This chapter is not over yet, please click on the next page to continue reading! So many professors who wanted to find fault, including Qi Wenrui, had to admit embarrassingly that they could not understand the core part of Qin Ke’s paper, let alone judge whether it was correct or not.

There is no problem. They can only make a rough judgment based on the most basic physical theory and the logical context of the paper.

When Qin Ke explained the magnetic fluid power generation part, most of the people present secretly breathed a sigh of relief and finally understood it roughly.

But before they could relax their nerves, Qin Ke had quickly switched from magnetic fluid power generation to magnetohydrodynamics. This is a discipline that combines fluid mechanics and electrodynamics to study the interaction between conductive fluids and electromagnetic fields. The core is also a set of basic equations.

This again involves a system of nonlinear partial differential equations in mathematics. As we all know, "nonlinear" can basically be equated to "very complex", and it usually needs to be solved by approximation methods or numerical methods.

"After the fluid mechanics model is established, we can establish the above-mentioned system of equations, substitute several special values ​​into it for verification, and obtain the special solutions of Hartmann flow and Couette flow that are commonly used in the industry.

. And this can also be inferred that this fluid dynamics model is established and correct..."

"Through the fluid mechanics model, we can find that when the above-mentioned curve trajectory consistent with the equation set (16) is carved inside the power generation channel, the characteristics of magnetohydrodynamics can be fully utilized, making the cutting effect of the conductive gas when passing through the strong magnetic field more effective.

Obviously, thereby improving the power generation efficiency. I have already obtained the specific values ​​​​in the mathematical calculations just now. Next, I will explain my simulation experiments and the values ​​​​according to the simulation experiments..."

This chapter is not finished yet, click [next page] to continue reading -->>

[I really just want to be a god of learning]

【】

"We can see that the derivation of the fluid mechanics model and our simulation experiment are basically consistent. Substituting the value into the output power We of the unit volume of the conductive fluid, according to We=σv*2B*2k(1-k)

, we can calculate the results before and after optimization. As long as the conclusions in my paper are adopted, the efficiency of magnetic fluid power generation can be increased by about 27% at almost no cost!"

The whole place fell into a confused silence again. Except for Ning Qingyun, Jiang Weixian, and Academician Guo Weiyang, who had read the paper beforehand, everyone else was in a state of shock.
Chapter completed!