Te huru o te mau mǎhu taero

I roto i te mau huru tupuraa atâta, e mea faufaa roa ia taa i te huru o te mau mǎhu e ama ra i roto i te mau mǎhu e ama ra. Oia ho'i, te mau mana'o tauturu no te tuatapaparaa e te haapiiraa, Te mau mana'o tauturu no te haapiiraa, Te mau nota, e te paainaraa.

1. Te mau mana'o tauturu no te tuatapaparaa e te haapiiraa:

E tupu teie huru raveraa i roto i te mau vahi i reira te mau tao'a no roto mai i te mau tao'a i î i te tao'a e nehenehe ai e faaorehia, te tape'a-maite-raa i te aifaito i roto i te puai o te tino. It’s a stable process, ti'amâ i te mau are miti puai, characterized by a specific speed of Te mau nota that depends on fuel delivery and reaction rates.

2. Constant-Volume Explosion:

Occurring within a rigid container, this ideal combustion often starts locally and spreads. In such a scenario, explosion parameters differ, necessitating a constant-volume approach. Te mau nota, the explosion pressure can be 7-9 times the initial pressure for hydrocarbon gas-air mixtures.

3. Deflagration:

Involves gradual Te mau mana'o tauturu no te acceleration due to confinement or disturbance, leading to a pressure wave. Different from constant-pressure combustion, the pressure wave and flame front move subsonically. It’s a common phenomenon in industrial explosions, often exhibiting a complex wave and zone structure.

4. Detonation:

The most intense form of gas explosion, marked by a supersonic reactive shock wave. For hydrocarbon gas-air mixtures, detonation speeds and pressures can be significantly high.

Understanding these modes is vital for preventing explosions. Deflagration, i roto ihoa râ i te, can weaken or intensify into a detonation under certain conditions, so mitigating factors that could accelerate flame propagation is crucial.