Automatic LED Strip Soldering Machine

Automatic LED strip Soldering Machine

1.Models for Automatic LED strip Soldering Machine

A. Single head, single station,(R axis)

B. Single head, double stations,(R axis)

C. Double heads, single station,(R axis)

D.Double heads, double stations,(R axis).

E. Other customized designs are available. Welcome to contact us.

 

2.Features for Automatic LED strip Soldering Machine

Greatly reduce human effort and labor cost.

Easy to operate. No special skills are needed.

Long-life span.

3.Application of Automatic LED strip Soldering Machine

Communication industry: Apple product data line, HDMI, RJ45, FPC, high frequency first class products are suitable for automatic soldering machine.

Optoelectronics industry: led display, led strip, led rectifier, led ball lamp, led lamp beads and other products are applicable to automatic soldering machine.

Appliance industry: air conditioning remote control, air conditioning control panel, computer speakers, TV switch connectors and other products are suitable for automatic soldering machine.

Automotive industry: ignition switches, automotive fuel sensors, navigators, motorcycle flash and other products are suitable for automatic soldering machine.

Toy Industry: Toy handle connectors, circuit boards and other products are suitable for automatic soldering machine.

 

5.Certificate 5

 

7.Shipment5

DHL/TNT/FEDEX. If you want other shipping term, please tell us. We will support you.

 

8. Terms of Payment 

Bank transfer, Western Union, Credit Card.

Please tell us if you need other support. 

 

 

9. Related Knowledge:

Welding History

Before the end of the 19th century, the only welding process was metal forging, which had been used by blacksmiths for hundreds of years. The earliest modern welding techniques appeared at the end of the 19th century, starting with arc welding and oxygen gas welding, and later, resistance welding.

In the early 20th century, the demand for military equipment during World War I and World War II was very high, and the need for a cheap and reliable metal joining process became critical, which promoted the development of welding technology. After the wars, several modern welding techniques emerged, including the widely used manual arc welding, gas metal arc welding, submerged arc welding, flux-cored wire arc welding, and electroslag welding. These methods allowed for automatic or semi-automatic welding.

In the second half of the 20th century, welding technology advanced rapidly, with the development of laser welding and electron beam welding. Today, welding robots are widely used in industrial production, and researchers continue to explore the nature of welding, developing new methods and improving welding quality.

The history of metal connections dates back thousands of years. Early welding techniques were found in Europe and the Middle East during the Bronze and Iron Ages. The civilizations of the two river regions, such as Babylon, had begun using soldering technology thousands of years ago. In 340 BC, welding technology was used in the construction of the ancient Delhi Iron Pillar in India, which weighed 5.4 tons.

Medieval blacksmiths joined metals by constantly forging red-hot pieces, a process known as forging. In 1540, Wiener Heavy Bilinko's "Flameology" described forging techniques. During the European Renaissance, artisans mastered forge welding, and the technique was continually refined over the next few centuries. By the 19th century, welding technology had made significant advances. In 1800, Sir Humphry Davy discovered the electric arc. Later, the arc welding process was popularized with the invention of the metal electrode by Russian scientist Nikolai Slavnyov and American scientist C. Coffin. Arc welding and later, carbon arc welding using carbon electrodes, became widely used in industrial production. Around 1900, A.P. Stroganov developed a metal-clad carbon electrode in the UK that provided a more stable arc. In 1919, CJ Holslag first used alternating current (AC) power for welding, although this technology did not become widely used until ten years later.

Resistance welding was developed during the last decade of the 19th century. The first patent for resistance welding was filed by Ireuch Thomson in 1885, and he continued to improve the technology for the next 15 years. Aluminum heat welding and flammable gas welding were invented in 1893. Edmund David discovered acetylene in 1836. By around 1900, flammable gas welding became widely used due to the development of a new type of gas torch. Due to its low cost and good mobility, gas welding became one of the most popular welding techniques in the early 20th century. However, as engineers improved metal coating technology on the electrode surface (i.e., the development of flux), new electrodes were able to provide a more stable arc and effectively isolate base metals from impurities. As a result, arc welding gradually replaced flammable gas welding and became the most widely used industrial welding technology.

World War I increased the demand for welding, and countries were actively developing new welding techniques. The UK primarily used arc welding, and they built the first ship with a fully welded hull, the Flago. During the war, arc welding was also applied to aircraft manufacturing for the first time. Many German aircraft, for example, were constructed using this method. It is also worth noting that the world's first fully welded road bridge was built in 1929 over the Słudwia Maurzyce River near Wolff, Poland, designed by Stefan Bryła of the Warsaw Institute of Technology in 1927.

In the 1920s, welding technology made major breakthroughs. Automatic welding emerged in 1920, with an automatic wire feeder ensuring a continuous arc. Protective gas also gained significant attention during this period. Because metal reacts with oxygen and nitrogen in the atmosphere at high temperatures, the resulting voids and compounds can weaken the weld joint. The solution was to use gases like hydrogen, argon, and helium to isolate the weld pool from the atmosphere. In the next decade, further developments allowed for welding active metals such as aluminum and magnesium. From the 1930s to World War II, the introduction of automatic welding, alternating current, and active agents greatly contributed to the development of arc welding.

In the mid-20th century, scientists and engineers invented a variety of new welding techniques. Stud welding, invented in 1930, was quickly adopted by the shipbuilding and construction industries. Submerged arc welding, invented the same year, is still widely used today. After decades of development, tungsten gas shielded arc welding was completed in 1941. In 1948, gas-shielded arc welding allowed for rapid welding of non-ferrous metals, though it required large amounts of expensive shielding gas. Manual arc welding using consumable electrodes was developed in the 1950s and quickly became the most popular arc welding technique. In 1957, flux-cored arc welding was introduced, allowing for self-shielded wire electrodes that greatly improved welding speed. In the same year, plasma arc welding was invented, and electroslag welding followed in 1958.

Recent developments in welding technology include electron beam welding, introduced in 1958, which allows for deep, narrow welding of small areas. Laser welding, invented in 1960, later became the most efficient high-speed automatic welding technology. However, both electron beam welding and laser welding have limited applications due to their high cost.