Of course, it is not perfect either, the five-axis machining center has a shortcoming.

The disadvantage is that the side of the workbench that clamps the part cannot be processed. If you want to continue processing, you can only take the part off first, turn it over and re-clamp it.

But there is a disadvantage in this way. Because the position of your parts has changed, the relevant parameters will also change, which will eventually lead to a decrease in processing accuracy.

In addition, many parts are heavy, and it takes a lot of effort to reinstall them, which ultimately reduces the production efficiency of a machine.

To solve this problem, the best way is to develop a mechanical system that automatically turns the parts over.

This is called "seven-axis linkage machining center" or "nine-axis linkage machining center" in the field of CNC machining centers.

Its disadvantage is that its price and complexity will be much greater than that of a five-axis machining center. After all, as the complexity of the machine increases, the price will naturally soar.

What Lin Feng wanted to develop at this time was undoubtedly the five-axis linkage machining center, because the nine-axis linkage machining center was derived based on the five-axis linkage machining center.

Therefore, you must first have a basic embryo, and then it is possible to evolve into a seven-axis linkage machining center or a nine-axis linkage machining center.

If you start with a nine-axis machining center, the research and development difficulty will be too high and it will not be easy to get results quickly.

So Lin Feng decided to first build a five-axis linkage machining center, and then upgrade the nine-axis linkage machining center by upgrading the panel.

Developing a five-axis machining center is both easy and difficult.

It is easy to say because Daxia attaches great importance to the research and development of high-end machine tools, especially five-axis linkage machining centers.

So now, decades later, the Daxia version of the five-axis linkage machining center has already been developed and produced.

After all, this thing was completely finalized and put into practical use in the 20s, and Daxia also launched a project to develop a domestic five-axis linkage machining center at that time.

It took more than 2005 years, and in , the five-axis linkage blade machining center developed by Beijing Institute of Mechanical and Electrical Engineering won the first prize for scientific and technological progress.

After that, because of the first one, the second, third and improved models naturally emerged like mushrooms after rain.

By 2013, Daxia's five-axis linkage centers could be sold overseas, making it one of the major exporters of five-axis linkage machining centers.

But this is only the surface glory. In fact, the five-axis linkage machining center produced by Daxia is only in the low-end field due to the problem of machining accuracy.

In addition, these five-axis machining centers are more or less subject to human control in core aspects.

They are either tool problems, detection instrument or sensor problems, or CNC system problems.

Under such circumstances, although Daxia's five-axis linkage machining center came out, it was more or less controlled by others.

And to be honest, many of the most advanced things cannot be purchased by the machine tool factories in Daxia.

The final result is that a good cook cannot cook without rice. Although Daxia’s five-axis linkage machining center has been launched, it can only be in the mid-to-low-end field due to the problem of parts processing accuracy.

So although Daxia can now produce five-axis linkage machining centers and even export them to earn foreign exchange, they are mainly in the mid- and low-end fields.

Among them, if Lin Feng wants to develop his own five-axis linkage machining center.

In fact, we can learn from the experience of other Daxia five-axis linkage machining centers, and then combine our own advantages to achieve miracles. What are our own advantages?
The advantage of Xingtu Technology is that it has artificial intelligence Jarvis!

In fact, the field where artificial intelligence Jarvis is most suitable is not management of the company, but production, especially metal processing.

Because artificial intelligence Jarvis can use huge computing power to simulate the entire production process in advance and calculate the fastest and most efficient metal processing production steps.

Countless production simulations are then performed to compensate for mechanical precision, and the accuracy of the parts produced ultimately exceeds the highest accuracy that programmers can achieve.

After all, due to brain limitations, humans have no way of simulating the complete parts production and processing process in their brains.

Although humans can use their own experience to find ways to produce high-precision parts, they still seem a bit powerless compared to Jarvis' complete simulation.

Another greater advantage is that humans want to use a five-axis machining center to process a very complex part.

They need to use software programming on the computer to control and arrange each processing and production step of the five-axis linkage machining center according to the requirements of the drawings.

This programming process usually takes several days to a week.

The artificial intelligence Jarvis relies on powerful computing power.

Tasks that would take a human several days or even a week to complete can be completed in just seconds or minutes for Jarvis.

This is the huge advantage of applying artificial intelligence Jarvis in the field of metal processing.

Of course, whether it is to quickly generate machining steps according to part drawing requirements.

Or simulating the parts processing and production process countless times in advance to improve accuracy. These are not the most powerful aspects of artificial intelligence Jarvis.

The most powerful thing about artificial intelligence Jarvis is its unparalleled learning ability!
Because the artificial intelligence Jarvis has unparalleled learning ability, he will constantly try to adjust the part processing model every time he produces parts.

Eventually, through continuous production, debugging and processing of the model, as the number of times the part is produced increases and more data is obtained, the precision of the parts that Jarvis can produce will become higher and higher.

Eventually, the highest achievable limit of machining accuracy is reached, and the parts produced from then on are all parts with the highest limit of accuracy. This is the so-called "integration of man and machine".

Therefore, the application of artificial intelligence Jarvis in the field of metal processing is really amazing, and other manufacturers cannot compare with it at all.

Of course, although the application of artificial intelligence Jarvis in the field of metal processing is very amazing, you also need to have a good foundation in the five-axis linkage machining center.

This artificial intelligence Jarvis is equivalent to a scoring machine. A five-axis linkage machining center that could originally achieve a score of 60 may eventually reach 80 or even 90 points thanks to the "human-machine integration" of artificial intelligence Jarvis.

But if there is a five-axis machining center that can achieve 100 points.

Then, relying on the 'human-machine integration' effect of artificial intelligence Jarvis, it will definitely be able to achieve an incredible score of 120 points or even higher.

Therefore, the key to everything still depends on Lin Feng to quickly develop a five-axis linkage machining center that can reach 100 points, and finally create an incredible miracle in the eyes of the world.

As for how to quickly develop a five-axis machining center that can score 100 points, Lin Feng only thought about it for a moment and came up with a solution. (End of this chapter)