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Induktives Löten

Die Induktionserwärmung eignet sich perfekt für Lötanwendungen. Die Wärme wird auf kontrollierte Weise an genauen Bereichen der Teile erzeugt. Dank der schnellen Temperatur-Ansteigzeit, des hohen Wiederholbarkeits-Niveaus und der kontaktlosen und sauberen Erwärmung ist die Induktionserwärmung ideal für Anwendungen auf Produktionslinie (wie das Anbringen von Lichtwellenleiter-Ferrulen). Typische Induktionsanlagen für das induktive Weichlöten haben Leistungen von 1 bis 40 kW.


Anwendungen: Löten

Ambrell zeigt zahlreiche Anwendungsbeispiele. Klicken Sie auf die Anwendung, an der Sie interessiert sind. Melden Sie an, sich um über die ausgewählte Anwendung nachzulesen:

Heating a Kovar Ferrule for Glass Soldering

The solder formed a relatively uniform domed seal around the fiber despite the asymmetry of the open C coil. It took under 10 seconds to heat the part to soldering temperature

Soldering a Fusible Copper Strip

It takes under 10 seconds to heat four copper strips concurrently, resulting in a boost in throughput for the client. Induction is a highly repeatable process that heats just the area of the copper strip that requires it.

Soldering a pair of magnetic steel pins

Heating with induction required under 10 seconds and is a highly repeatable process; the customer can expect the same result every time with only the portion of the part requiring heating being heated. There is no open flame with induction, which makes it a safer method of heating than torch heating.

Soldering a rivet onto a steel tank cap with induction heating

Induction proved faster than the client’s previous heating torch process. It is also is a repeatable heating process, so the client gets superior results and is more energy efficient than torch heating. Induction doesn’t have an open flame and introduces less heat into the work environment than a torch

Soldering copper tabs for stringing, tabbing solar panels

Induction’s precision heating ensures repeatable results and less damage to surrounding substrates while demonstrating reduced heat loss and lower energy usage...

Soldering a copper grounding lug and wire

For this grounding lug soldering application, induction delivers consistent result is achieved each time and does not present a flame, so it helps create a safer, cooler working environment than other methods

Soldering brass and steel radiator caps

The heating process is completed within 15 seconds with consistent results without the use of flame, creating a safer, cooler working environment...

Soldering a copper tube to a brass valve [flow valve]

The heating process was completed within 12 seconds, faster than the client’s gas torch and more reliably. Without flame, induction helps create a safer, cooler working environment.

Soldering a copper wire, contactor assembly [motor]

High intensity heat must be applied to the joint area for this application so that thermal conduction of the copper does not sink away the heat delivered from the induction process.

Soldering a Ferrule to a Fiber Optic Cable (Hermetic Sealing)

To heat a Kovar ferrule and fiber optic cable to 297°F within 10 seconds for a soldering application, to form a hermetic seal

Soldering a fine copper wire to a connector assembly

induction heating delivered a higher quality joint, is more energy efficient than the outdated system that the client was using.

Soldering a steel canister for sealing

Current hand-soldering process results in uneven, non-uniform joints and requires long production times. Induction delivers uniform, quality joints by generating heat within the end-plate and reservoir walls.

Soldering Fiber Optic Cable to Fiber Ferrule with Glass Preform

Induction heating provides rapid localized heat only where needed, repeatable, consistent results with clean, controllable joints

Soldering a steel funnel to flex spout

Induction heating delivers non-contact energy-efficient heat without flame, resulting in repeatable and consistent results

Hermetically sealing a fiber optic cable in a kovar ferrule

Induction heating provides instant start up time, requiring very little power resources, pin point accuracy, a clean source of heat which is easily integrated into existing automated systems

Soldering windows to time indicator housings

Soldering soda lime glass metal edged windows to steel time indicator housings

Soldering a copper chip to a silver dipped brass RF attenuator

Induction heating provides repeatable consistent results in all three areas soldered at the same time, not individually. Faster process time, increased production and even distribution of heating

Soldering wires onto three connector tabs on a three position wall socket plug

Customer is currently using a soldering iron & individually touching each soldering point which is producing inconsistent results and quality issues.

Soldering 3 copper spacers to circuit board simultaneously

Induction heating delivers precise, controlled application of heat in a repeatable, non-contact, clean heating process, enabling increased production capacity and improved energy efficiency.

Soldering Electrical Flex Circuits

To heat multiple joints on flex circuit strips to 180-200°F within seven seconds for a soldering application.

Soldering a Radio Antenna

To heat a coaxial antenna assembly to 600°F within 2 seconds for a soldering application. The goal to improve on an existing procedure with a soldering iron which required 10 to 15 seconds.

Soldering Solar Flex Circuits

Heat multiple joints on solar flex circuit strips to 500°F (260ºC) within ten seconds for a soldering application.

Soldering three fuse caps simultaneously

Soldering three fuse caps simultaneously to reflow lead free solder and make a joint between the fuse cap and fuse wire guide.

Soldering three brass connectors in a solar panel junction box assembly

Solder three brass connectors one at a time in a solar panel junction box without affecting the components in the junction box

Soldering a steel cover onto a nickel plated EMI filter

Soldering a nickel plated steel cover onto a nickel plated steel EMI filter housing without damaging the RF circuit

Soldering 2 copper wires to copper buss bar

Induction heating delivers reduced solder time, even distribution of heating and improved joint-to-joint consistency

Soldering an LED assembly to an aluminum spotlight housing

A multi turn pancake coil is used to heat the bottom of the aluminum spotlight housing. The LED housing was not available so this application is done with temperature sensing paint to determine the feasibility

Soldering connector to wire harness

Induction heating provides reduced production cost, faster process time, hands-free heating that involves no operator skill for manufacturing

Soldering two connectors simultaneously to gound plate

Induction heating provides non-contact heat, hands-free heating that involves no operator skill for manufacturing with even distribution of heating

Soldering fabric to kovar tip assembly

A three turn pancake coil is used to heat the tip of the cone to 300 ºF (149 ºC) in 2-3 seconds

Soldering a kovar piece with glass to a copper base for a photon light source

Induction heating provides ability to use same equipment for both assembly and repair, hands-free heating that involves no operator skill for manufacturing, and uniform control of heat from part to part

Soldering brass and copper (anesthetic medical equipment)

This process is completed in two steps that use a 3 turn helical coil. The first process is to solder the brass ring to the copper piece which takes 85 seconds.

Soldering circuit board posts with lead or lead free solder preforms

Induction heating provides hands-free heating that involves no operator skill for manufacturing, lends itself well to automation, solder controlled by preforms, no excess left on board, good solder flow without over heating the board

Soldering Brass end cap on heat exchanger

A dual four turn pancake coil is used to solder 2 brass caps per cycle. Liquid solder is squirted onto the end cap and is heated for 18 seconds at 302ºF (150ºC) to burn off the flux

Reflowing the solder of an area on a circuit board

An aluminum fixture is a large heat sink to the induction field. In order for solder alloy to wick and run the length of the overlap area, flux is applied to the solder location.

Soldering of satellite antennas

Induction heating delivers increased production rate due to speed of heating, higher quality vs. a soldering iron due to precision and repeatability and cost savings due to reduced scrap and higher quality production

Soldering wires onto connector assemblies

Soldering wires onto connector assemblies >

Compared to using a manual soldering iron, induction heating precisely applies heat to for higher quality solder joints This is ideal for integrating with an automated system. By stick- feeding the solder more aesthetically pleasing parts are produced.

Soldering a copper tab on a speaker ring

With an efficient coil design induction heating easily reaches the desired reflow temperature in a very short amount of time.

Soldering Co-axial Wire Assemblies

A multi-turn helical coil is used and temperature-indicating paint is applied to the joint area. The wire assembly is placed over the induction heating coil, and RF power is applied.

Soldering a Stainless Steel Tube to Cylinder

Heat a.125” (3.175mm) diameter stainless steel tube to a 1” diameter cylinder 1” (25.4mm) tall for a soldering application

Soldering Cellular Phone Antenna

Soldering two brass tubes measuring 3/4" and 1/4" together for use as cellular phone antennas. The lengths of tubes range from four (4) feet to twelve (12) feet, and must be soldered along the axial side.

Soldering Ice Machine Evaporator assemblies

To heat a section of 3/8" copper tubing along with a 90 degree elbow for soldering. The copper tubing is to be used in Ice Machine Evaporator Assemblies, and soldering takes place after the tubes have been placed within the assembly.

Soldering Brass Bellows Assembly

To heat a brass bellows and end cap assembly to 450F for soldering within 20 seconds. Presently, a soldering iron is used to produce the joint between the bellows and cap.

Soldering Brass Slip Ring

To heat 1 3/4", 3" and 6" diameter brass slip rings and a sheathed copper wire assembly to 360F for soldering within three (3) to six (6) seconds. Currently production is accomplished by using a soldering iron and stick feeding rosin-cored solder.



Induktionserwärmung ist eine schnelle, effiziente, genaue, wiederholbare und kontaktlose Methode, um Metalle oder andere Stromleiter-Materialien zu erwärmen. Das Material kann ein Metall wie Stahl, Kupfer, Aluminium oder Messing sein oder auch ein Halbleiter wie Karbon, Graphit oder Silikon-Karbid. Um nichtleitende Materialien wie Kunststoffe oder Glas zu erwärmen, wird die Induktion verwendet, um einen Stromleiter-Suszeptor wie Graphit zu erwärmen, der dann seinerseits die Wärme auf das nichtleitende Material überträgt.

Lesen Sie unsere vierseitige Broschüre “Über Induktionserwärmung”.


Broschüre Downloaden



Induktive Erwärmung: Induktoren


Eine Induktionsspule ist eine Komponente der Induktionserwärmungsanlage, die definiert, wie effektiv und effizient Ihr Werkstück erwärmt wird.

Bitte lesen Sie unsere Informationsbroschüre, in der die Grundlagen der Induktoren und ihr Design erklärt werden.


Broschüre Downloaden


Zuerst wird Schmelzmittel auf den zu Lötenden Flächen aufgetragen und anschließend wird der zu lötende Bereich erwärmt. Die erforderliche Temperatur liegt gerade über dem Schmelzpunkt des Lots. Das Lot fließt dann in die Lötstelle. Nach dem Fließen, das Lot abkühlen und sich verfestigen lassen.

Metall: Eisen, Nickel, Kupfer, Blei, Zinn, Aluminium
Lot: Allgemein Blei- und Zinn-Legierungen
Schmelzmittel: ist erforderlich, um die zusammenzulötenden Oberflächen von Oxiden zu befreien, das Benetzen zu fördern und einen engen Kontakt zwischen dem Lot und dem Metall der Werkstücke zu erhalten. Wenden Sie sich an unsere Experten um das für Ihren Prozess geeignete Schmelzmittel zu bestimmen.
Wärmequelle: Eine schnelle und genaue Erwärmung gibt die besten Ergebnisse.

Die Sauberkeit der zusammenzulötenden Oberflächen ist kritisch

Beide zusammenzulötende Metalle müssen gleichzeitig auf Temperatur kommen

Wenn die Temperatur zu hoch ist kann keine starke Lötung entstehen.

her als Lotstäbe verwenden Sie Lötpaste oder Vorformen, die vor der Erwärmung in die zu lötenden Bereiche gelegt werden