High frequency Induction Soldering Brass Tubes

Objective To simultaneously high frequency Induction Soldering Brass Tubessolder to a brass water jacket assembly with induction heating. Equipment DW-HF-15KW Induction Heating Machine Key Parameters Power: 5 kW Temperature: 424°F (217°C) Time: 10 seconds until the alloy flows; 15 seconds to allow alloy to even out around the tube. TEST 1 Materials • Brass water … Read more

Induction Soldering Coaxial Cable

Objective Induction Soldering coaxial cable to connector ring and pin in two steps in under 5 seconds by reaching a temperature of 500°F (260°C) with induction heating. Equipment DW-UHF-6KW-III handheld induction heater Channel coil Materials • No-flux solder wire • Coaxial cable • Cable connector • Center pin Key Parameters Power: 3.0kW Temperature: 662°F (350°C) … Read more

Induction Soldering PCB Board with Copper Pipe

Objective: Induction Soldering PCB Board with Copper Industry: Medical & Dental Materials: Flat copper pipes, PCB board Alloy: Low-temperature solder paste Equipment: DW-UHF-6KW-III handheld induction brazing machine Power: 3.88 kW Time: 8 secs. Coil: Coated custom-made coil. The Process: HLQ was contacted by a leading manufacturer of clinical diagnostic equipment who is striving to drive innovation in the Magnetic … Read more

induction brazing and soldering technology

HLQ Induction heating systems are value added systems that can fit directly into the manufacturing cell, reducing scrap, waste, and without the need for torches. The systems can be configured for manual control, semi-automated, and all the way up to fully automated systems. HLQ induction brazing and soldering systems repeatedly provide clean, leak-free joints for … Read more

Induction Brazing Copper To Copper Parts

Objective Induction Brazing Copper to Copper parts Spacer. The workpieces were heated to 2012˚F (1100˚C) in 1 minutes. Recommended Equipment The recommended equipment for this application is the  DW-HF-45kw induction heating machine Materials: Copper section: 0.55” thick x 1.97” long x 1.18” wide x 0.2” long (14 mm thick & 50 mm long x 30 … Read more

Induction Soldering Cable to Metallic Plate

Objective The purpose of this test is to demonstrate the induction soldering cable to metallic plate process. Recommended Equipment The recommended equipment for this test is the DW-UHF-6kw-I handheld induction heater. Key Parameters Power: Up to 0.72 kW Temperature: 482°F (250°C) Time: 4.5 seconds to 14 seconds Results and Conclusions: The results were satisfactory at … Read more

high frequency induction soldering wire to connector

Objective The purpose of this test is to demonstrate the induction soldering wire to connector Recommended Equipment The recommended equipment for this test is the with the customized induction heating coil.  DW-UHF-6KW-I handheld induction heater Key Parameters Power: Up to 0.48 kW Temperature: 392°F (200°C) Time: 1.5 seconds Process and Results: This induction soldering wire … Read more

Induction Soldering Brass Corner Joint

Hig Frequency Induction Soldering Brass Corner Joint Objective Successfully solder two 45° brass corner joints. Equipment: DW-UHF-10kw induction soldering heater Materials StayBrite #8 silver solder supplied by customer Bridgit solder flux supplied by customer Brass corner joint Pancake coil Key Parameters Power: 5.5 kW Temperature: Approximately 550° F (288° C) Time: 20 sec Process: Flux … Read more

induction soldering copper tubing to brass valves

High frequency induction soldering copper tubing to brass valves Objective: Test: Induction Soldering copper tubing to brass valves Industry: HVAC Materials: Copper and brass pipes Equipment: DW-HF-25kw induction heating machine Power: 16 kW Temperature: 932oF (500oC) Time: 20 seconds Coil: Coated custom-made coil. The Process: This application request was brought to HLQ Induction Heating Power’s attention by a HVAC company. Their … Read more

Induction Brazing Principle-Theory

Induction Brazing Technology

Induction Brazing Principle|Theory
Brazing and soldering are processes of joining similar or dissimilar materials using a compatible a filler material. Filler metals include lead, tin, copper, silver, nickel and their alloys. Only the alloy melts and solidifies during these processes to join the work piece base materials. The filler metal is pulled into the joint by capillary action. Soldering processes are conducted below 840°F (450°C) while brazing applications are conducted at temperatures above 840°F (450°C) up to 2100°F (1150°C).induction brazing principle-theory

The success of these processes depends upon the assembly’s design, clearance between the surfaces to be joined, cleanliness, process control and the correct selection of equipment needed to perform a repeatable process.

Cleanliness is ordinarily obtained by introducing a flux which covers and dissolves dirt or oxides displacing them from the braze joint.

Many operations are now conducted in a controlled atmosphere with a blanket of inert gas or combination of inert / active gasses to shield the operation and eliminate the need for a flux. These methods have been proven on a wide variety of material and part configurations replacing or complimenting atmosphere furnace technology with a just in time – single piece flow process.

Brazing Filler Materials
Brazing filler metals can come in a variety of forms, shapes, sizes and alloys depending on their intended use. Ribbon, preformed rings, paste, wire and preformed washers are just a few of the shapes and forms alloys that can be found.soldering-brazing-filler materials

The decision to use a particular alloy and/or shape is largely dependent on the parent materials to be joined, placement during processing and the service environment for which the final product is intended.

Clearance Affects Strength
Clearance between the faying surfaces to be joined determines the amount of braze alloy, capillary action / penetration of the alloy and subsequently the strength of the finished joint. The best fit up condition for conventional silver brazing applications are 0.002 inches (0.050 mm) to 0.005 inches (0.127 mm) total clearance. Aluminum is typically 0.004 inches (0.102 mm) to 0.006 inches (0.153 mm). Larger clearances up to 0.015 inches (0.380 mm) usually lack sufficient capillary action for a successful braze.

Brazing with copper (above 1650°F / 900°C) requires the joint tolerance kept to an absolute minimum and in some cases press fit at ambient temperatures to assure minimum joint tolerances while at the brazing temperature.

Induction Heating Theory
Induction systems provide a convenient and precise way to quickly and efficiently heat a selected area of an assembly. Consideration must be given to the selection of power supply operating frequency, power density (kilowatt applied per square inch), heating time, and induction coil design to provide the required depth of heating in a specific braze joint.

Induction heating is non-contact heating by means of transformer theory. The power supply is an AC source to the induction coil that becomes the primary windings of the transformer while the part to be heated is the transformer’s secondary. The work piece heats by the base materials’ inherent electrical resistivity to the induced current flowing in the assembly.basic principle of induction heating

Current passing through an electrical conductor (the workpiece) results in heating as current meets resistance to its flow. These losses are low in current flowing through aluminum, copper and their alloys. These non-ferrous materials require additional power to heat than their carbon steel counterpart.

The alternating current tends to flow on the surface. The relationship between the frequency of the alternating current and the depth it penetrates the part is known as the reference depth of heating. Part diameter, material type and wall thickness can have an effect on heating efficiency based on the reference depth.