Monster Factory

The research and development of biomimetic electromyocardium was placed in an experimental workshop not far from the office.

The Longxi Beach Factory is now overstretched, with cars walking on the Roundabout, viewing the factory as if it were a small city.

But the core of the factory has always been in that three-sided barren mountain.

Ye Qing's office is here, the factory R&D center is here, and the basement base is here.

Ye Qing walked into the experimental workshop, and has been waiting for many years for the masters of ingenuity, metal experts, electronic messengers and materials to participate in this study.

The technical information on biomimetic electromyocardium has been derived by Ye Qing, one for each of the four monsters.

The term bioelectric muscle is not too strange in mechanical dynamics. Traditional hydraulic pneumatics, and most prevalent bearing dynamics, have almost developed to the extreme. And these drivers are often linked to bulky.

Engineers are eager to find a breakthrough pattern of motion that can independently contract linearly, like muscle fibers.

It is also this mode of power that perfectly simulates the characteristics of human movement.

It can be used extensively in the robot field, the medical field.

Primary gimmick products associated with biomimetic electromyocardium are available every year, but none of these products currently have the potential to be commercialized.

For example, MIT developed the stunning version of "Nylon Muscle," which can only move the nylon muscle by special moulding methods and thermal deformation principles.

A little memory of the material feeling, use the temperature to control the material shrinkage.

But its drawbacks are also evident, as the preferred material has a low shrinkage cycle life of only tens of thousands of times. Systole produces very low intensity, similar to in patients with muscle weakness.

There is also poor contraction angle controllability, inability to perform flexible movement of human fingers and torso, etc.

It is more expensive, for example, to imitate bioelectric muscle materials made of various alloys.

Its contraction lifespan is improved and its power is enhanced, but the power core is still the same.

By means of motors, mechanisms such as pulleys and tape discs are converted into linear contractile movements similar to those of muscles. Volume becomes heavier and energy consumption increases dramatically.

It's expensive, and biomimicry is unequal. The Watcher Robot Series, designed by a crystal, uses this technology, just to imitate it better.

Giant Beast Industries now possesses the most perfect biomimetic electromuscle technology.

This biomimetic electric muscle consists of a thin, artificial motion fiber with a ballpoint core.

Each movement fiber is able to perform the exact same biomimetic action as the human muscle independently.

Motor fibers can be stacked repeatedly or made thinner. And of course, it's going to be very expensive.

A standard size motion fiber, first printed with a special structural tubing from a biological fiber material.

To fit a high-tech product called [thermal neurons] in the tube, thermal neurons can convert electrical energy into thermal energy. And like the human nerve, it freely controls the cells, releasing different calories.

The thermal energy length of each unit can be as precise as five millimeters long, and the heat conductivity between them is very low.

It's complicated to say, if it's a common image comparison.

The idea is to have a soft electric filament, a 5 mm section, or even a 2 mm section, with varying temperatures, and the temperature difference is not conductive to each other.

That makes it easier.

But if it were to be achieved by technical means, it would probably be hunted down by material engineers.

They'll hunt, they'll yell, "Come on, I'll give you a problem. How to make a glass of water, one third is 50 degrees, one third is 70 degrees, and one third is 100 degrees. ”

“I can't get it out, I cut you. ”

Thermal neuron technology, like a glass of water, is the technical difficulty of several different temperatures.

What is the key role that this technology can play in biomimimicry?

It allows for thermal deformation of special biological fiber material tubing through dense thermal units.

This is precisely controllable thermal deformation, with a deformation angle of precision that far exceeds what the human muscle can control.

Special biological materials, contraction strength produced under thermal deformation, and energy released from storage also far exceed the equivalent volume of human muscle strength.

Biological material and thermal neurons, which form an artificial motor fiber.

Artificial motion fibers are also heavily superimposed and attached to ultra-light metal bones that are similar in height to the human skeleton.

They form an intact artificial body. The shrinkage cycle life cannot be described in terms of number of times, as it is in a normal environment and has a working life of more than five years.

Depending on the structure of the ultra-light metal skeleton, or the absence of a metal skeleton as in the tongue, countless modes of motion can derive from this.

I don't know if it's a coincidence or a crystallization of monster factory technology.

Biomimetic electromyocardium, while in motion, is caused by heat generated by thermal neurons and conducted onto special biomaterial tubules.

Its surface temperature also feels like the skin temperature of the human body.

It represents infinite possibilities.

……

“Thermal neurons are difficult, boss. You have to deploy fifty skilled masters to produce equipment.” After reading the technical information, the master answered.

“Ultra-light metal skeleton is very simple.” The metallist replied.

“Raw materials for biofiber tubing are difficult. It requires us to add more synthetics to the previous generation of biofiber materials. We need technical guidance from cooperative biologics companies in order to obtain qualified raw materials.” The Master of Materials replied.

“Electronic motion control systems are simple because we don't have to program controls.” The electronic messenger replied.

“It's not hard. ”

Ye Qing replied, “I have also read the data carefully. Our difficulty is mainly that there is no dedicated industrial equipment for large-scale thermal neurons. ”

“Biological Fiber Material We have a technical reserve and equipment. ”

“So concentrate on the devices that make thermal neurons on a large scale. Just in time for the factory to upgrade Virtual Factory 5.0, there are a lot of jobs to suspend. ”

Ye Qingmei Yuma doesn't have much to worry about. Before some technology breaks through the window paper, it will feel amazing, shouting is impossible.

But with a whole set of technical information to pierce the window paper, it makes sense.

How do thermal neurons work?

Science tells us that there is resistance to convert electricity into thermal energy.

Only metal is the best resistive material, but the thermal energy converted from metal is uncontrollable, hot together, cold together.

So just don't use backward resistance heating.

Premium, like why is it hot to sun?

Because it glows, light contains electromagnetic energy.

So if a thermal neuron, a thermal unit, is equivalent to a micro-electromagnetic wave generator, it can release precisely different temperatures that can be controlled?

The i7 processor, smaller than the matchbox, integrates 1.8 billion transistors.

The giant animal industry has to integrate 200 or even 500 controllable microelectromagnetic generators into a metre long thermal neuron.

Hard, from a mechanical point of view, to manufacture an i7 processor.

Naturally ~ Only the giant animal industry can produce technology.