We use heatsinks to keep something that is making a lot of heat cool

The only place we really have to get heat out of an object is into the air. The rate at which a heatsink can get heat into the air is determined by how hot it is and how much air comes into contact with it. Since we want to keep the item being heat sunk cool we opt to increase the amount of air coming into contact with the heat sink

Most heatsinks will have lots of thin fins giving them a ton of surface area so more air comes in contact and carries away heat. A lot will also use a fan to ram air through which lets them use tighter spaced fins for more surface area and even more heat dissipation

Sometimes you’ll see weird little pipes in the heatsink, these are called heatpipes (we’re good at naming things). They have a little liquid that changes phase in them. When its by the heat source it boils and turns into a gas then heads up to the tips of the heatpipe where it condenses and drops off its heat right next to the fins, then it travels down the walls of the heatpipe back to the base where it boils again. This works even if the heatsink isn’t bottom down because capillary action is weird

A heat sink is a drain (hence the word sink).Heat “flows” from a hot point(the top) to a cool point (the bottom) as molocules beat the heck out of each other as they heat up.
As air flows over the fins, the molocules in the metal whack the air molocules as they fly by bleeding off kinetic energy (heat) in the molocule.
Thus, for a heat sink to be effective it needs to have the maximum surface area possible so you have as many air molocules being assaulted by metal molocules as you can get.
Hence the packed in and often wavy shape of the super thin metal fins.

A heat sink is a drain (hence the word sink).Heat “flows” from a hot point(the top) to a cool point (the bottom) as molocules beat the heck out of each other as they heat up.
As air flows over the fins, the molocules in the metal whack the air molocules as they fly by bleeding off kinetic energy (heat) in the molocule.
Thus, for a heat sink to be effective it needs to have the maximum surface area possible so you have as many air molocules being assaulted by metal molocules as you can get.
Hence the packed in and often wavy shape of the super thin metal fins.

A heat sink is a drain (hence the word sink).Heat “flows” from a hot point(the top) to a cool point (the bottom) as molocules beat the heck out of each other as they heat up.
As air flows over the fins, the molocules in the metal whack the air molocules as they fly by bleeding off kinetic energy (heat) in the molocule.
Thus, for a heat sink to be effective it needs to have the maximum surface area possible so you have as many air molocules being assaulted by metal molocules as you can get.
Hence the packed in and often wavy shape of the super thin metal fins.

Heat exchangers are basically a chunk of conductive material, often aluminum, that takes heat from one object and allows it to be released into another. One thing to know about heat, or what is often called thermal energy, is that it wants to equilibrate. Heat will move from the hot place to the colder place, not the other way around, until it is nice and even.

Now, to understand the design of a heat exchanger, we need a bit of theory on the ways heat likes to move around. You have your three main ways for heat to move: conduction, convection, and radiation. The two main culprits at play in a heat exchanger are conduction and convection. Lets focus on those and ignore radiation.

Conduction is when two objects are in direct contact with each other and the heat moves from hot to cold. So you are holding a snowball, your hand conducts heat into it and the snowball feels like it is stealing your heat energy, which it is. Conduction does not work nice and linearly, it is much faster the larger the differences in temperature, which is why cold things can sometimes hurt. The materials matter too, some materials conduct heat much better than others, we call these materials conductors and their counterparts insulators.

Convection is another important piece of a heat exchanger. You can think of convection as a fluid stealing away heat from an object. That fluid can be most anything, and some are better than others. Think of standing outside on a nice fall day and the wind hits you hard, you feel rather cold rather quickly, say it is 55 degrees F ( 13 degree C) outside. Now, think of the last time you were in the water, and the water was 55 degrees F. VERY different story, you are not just a little cold you are freezing! This effect is much quicker if the water or air are moving faster, like a river. That is because water steals your heat much better than air does. So now we know that moving fluids (air/water) can steal you heat away rather well.

Now, why do they have fins.

Lets combine what we know now and add one more little piece to our new heat transfer knowledge. The efficiency of a heat exchanger is tied to its surface area and the amount of contact it has with the hot thing you are trying to cool. You want lots of good direct contact with your hot thing to allow conduction to do its job, you also want lots of contact with your fluid so it can steal away the heat faster via convection. The fins that you see on many heat exchangers are doing exactly this, they are increasing the surface area to allow convection to work much faster. More fins, faster cooling. Then you add in something to move your fluid across the fins and you are really cooling!

In conclusion:

Hot thing => conducts to metal chunk => convection steals away the heat from the metal=> heat is transferred away via the cooling fluid => the fins make the surface area larger so heat is transferred faster.

Heat exchangers are basically a chunk of conductive material, often aluminum, that takes heat from one object and allows it to be released into another. One thing to know about heat, or what is often called thermal energy, is that it wants to equilibrate. Heat will move from the hot place to the colder place, not the other way around, until it is nice and even.

Now, to understand the design of a heat exchanger, we need a bit of theory on the ways heat likes to move around. You have your three main ways for heat to move: conduction, convection, and radiation. The two main culprits at play in a heat exchanger are conduction and convection. Lets focus on those and ignore radiation.

Conduction is when two objects are in direct contact with each other and the heat moves from hot to cold. So you are holding a snowball, your hand conducts heat into it and the snowball feels like it is stealing your heat energy, which it is. Conduction does not work nice and linearly, it is much faster the larger the differences in temperature, which is why cold things can sometimes hurt. The materials matter too, some materials conduct heat much better than others, we call these materials conductors and their counterparts insulators.

Convection is another important piece of a heat exchanger. You can think of convection as a fluid stealing away heat from an object. That fluid can be most anything, and some are better than others. Think of standing outside on a nice fall day and the wind hits you hard, you feel rather cold rather quickly, say it is 55 degrees F ( 13 degree C) outside. Now, think of the last time you were in the water, and the water was 55 degrees F. VERY different story, you are not just a little cold you are freezing! This effect is much quicker if the water or air are moving faster, like a river. That is because water steals your heat much better than air does. So now we know that moving fluids (air/water) can steal you heat away rather well.

Now, why do they have fins.

Lets combine what we know now and add one more little piece to our new heat transfer knowledge. The efficiency of a heat exchanger is tied to its surface area and the amount of contact it has with the hot thing you are trying to cool. You want lots of good direct contact with your hot thing to allow conduction to do its job, you also want lots of contact with your fluid so it can steal away the heat faster via convection. The fins that you see on many heat exchangers are doing exactly this, they are increasing the surface area to allow convection to work much faster. More fins, faster cooling. Then you add in something to move your fluid across the fins and you are really cooling!

In conclusion:

Hot thing => conducts to metal chunk => convection steals away the heat from the metal=> heat is transferred away via the cooling fluid => the fins make the surface area larger so heat is transferred faster.

Use a highly conductive material to make shapes with maximum surface area to maximize heat transfer to the surrounding air. Easiest shape to manufacture is skivving a large number of thin fins.

If you need more cooling, force air into the fins to displace the warm air with fresh, cool air.

Use a highly conductive material to make shapes with maximum surface area to maximize heat transfer to the surrounding air. Easiest shape to manufacture is skivving a large number of thin fins.

If you need more cooling, force air into the fins to displace the warm air with fresh, cool air.

Use a highly conductive material to make shapes with maximum surface area to maximize heat transfer to the surrounding air. Easiest shape to manufacture is skivving a large number of thin fins.

If you need more cooling, force air into the fins to displace the warm air with fresh, cool air.

Heat exchangers are basically a chunk of conductive material, often aluminum, that takes heat from one object and allows it to be released into another. One thing to know about heat, or what is often called thermal energy, is that it wants to equilibrate. Heat will move from the hot place to the colder place, not the other way around, until it is nice and even.

Now, to understand the design of a heat exchanger, we need a bit of theory on the ways heat likes to move around. You have your three main ways for heat to move: conduction, convection, and radiation. The two main culprits at play in a heat exchanger are conduction and convection. Lets focus on those and ignore radiation.

Conduction is when two objects are in direct contact with each other and the heat moves from hot to cold. So you are holding a snowball, your hand conducts heat into it and the snowball feels like it is stealing your heat energy, which it is. Conduction does not work nice and linearly, it is much faster the larger the differences in temperature, which is why cold things can sometimes hurt. The materials matter too, some materials conduct heat much better than others, we call these materials conductors and their counterparts insulators.

Convection is another important piece of a heat exchanger. You can think of convection as a fluid stealing away heat from an object. That fluid can be most anything, and some are better than others. Think of standing outside on a nice fall day and the wind hits you hard, you feel rather cold rather quickly, say it is 55 degrees F ( 13 degree C) outside. Now, think of the last time you were in the water, and the water was 55 degrees F. VERY different story, you are not just a little cold you are freezing! This effect is much quicker if the water or air are moving faster, like a river. That is because water steals your heat much better than air does. So now we know that moving fluids (air/water) can steal you heat away rather well.

Now, why do they have fins.

Lets combine what we know now and add one more little piece to our new heat transfer knowledge. The efficiency of a heat exchanger is tied to its surface area and the amount of contact it has with the hot thing you are trying to cool. You want lots of good direct contact with your hot thing to allow conduction to do its job, you also want lots of contact with your fluid so it can steal away the heat faster via convection. The fins that you see on many heat exchangers are doing exactly this, they are increasing the surface area to allow convection to work much faster. More fins, faster cooling. Then you add in something to move your fluid across the fins and you are really cooling!

In conclusion:

Hot thing => conducts to metal chunk => convection steals away the heat from the metal=> heat is transferred away via the cooling fluid => the fins make the surface area larger so heat is transferred faster.