Thermal Runaway & Thermal Stability | Analog and Digital Electronics - Electrical Engineering (EE) PDF Download

Q: 1. What is thermal runaway?

Ans. Thermal runaway refers to a situation where the temperature of a system increases uncontrollably due to a positive feedback loop. It occurs when the heat generated within a system exceeds the capacity of the system to dissipate it, leading to a rapid increase in temperature.

Q: 2. How does thermal runaway occur?

Ans. Thermal runaway can occur due to various factors, such as a malfunctioning cooling system, excessive power input, or a failure in the temperature regulation mechanism. When the heat generated exceeds the system's ability to dissipate it, the temperature starts to rise rapidly, leading to thermal runaway.

Q: 3. What are the dangers of thermal runaway?

Ans. Thermal runaway can pose serious risks, such as the overheating and possible destruction of electronic components, fires, and even explosions. It can also lead to the release of toxic gases or the formation of hazardous byproducts, depending on the materials involved.

Q: 4. How can thermal runaway be prevented?

Ans. Preventing thermal runaway involves implementing measures to control and dissipate heat effectively. This can be achieved by ensuring proper ventilation and cooling systems, monitoring temperature levels, and employing safety measures such as thermal cutoff switches or alarms. Regular maintenance and inspection of the system also play a crucial role in preventing thermal runaway.

Q: 5. What is thermal stability?

Ans. Thermal stability refers to the ability of a system or material to maintain a relatively constant temperature under varying conditions. It indicates the system's resistance to thermal runaway and its capacity to dissipate heat efficiently, preventing temperature fluctuations that could lead to instability or damage. Achieving thermal stability often involves the use of thermal management techniques and appropriate design considerations.

THERMAL RUNAWAY:

The collector current for the CE circuit is given by I_C = βI_B+(1+β)I_CO . The three variables in the equation, β, I_B, and I_CO increase with rise in temperature. In particular, the reverse saturation current or leakage current I_COchanges greatly with temperature. Specifically, it doubles for every 10^oC rise in temperature. The collector current I_Ccauses the collector base junction temperature to rise which in turn, increase I_CO, as a result I_C will increase still further, which will further increase the temperature at the collector base junction. This process will become cumulative at the collector base junction leading to “thermal runaway”. Consequently, the ratings of the transistor are exceeded which may destroy the transistor itself.

The collector is made larger in size than the emitter in order to facilitate the heat dissipation at the collector junction. However if the circuit is designed such that the base current I_Bis made to decrease automatically with rise in temperature, then the decrease in βI_B will compensate for increase in the (1+β)I_CO, keeping I_C almost constant.

THERMAL RESISTANCE

Consider transistor used in a circuit where the ambient temperature of the air around the transistor is T_A^oC and the temperature of the collector-base junction of the transistor is T_J^oC.

Due to heating within the transistor, T_J is higher than T_A. As the temperature difference T_J- T_A is greater, the power dissipated in the transistor, P_D will be greater, i.e,

(T_J- T_A) ∝ P_D

The equation can be written as T_J- T_A= Thermal Runaway & Thermal Stability | Analog and Digital Electronics - Electrical Engineering (EE) P_D, where is the constant of proportionality and is called the Thermal resistance. Rearranging the above equation= (T_J- T_A) /P_D. Hence is measured in ^oC/W which may be as small as 0.2^oC/W for a high power transistor that has an efficient heat sink of up to 1000^oC/W for small signal, low power transistor which have no cooling provision.

As Θ represents total thermal resistance from a transistor junction to the ambient temperature, it is referred to as Θ_J-A. However, for power transistors, thermal resistance is given as Θ_J-C.

The amount of resistance from junction to ambience is considered to consist of 2 parts.

Θ_J-A = Θ_J-C - Θ_C-A.

which indicates that the heat dissipated in the junction must make its way to the surrounding air through two series paths from junction to case and from case to air. Hence the power dissipated is given as-

P_D = (T_J- T_A) / Θ _J-A

=(T_J- T_A )/ Θ _J-C + Θ _C-A)

Θ_J-C is determined by the type of manufacturer of the transistor and how it is located in the case, but Θ_C-A is determined by the surface area of the case or flange and its contact with air. If the effective surface area of the transistor case could be increased, the resistance to heat flows could be increased Θ_C-A, could be decreased. This can be achieved by the use of a heat sink.

The heat sink is a relatively large, finned, usually black metallic heat conducting device in close contact with transistor case or flange. Many versions of heat sink exist depending upon the shape and size of the transistor. Larger the heat sink smaller is the thermal resistance Θ_HS-A.

This thermal resistance is not added to Θ_C-A in series, but is instead in parallel with it and if Θ_HS-A is much less than Θ_C-A, then Θ_C-A will be reduced significantly, thereby improving the dissipation capability of the transistor. Thus

Θ _J-A=Θ _J-C + Θ _C-A|| Θ_HS-A.

4.8 CONDITION FOR THERMAL STABILITY:

For preventing thermal runaway, the required condition is the rate at which the heat is released at the collector junction should not exceed the rate at which the heat can be dissipated under steady state conditions. Hence the condition to be satisfied to avoid thermal runaway is given by-