Monster Factory - 1035
The research and development of the bionic electric muscle was placed in the experimental workshop not far from the office.
The Longxitan factory now has a huge paved area. Cars are walking on Huanhai Avenue. Looking at the factory is like looking at a small city.
But the core of the factory has always been in that barren mountain surrounded on three sides.
Ye Qing’s office is here, the factory R&D center is here, and the underground base is also here.
Ye Qing walked into the test workshop, and the masters of ingenuity, metal experts, electronic messengers, and materials who participated in this research have been waiting for a long time.
The technical data of the bionic electric muscle has been led by Ye Qing, one for each representative of the four monsters.
The term bionic electric muscle is not too unfamiliar in mechanical dynamics. The traditional hydraulic and pneumatic, and the most common bearing power, have almost been developed to the extreme. And these motivations are often tied to the cumbersomeness.
Engineers are eager to find a breakthrough movement pattern, such as a movement pattern that can independently and linearly contract like muscle fibers.
Only this kind of power mode can perfectly simulate the characteristics of human movement.
It can be widely used in robotics and medical fields.
Primary gimmick products related to bionic electric muscles come out every year, but these products are currently not commercialized.
For example, the gimmick “nylon muscle” developed by MIT can only move nylon muscles through special molding methods and thermal deformation principles.
It feels like a memory material, and the temperature is used to control the shrinkage of the material.
But its shortcomings are also obvious. The preferred material has a very low shrinkage cycle life, only tens of thousands of times. The force produced during contraction is very low, similar to that of patients with muscle weakness.
There is also poor controllability of the contraction angle, and the inability to complete the flexible movement of human fingers and torso, etc.
A little more expensive, such as bionic electric muscle materials made of various alloys.
Its contracted lifespan has been improved, and its strength has been increased, but the power core is actually still the same.
Through motors, mechanisms such as pulleys and take-up reels are transformed into linear contraction motions similar to muscles. The volume becomes heavier and the energy consumption will increase substantially.
The cost is high, and the bionics are also nondescript. The Watcher robot series designed by Dianjing uses this kind of technology, just imitating a little bit more intelligently.
Behemoth Industry now has the most perfect bionic electric muscle technology.
This kind of bionic electric muscle is composed of artificial sports fibers with the thickness of a ballpoint pen core.
Each movement fiber can independently complete the same bionic action as a human muscle.
Sports fibers can be stacked repeatedly or made more slender. Of course, if you do that, the cost will become very expensive.
A standard-size sports fiber is first printed out of a special structure tube from a biological fiber material.
The tube body must fit a high-tech product called [Thermal Neuron], which can convert electrical energy into heat. And like human nerves, it can freely control each unit and release heat energy with different heat.
The thermal energy length of each unit can be accurate to five millimeters long, and the thermal conductivity between each other is also very low.
It is very complicated and difficult to understand, if it is a popular image.
It is necessary to make a soft electric heating wire to a section of 5 mm or even a section of 2 mm, and there will be different temperature changes, and the temperature difference will not be transmitted to each other.
The reason becomes simple.
But if you want to achieve it through technical means, I am afraid that it will be hunted down by the material engineers.
They will chase and yell at the same time, “Come on, I will give you a debut question. How to make a glass of water so that one third is 50 degrees, one third is 70 degrees, and one third is 100 degrees. .”
“I can’t figure it out, I cut you down.”
Thermal neuron technology is similar to a glass of water, with several technical difficulties at different temperatures.
What key role can this technology play in the bionic electric muscle?
It can thermally deform the pipe body of special bio-fiber materials through dense thermal units.
This is a precise and controllable thermal deformation, and the accuracy of the deformation angle far exceeds the range that can be controlled by human muscles.
Special biological materials, the contraction strength generated under thermal deformation, and the energy released by storage, are far more than the strength of human muscles of the same volume.
Biological materials and thermal neurons form an artificial movement fiber.
Artificial sports fibers are superimposed on a large number of super-light metal bones that are highly similar to human skeletons.
They constitute a complete artificial body. The contraction cycle life cannot be described by times, because it has a working life of more than five years under normal conditions.
Depending on the structure of the ultra-light metal bone, or the metal-free bone like the tongue, countless ways of movement can be derived from this.
I don’t know if it is a coincidence or the crystallization of the monster factory technology.
When the bionic electric muscle is in motion, the thermal neurons generate heat and conduct it to the special biological material tube.
Its surface temperature feels like the temperature of human skin.
It represents infinite possibilities.
…
“Thermal neuron is more difficult. Boss, you have to deploy fifty exquisite masters to produce equipment.” After reading the technical data, the exquisite master replied.
“The ultra-light metal skeleton is very simple.” The metal expert replied.
“The raw materials of the biofiber tube body are more difficult. It requires us to add more synthetics to the previous generation of biofiber materials. We need to provide technical guidance to the cooperative biological companies to obtain qualified raw materials.” The material master replied. .
“The electronic motion control system is very simple, because we don’t have to compile control programs.” The electronic messenger replied.
“Not difficult.”
Ye Qing replied, “I have also read the information carefully. Our difficulty is mainly that there is no special industrial equipment for large-scale production of thermal neurons.”
“We have technical reserves and equipment for bio-fiber materials.”
“So, concentrate on solving the equipment for large-scale manufacturing of thermal neurons. It just so happens that the factory is about to carry out the rectification and upgrade of the virtual factory 5.0, and there are many positions to be suspended.”
Ye Qing didn’t have too much worry between his eyebrows. Some techniques would feel unthinkable before breaking the window paper, and shouted that it was impossible.
But with a whole set of technical information to pierce the window paper, it becomes reasonable.
How to make thermal neurons?
Science tells us that only with resistance can electricity be converted into heat.
Only metal is the best resistance material, but the heat energy transformed by metal is uncontrollable. It needs to be hot and hot together, and cold and cold together.
So there is no need for the backward resistance heating method.
The more advanced ones, such as why is it hot in the sun?
Because it emits light, the light contains electromagnetic energy.
So if a thermal unit on a thermal neuron is equivalent to a miniature electromagnetic wave generator, can it not be allowed to release precise and controllable different temperatures?
In an i7 processor smaller than a matchbox, 1.8 billion transistors can be integrated.
It is difficult for the Giant Animal Industry to integrate two hundred or even five hundred controllable micro-electromagnetic generators in a one-meter-long thermal neuron?
It is difficult. From a machining point of view, it is more difficult than manufacturing i7 processors.
Of course ~ and only the giant beast industry has the technology to produce it.
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