Cutting-edge technology: Starting with individual stealth equipment

Upon arriving at the company, Lin Chuan was in his office.

Instead of immediately getting to work, he opened the Hyperdimensional Technology Library.

DeepBlue Technology received RMB 10 billion in payment from Henghui Group, which means that in 2011, it not only achieved profitability, but its net profit exceeded RMB 7 million, which is a certainty.

Previously, the latest task of Super Dimension Library was for DeepBlue Technology to achieve a net profit of 1 million yuan within the year, and the task has been exceeded.

Lin Chuan has gained another technology point, which can be used to unlock a new technology.

I didn't use it a while ago, but I'm planning to use it now.

[Would you like to spend 1 tech point to randomly unlock a technology?]

Seeing the familiar interface, Lin Chuan perked up and said to himself, "Super Battery Technology, bring it on!"

He still longed for this technology: once it was unlocked, an electromagnetic rifle could be custom-designed for individual stealth combat suits, and the suit's endurance would receive an epic boost.

It could even spark an epic revolution in new energy technologies.

The applications of high-energy-density and high-power-density batteries are extremely broad.

Whether for military or civilian use, it can shine brightly.

In the military field, needless to say, the development of high-energy laser weapons and electromagnetic railguns can be greatly accelerated.

In the civilian sector, the new energy vehicle sector alone can support a market size of trillions of yuan.

Lin Chuan decisively chose to unlock it.

After a short wait, a new information window popped up.

A moment later, Lin Chuan took a closer look: "Wow, it actually pairs quite well with plasminoides. If only I could unlock the advanced second-generation plasminoides technology..."

[Unlocked successfully]

[Unlocking Technology: Clean Energy Generation Technology Through Waste Incineration]

[Category: Energy Technology & Solid Waste Treatment / Advanced Manufacturing & Environmental Protection Equipment]

[Complete information has been saved and can be accessed at any time.]

Lin Chuan saw the unlocked new technology, which seemed to fit well with the "plastic-eating bacteria".

Combining these two approaches could completely solve the problem of the mountains of garbage generated by humanity. Currently, China alone produces approximately 2.5 million tons of garbage every year, a scale large enough to fill 35 and a half West Lakes.

"Plastic-eating bacteria" can only solve the problem of plastic waste, which accounts for only about 15% of the total amount of waste.

Currently, with the rapid economic development in China and the continuous improvement of people's living standards, the amount of garbage generated is also increasing, and the situation of garbage surrounding cities has begun to emerge in China.

There are more than 400 landfills around the Beijing metropolitan area, and the dark, towering mountains of garbage are an eyesore.

In Shenzhen, where land is incredibly valuable, the Yulong landfill is home to a 110-meter-high garbage mountain, equivalent to a 36-story building.

It was put into use in 1983, closed in 1997, and shut down in 2005, with a total of about 255 million cubic meters of garbage, weighing 410 million tons.

Waste disposal is a major headache for cities. Landfilling leaves long-term pollution, and incineration is even worse.

Because the current incineration temperature is low, combustion is incomplete, and it also produces dioxins, which are 900 times more toxic than arsenic.

Even introducing waste incineration equipment from Mitsubishi in Japan couldn't solve the problem.

Domestic waste has a water content of over 50%, and most of it is kitchen waste with low calorific value.

The small notebook contains dry, finely sorted trash with high calorific value.

This has resulted in the imported incinerator equipment being unable to function properly in China; either it fails to ignite or combustion is incomplete, which further exacerbates pollution.

At this moment, Lin Chuan was browsing the newly unlocked technological information.

The core is the manufacturing of an advanced incinerator, which mainly consists of three technologies.

Firstly, the washboard grate.

The grate bars are arranged in a stepped, staggered pattern, mimicking the wavy structure of a washboard.

As the waste moves on the grate, it is constantly turned over, broken, and loosened, forcibly increasing its contact area with the air.

"This is quite suitable for the domestic situation," Lin Chuan said to himself as he perused the technical documents.

According to technical information, it effectively addresses the pain points of high moisture content, high kitchen waste content, and low calorific value of domestic waste, extending the residence time of wet waste on the grate to 45-60 minutes, which is twice as long as traditional grates, ensuring that moisture evaporates fully and combustible components are completely released.

Then, Lin Chuan looked at the second technical component.

Circulating fluidized bed incineration technology.

High-speed air is injected into the bottom of the furnace, causing inert media such as quartz sand to become fluidized, forming a violently turbulent "sand bath". Waste particles collide, rub, and break at high speed in the fluidized bed, resulting in a sharp increase in specific surface area and a 3-5 times increase in combustion rate.

Meanwhile, the huge heat capacity of the fluidized bed keeps the furnace temperature stable between 950 and 1050 degrees Celsius, and it is not easy to extinguish the fire even if the calorific value of the waste fluctuates.

The third core technology is the nuclear-level precision control system.

Drawing on the redundant control logic and real-time monitoring architecture of nuclear reactors, 32 thermocouples and 6 infrared temperature probes are arranged inside the furnace, and the data is refreshed every 0.1 seconds.

By using a PID cascade control algorithm, the grate speed, air volume ratio, and auxiliary fuel injection amount are automatically adjusted to keep the furnace temperature fluctuation within ±15℃, while traditional incinerators fluctuate within ±80℃.

The control software uses a "two out of three" voting logic, so a single sensor failure will not affect the system operation.

This technology and equipment has a strong ability to suppress toxic gases such as dioxins.

The first step is to control it at the source by using the intense turbulence of a fluidized bed and temperatures exceeding 900 degrees Celsius to completely burn the waste and destroy dioxin precursors.

Then there is the rapid cooling technology, where the flue gas is cooled to below 200°C within 1 second after leaving the furnace, bypassing the 300 to 450°C temperature window where dioxins are easily generated.

Finally, activated carbon powder is sprayed into the bag filter to adsorb residual dioxins and heavy metals.

The overall dioxin emission concentration is far superior to the EU standard, and only 1/35 of the national standard.

In addition, the additional waste heat power generation module generates superheated steam at 4.0 MPa and 400°C through a waste heat boiler, which drives the steam turbine generator set.

The power generation efficiency can reach 28%-32%, while that of traditional incinerators is only 15%-20%.

This technological solution can generate 350-400 kWh of electricity per ton of waste, and after deducting the electricity used for self-consumption, the net electricity generated to the grid is about 280-320 kWh.

Finally, Lin Chuan reviewed the entire set of technical documents and said to himself, "If this thing is developed, the plastic-eating bacteria seem to be useless. Whether it's plastic waste or kitchen waste, you can just dump it all into the furnace and burn it. If Huiheng finds out, won't the sky fall?"

However, upon further reflection, the role of plasminoides is still irreplaceable.

Lin Chuan saw an advanced version of "plastic-eating bacteria" technology in the Hyperdimensional Library that had not yet been unlocked. The metabolic products of this advanced version of plastic-eating bacteria are not carbon dioxide and water.

It's oil.

Plastic products are themselves hydrocarbon polymers derived from petroleum processing, and their elemental composition is highly consistent with that of petroleum.

Microbial degradation of plastics is essentially the process of breaking down long chains of polymeric plastics.

As long as the degradation pathway remains at the small molecule stage of hydrocarbons and does not completely decompose into carbon dioxide and water, petroleum-based raw materials can be obtained directly, which conforms to the basic law of conservation of matter.

……