW, 13.56 / 27.12 MHz, stable):
- Drying of foods, textiles, paper, chemical products, foundry cores, raw tobacco... - Drying and bonding of wood - Baking of bread, biscuitS... - Sterilization of food and pharmaceutical products - Thawing of deep-freeze products - Melting of chocolate... - Foaming of synthetic materials - Hardening of prefabricated concrete parts and fiber-reinforced resins - Welding of plastic materials - Vulcanization of various rubber products - Gelatification of explosives
We do, however, also manufacture equipment for special purposes. Please contact us, if you would like to receive detailed information.
We manufacture inductive and capacitive middle and high frequency generators with an output power ranging from 1.5 kW to 600 kW. The working frequency is between 5 kHz and 27.12 MHz.
Inductive Heating
The work piece in case of inductive heating consists of an electrically conductive matter or a semiconductor (silicon). The high frequency energy is transferred to the work piece by means of an inductor. This inductor is adapted to the geometric form of the heating zone, is in most cases made of bent copper hollow section and is cooled with water.
Some typical applications out of the wide variety of inductive medium and high frequency generators for industrial applications are listed below (up to 600 kW, 5 kHz to 2.5 MHz):
- Surface hardening and full hardening of steel components
- Welding and annealing of pipes
- Brazing, soldering
- Block heating for hot shaping
- Heating and melting of ferrous metals, non-ferrous metals and other materials, such as glass
- Unstressed annealing
- Recrystallization annealing
- Epitaxy plants for semiconductor fabrication
Capacitive Heating
The work piece in case of dielectric or capacitive heating consists of electrically non-conductive material, whereby its molecules are being polarized if it is placed within the electrical field of a capacitor. If this should be an alternating field, then the dipoles thus generated will perform oscillations, so that the electrical energy introduced in the field will be converted directly to heat within the material. In theory, the heating effect will be distributed evenly with respect to time and location over the entire mass, but in practical use the heat will flow from the inside to the outside to a certain degree due to the heat dissipation on the surface. Due to the heating-up of the material with a given work piece volume, electrical field strength and material loss factor will increase with frequency, this procedure functions only with high frequency.
Some typical applications are also listed in the following (up to 200 kW, 13.56 / 27.12 MHz, stable):
- Drying of foods, textiles, paper, chemical products, foundry cores, raw tobacco... - Drying and bonding of wood - Baking of bread, biscuitS... - Sterilization of food and pharmaceutical products - Thawing of deep-freeze products - Melting of chocolate... - Foaming of synthetic materials - Hardening of prefabricated concrete parts and fiber-reinforced resins - Welding of plastic materials - Vulcanization of various rubber products - Gelatification of explosives
We do, however, also manufacture equipment for special purposes. Please contact us, if you would like to receive detailed information.
We manufacture inductive and capacitive middle and high frequency generators with an output power ranging from 1.5 kW to 600 kW. The working frequency is between 5 kHz and 27.12 MHz.
Inductive Heating
The work piece in case of inductive heating consists of an electrically conductive matter or a semiconductor (silicon). The high frequency energy is transferred to the work piece by means of an inductor. This inductor is adapted to the geometric form of the heating zone, is in most cases made of bent copper hollow section and is cooled with water.
Some typical applications out of the wide variety of inductive medium and high frequency generators for industrial applications are listed below (up to 600 kW, 5 kHz to 2.5 MHz):
- Surface hardening and full hardening of steel components
- Welding and annealing of pipes
- Brazing, soldering
- Block heating for hot shaping
- Heating and melting of ferrous metals, non-ferrous metals and other materials, such as glass
- Unstressed annealing
- Recrystallization annealing
- Epitaxy plants for semiconductor fabrication
Capacitive Heating
The work piece in case of dielectric or capacitive heating consists of electrically non-conductive material, whereby its molecules are being polarized if it is placed within the electrical field of a capacitor. If this should be an alternating field, then the dipoles thus generated will perform oscillations, so that the electrical energy introduced in the field will be converted directly to heat within the material. In theory, the heating effect will be distributed evenly with respect to time and location over the entire mass, but in practical use the heat will flow from the inside to the outside to a certain degree due to the heat dissipation on the surface. Due to the heating-up of the material with a given work piece volume, electrical field strength and material loss factor will increase with frequency, this procedure functions only with high frequency.
Some typical applications are also listed in the following (up to 200 kW, 13.56 / 27.12 MHz, stable):
- Drying of foods, textiles, paper, chemical products, foundry cores, raw tobacco... - Drying and bonding of wood - Baking of bread, biscuitS... - Sterilization of food and pharmaceutical products - Thawing of deep-freeze products - Melting of chocolate... - Foaming of synthetic materials - Hardening of prefabricated concrete parts and fiber-reinforced resins - Welding of plastic materials - Vulcanization of various rubber products - Gelatification of explosives
We do, however, also manufacture equipment for special purposes. Please contact us, if you would like to receive detailed information.