12 Power Elecronics: Thermal Consideration - Part 1

00:37:34
https://www.youtube.com/watch?v=tfjuu9wgSME

ꦂ要

TLDRThe lecture focuses on the importance of thermal considerations in power electronics, particularly for MOSFETs and transistors. It explains how thermal dissipation affects component performance, emphasizing the need to manage heat to prevent damage. Key points include understanding thermal resistance, derating due to temperature increases, and utilizing heatsinks and other cooling mechanisms. The lecture also explains how electrical analogies can model thermal behavior, helping designers calculate and manage junction temperatures accurately to assure reliability in varying ambient conditions.

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  • šŸ”Œ The importance of early thermal considerations in power electronics design.
  • šŸ“‰ Derating is crucial to prevent component failure at high temperatures.
  • āš ļø Overheating can severely degrade MOSFET performance.
  • šŸ“‘ Understanding datasheet ratings is critical for appropriate design.
  • šŸ‘· Proper thermal design ensures components run below critical temperatures.
  • šŸŒ€ Heatsinks and cooling fans aid in managing heat efficiently.
  • šŸ” Junction temperature is a key parameter to monitor for avoiding damage.
  • šŸ”„ Thermal resistance parallels ohmic resistance in circuit analysis.
  • šŸ’” Electrical analogies facilitate thermal simulation and design planning.
  • šŸ–Šļø Contact with heatsinks needs optimization to minimize thermal resistance.

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  • 00:00:00 - 00:05:00

    The speaker introduces the topic of thermal considerations in power electronics, emphasizing its importance. They mention it is often overlooked in educational curriculums and aim to teach it before discussing switches. They explain that both linear and switch operations in transistors dissipate power which becomes heat, with inadequate design potentially damaging transistors. The importance of understanding datasheets' absolute maximum ratings, particularly in relation to ambient temperature and current capacity, is highlighted.

  • 00:05:00 - 00:10:00

    A discussion on heat dissipation and the reduction of current flow due to increased temperatures. The speaker uses examples of MOSFETs to illustrate the significance of temperature on performance, stressing the need for proper thermal design. They draw attention to the concept of the linear derating factor, explaining its role in power dissipation adjustments with temperature variations. Emphasis is placed on maintaining junction temperature within specified limits to prevent MOSFET damage.

  • 00:10:00 - 00:15:00

    The video further explains the thermal path from a transistor's junction to its case and beyond, outlining the role of thermal resistance. Thermal resistance causes temperature differences, affecting the ease of heat flow from the junction to the case. The concept is likened to electrical resistance, suggesting small resistance allows easier heat flow. They explain the necessity of understanding these thermal paths for effective design and introduce the concept of RĪø (theta) as a measure of thermal resistance between different points in a system.

  • 00:15:00 - 00:20:00

    The speaker uses electrical circuit analogies to explain thermal resistance and heat dissipation in transistors. They equate the flow of heat to electrical current, using circuit diagrams to simulate thermal behaviour. The components between the junction and ambient temperature, including cases, heatsinks, and their respective resistances, are detailed. This analogy helps in calculating junction temperatures indirectly.

  • 00:20:00 - 00:25:00

    Different examples of MOSFET packages are provided to illustrate variations in thermal resistance depending on packaging. The significance of choosing the right MOSFET package for a specific application based on its thermal resistance properties is emphasized. Examples underline that while the junction-to-case resistance might remain constant, junction-to-ambient resistance can vary significantly based on MOSFET design and external thermal management like heatsinks.

  • 00:25:00 - 00:30:00

    The speaker details the role of heatsinks in managing thermal resistance and maintaining effective temperature dissipation in transistors. They discuss heatsink datasheet interpretation, demonstrating how to calculate effective thermal resistance under different conditions. The impact of fan-assisted cooling versus natural convection on thermal resistance is outlined, with practical examples provided. Understanding heatsinks' thermal properties is stressed for effective thermal management.

  • 00:30:00 - 00:37:34

    The talk concludes by discussing the limitations and design considerations for heatsinks, specifically the effects of fin spacing on thermal resistance. The optimal balance between surface area and airflow for maximal cooling efficiency is highlighted. The importance of selecting the right heatsink based on thermal resistance and power dissipation needs for specific applications is reiterated, with a promise of future videos to delve into practical examples and simulations.

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Mind Map

悈恏恂悋č³Ŗ問

  • Why is thermal consideration important in power electronics?

    Thermal considerations are crucial because improper thermal design can lead to overheating, damaging the components like MOSFETs and transistors.

  • What can happen if I ignore thermal design for MOSFETs?

    Ignoring thermal design can lead to overheating and potential damage or failure of the MOSFET.

  • What is the absolute maximum rating found in datasheets?

    Absolute maximum ratings denote the highest allowable level of current, voltage, and power a component can handle without damage.

  • What is meant by 'derating' in thermal design?

    Derating refers to reducing the operational power or current levels as the temperature increases to prevent overheating and potential damage.

  • How does temperature affect a MOSFET's current handling capability?

    As temperature increases, the MOSFET's current handling capability decreases, reducing the maximum current it can safely pass.

  • What is thermal resistance in this context?

    Thermal resistance is a measure of the device's ability to dissipate heat and is analogous to electrical resistance, representing the ease with which heat can flow through the system.

  • Can electrical models be used to understand thermal behavior?

    Yes, thermal behavior can be mimicked using electrical models, relating current to power dissipation and voltage to temperature difference.

  • What role do heatsinks play in thermal management?

    Heatsinks help dissipate heat from components, reducing the thermal resistance between the component and ambient environment to manage temperatures effectively.

  • Why is heatsink physical design important?

    The physical design of heatsinks, including fin spacing, affects their ability to dissipate heat efficiently, impacting overall thermal resistance.

  • What is the junction temperature, and why should it be monitored?

    Junction temperature is the temperature within the MOSFET die that could become too high and lead to failure. Monitoring this ensures it stays below a critical threshold to maintain functionality.

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  • 00:00:00
    hi and welcome back to uh power
  • 00:00:02
    electronics lectures
  • 00:00:03
    and today we are going to cover fairmell
  • 00:00:06
    consideration
  • 00:00:08
    this is one of the important topics
  • 00:00:09
    sometimes they are ignored
  • 00:00:11
    in the curriculum of power electronics
  • 00:00:14
    or sometimes delayed too much
  • 00:00:16
    so the learners actually don't feel the
  • 00:00:19
    importance of this to be so that's why i
  • 00:00:22
    uh
  • 00:00:23
    maybe this time organize it to be
  • 00:00:26
    introduced earlier before even
  • 00:00:28
    we talk about switches because later on
  • 00:00:31
    when we talk about switches and
  • 00:00:32
    participations
  • 00:00:33
    and the advantage at this advantage that
  • 00:00:36
    thermal consideration will be
  • 00:00:38
    also considered during explaining these
  • 00:00:42
    switches so today we will consider
  • 00:00:45
    talking about this important topic
  • 00:00:47
    one of our previous videos we have
  • 00:00:49
    discussed the linear operation and the
  • 00:00:50
    switch operation
  • 00:00:52
    uh for for example for transistor and
  • 00:00:55
    both
  • 00:00:56
    uh have been used to step down the
  • 00:00:58
    voltage from high voltage to lower
  • 00:01:00
    voltage
  • 00:01:01
    and but both of them they dissipated
  • 00:01:05
    different values
  • 00:01:06
    of power and for example for the linear
  • 00:01:09
    we have seen something very high
  • 00:01:11
    for the switch we have seen something
  • 00:01:13
    very low and when
  • 00:01:14
    we use the artist wise it's not zero but
  • 00:01:18
    still some significant value and
  • 00:01:21
    regardless of high and low this power
  • 00:01:24
    distribution will be
  • 00:01:25
    translated to heat finally and
  • 00:01:28
    if i didn't consider good design
  • 00:01:31
    for the heat i will came up to the
  • 00:01:34
    maximum
  • 00:01:35
    and finally i might damage my transistor
  • 00:01:38
    so
  • 00:01:38
    every mosfet or transistor has a data
  • 00:01:41
    sheet and you have something called
  • 00:01:43
    absolute
  • 00:01:44
    maximum ratings and we let's look at the
  • 00:01:47
    continuous
  • 00:01:48
    drain current here we have two values
  • 00:01:51
    and these two values at
  • 00:01:53
    different temperatures so i can use this
  • 00:01:56
    mosfet for example to pass or to flow
  • 00:02:00
    eight ampere if i maintain the
  • 00:02:02
    temperature of the case
  • 00:02:04
    at 25 degree but if the temperature of
  • 00:02:07
    the case
  • 00:02:08
    raised to 100 degree i can't do
  • 00:02:11
    eight and there again i have to reduce
  • 00:02:14
    it or the maximum is reduced to five
  • 00:02:16
    so see this reduction is from eight
  • 00:02:18
    ampere to five ampere it's not
  • 00:02:21
    small reduction it's very significant
  • 00:02:22
    reduction and this link this with the
  • 00:02:25
    power dissipation
  • 00:02:26
    the maximum power dissipation at 25
  • 00:02:28
    degree
  • 00:02:29
    is 125 watt but
  • 00:02:33
    if the temperature is increased so this
  • 00:02:36
    one is not anymore working so
  • 00:02:38
    we have to consider this mosfet maybe to
  • 00:02:40
    be 100 watt or even
  • 00:02:42
    80 watt and if i keep pushing that
  • 00:02:45
    transistor to pass the same voltage and
  • 00:02:47
    current
  • 00:02:48
    i will end up damaging my mosfet
  • 00:02:52
    so let's link this figure here with this
  • 00:02:55
    figure which is called
  • 00:02:56
    linear d rating factor that linear d
  • 00:02:59
    rating factor it says it's
  • 00:03:01
    one what pair cell is used where degrees
  • 00:03:04
    celsius
  • 00:03:05
    that means for each one degree series is
  • 00:03:08
    increase
  • 00:03:08
    above the ambient i'm i will lose one
  • 00:03:12
    watt of the capability of
  • 00:03:15
    dissipating power that means if i have
  • 00:03:19
    10 degree above the ambient and instead
  • 00:03:21
    of 25
  • 00:03:22
    i have now my mosfet has a temperature
  • 00:03:25
    of 35
  • 00:03:26
    i will lose 10 watt from my maximum
  • 00:03:31
    power dissipation for example 115
  • 00:03:34
    instead of 125
  • 00:03:36
    and if i'm working at different
  • 00:03:38
    temperatures i will lose
  • 00:03:40
    a proportional percentage of this one so
  • 00:03:43
    that's why
  • 00:03:45
    the temperature actually present
  • 00:03:48
    for me or produce for me a new mosfet
  • 00:03:52
    with different ratings that i should
  • 00:03:54
    consider
  • 00:03:55
    and if i didn't i will damage my mosfet
  • 00:03:58
    and the thing that i need to look at and
  • 00:04:00
    maintain
  • 00:04:00
    always is called the junction
  • 00:04:02
    temperature we have here the junction
  • 00:04:04
    temperature it says
  • 00:04:06
    it's up to 150 degree that means my
  • 00:04:09
    junction temperature which is
  • 00:04:11
    the inside my transistor
  • 00:04:14
    if it exceeds the temperature which is
  • 00:04:16
    the in this table
  • 00:04:18
    that means i will damage my mosfet so
  • 00:04:21
    this is
  • 00:04:21
    my goal and objective to keep this
  • 00:04:23
    junction
  • 00:04:24
    temperature to be less than 150 and to
  • 00:04:27
    maintain
  • 00:04:28
    also good margin i have to keep it below
  • 00:04:31
    100
  • 00:04:32
    degrees celsius for example and again
  • 00:04:35
    from the same data sheet irf 840
  • 00:04:38
    i have seen the current now
  • 00:04:41
    it was 8 ampere if we consider 25 degree
  • 00:04:45
    case temperature but if the temperature
  • 00:04:47
    now start
  • 00:04:48
    increasing and this is natural because
  • 00:04:51
    it will increase if we draw some current
  • 00:04:53
    and that will be translated to power
  • 00:04:55
    dissipation and then heat
  • 00:04:57
    so if for example i am now at hundred
  • 00:04:59
    degree
  • 00:05:00
    this will come up at five ampere so my
  • 00:05:03
    uh transistor now is changing and the
  • 00:05:06
    current
  • 00:05:07
    that was able to to flow
  • 00:05:10
    is not anymore working and the same for
  • 00:05:13
    example
  • 00:05:14
    something called power d rating curve
  • 00:05:16
    and some that is each
  • 00:05:17
    data sheets provide this curve and one
  • 00:05:20
    of the
  • 00:05:20
    mosfets is irfp 240. that curve tell us
  • 00:05:24
    if you are at low temperatures here okay
  • 00:05:28
    you can use this mosfet to dissipate 150
  • 00:05:32
    watt
  • 00:05:32
    but for example if your temperature is
  • 00:05:34
    increasing because you didn't
  • 00:05:36
    um design your thermal anticipation
  • 00:05:40
    well and you didn't consider me for
  • 00:05:42
    example a cooling element or a fan
  • 00:05:45
    or a heatsink so this will increase
  • 00:05:48
    maybe for example 100 degree 100 degree
  • 00:05:51
    i will come up with
  • 00:05:52
    60 watt dissipation maximum that means i
  • 00:05:55
    if i if i kept my voltage and current
  • 00:05:58
    the same
  • 00:06:00
    for all the period while that
  • 00:06:01
    temperature is increasing
  • 00:06:03
    i will definitely lose my lose my mosfet
  • 00:06:06
    because of
  • 00:06:07
    the d rating factor that's shown in this
  • 00:06:10
    curve
  • 00:06:11
    so all this introduction is to emphasize
  • 00:06:14
    the importance of thermal
  • 00:06:16
    design and consideration that we have to
  • 00:06:20
    take into account to make our mosfet
  • 00:06:23
    work in any different
  • 00:06:25
    uh environment or ambient temperatures
  • 00:06:28
    so the primary goal of our design
  • 00:06:31
    thermal design is to limit the junction
  • 00:06:33
    temperature and you might ask what is
  • 00:06:35
    the junction temperature
  • 00:06:37
    look at the mos mosfet some mosfets
  • 00:06:39
    these are two mosfets and these are two
  • 00:06:41
    bgts
  • 00:06:42
    for example and we have something inside
  • 00:06:45
    them
  • 00:06:45
    called a dye and that dye is the
  • 00:06:48
    silicone piece
  • 00:06:49
    okay um or different semiconductor
  • 00:06:52
    a material and inside it there is a
  • 00:06:55
    junction
  • 00:06:55
    okay p and junction p and p junction or
  • 00:06:58
    or and channels or and
  • 00:07:00
    any junction that uh will be uh
  • 00:07:03
    controlled
  • 00:07:04
    to uh past the um the the current
  • 00:07:08
    and inside this die the junction we have
  • 00:07:12
    to keep that junction
  • 00:07:13
    below the 150 as we have seen in one of
  • 00:07:15
    the data sheets
  • 00:07:17
    so we have different shapes and
  • 00:07:18
    different maybe um
  • 00:07:21
    texture for them but all of these are
  • 00:07:24
    embedded inside and we
  • 00:07:25
    can't measure the temperature of that
  • 00:07:28
    junction so the direct measurement of
  • 00:07:30
    the junction is difficult because its
  • 00:07:32
    package
  • 00:07:32
    blocks access to that junction and
  • 00:07:35
    sometimes we have to measure
  • 00:07:37
    this uh this temperature of that
  • 00:07:41
    junction
  • 00:07:42
    but indirectly using the case
  • 00:07:45
    or the body uh
  • 00:07:48
    exposed metal just to know what is the
  • 00:07:51
    temperature of the inside
  • 00:07:53
    which is the junction and to do that we
  • 00:07:56
    have to know the characteristics
  • 00:07:58
    of the thermal components between that
  • 00:08:02
    junction and between that case
  • 00:08:03
    okay so this is the goal and we have now
  • 00:08:07
    to understand
  • 00:08:08
    how the heat transfer from this junction
  • 00:08:12
    to the ambient okay and
  • 00:08:16
    after that we do our calculation and
  • 00:08:18
    really understand
  • 00:08:19
    what is required to make a proper design
  • 00:08:22
    to start we have
  • 00:08:23
    a transistor here and that's the die
  • 00:08:25
    with the junction
  • 00:08:27
    and we have here the die that die with a
  • 00:08:30
    junction
  • 00:08:31
    will take the power electrical power
  • 00:08:33
    dissipated
  • 00:08:34
    which is um produced by multiplication
  • 00:08:37
    of current and voltage
  • 00:08:39
    and then translate that or convert it to
  • 00:08:41
    heat
  • 00:08:42
    that heat now will be
  • 00:08:45
    flowing through the body of that dye
  • 00:08:49
    and going to the case and that should be
  • 00:08:52
    designed by the manufacturer
  • 00:08:54
    to make a direct flow or the easy way
  • 00:08:57
    for the heat to go from the dye to the
  • 00:09:01
    case if it's kept inside it will be
  • 00:09:04
    it will exceed the maximum temperature
  • 00:09:07
    very quickly
  • 00:09:08
    and damage the junction so that's why we
  • 00:09:11
    have here the temperature of the
  • 00:09:12
    junction
  • 00:09:13
    and that dye is is sitting on the
  • 00:09:16
    uh case and that case also by the time
  • 00:09:20
    while while this developing higher and
  • 00:09:22
    higher current
  • 00:09:23
    higher and higher temperature that also
  • 00:09:25
    the case will develop
  • 00:09:27
    a new temperature but less than the
  • 00:09:30
    uh junction now if that is a hundred
  • 00:09:33
    degrees celsius
  • 00:09:34
    the case will be less than 100 degrees
  • 00:09:37
    celsius
  • 00:09:38
    what controls how much less
  • 00:09:42
    temperature it's called there's a new
  • 00:09:44
    component here between them
  • 00:09:46
    it's called the thermal resistance and
  • 00:09:48
    the thermal resistance works exactly
  • 00:09:50
    like the
  • 00:09:51
    electrical resistance because the
  • 00:09:53
    thermal resistance here
  • 00:09:54
    it blocks the temperature to go from the
  • 00:09:57
    die
  • 00:09:58
    or the junction to the case and if that
  • 00:10:02
    resistance is very very very small that
  • 00:10:04
    means the way of the temperature to
  • 00:10:07
    to go to the case is very easy and all
  • 00:10:09
    will be
  • 00:10:10
    uh fine to go without any obstacles in
  • 00:10:13
    the way
  • 00:10:14
    and the temperature of the case will be
  • 00:10:15
    very close to the temperature of the
  • 00:10:18
    junction but if the resistance here
  • 00:10:20
    between the dye
  • 00:10:22
    and the case very very high that means
  • 00:10:24
    that junction temperature will be kept
  • 00:10:26
    inside
  • 00:10:27
    and the difference between them will be
  • 00:10:29
    also very high
  • 00:10:30
    this is exactly like the electrical
  • 00:10:33
    component
  • 00:10:34
    and this resistance here is is called
  • 00:10:37
    our theta okay thermal resistance and
  • 00:10:40
    because
  • 00:10:40
    our theta this one is between the
  • 00:10:42
    junction and the case
  • 00:10:44
    we call it r theta j c or
  • 00:10:47
    our theta junction to the case okay so
  • 00:10:51
    now look at the junction which is this
  • 00:10:53
    inside
  • 00:10:54
    here we can't actually see it but here
  • 00:10:56
    we have the case
  • 00:10:57
    okay and the case some part of the case
  • 00:11:00
    is exposed to the ambient
  • 00:11:02
    that means some maybe the front side
  • 00:11:05
    here
  • 00:11:05
    is can deliver something richer to the
  • 00:11:08
    ambient and radiate it
  • 00:11:10
    so that's why we have ambient
  • 00:11:11
    temperature here
  • 00:11:13
    and we have something called the thermal
  • 00:11:16
    resistance between the case
  • 00:11:18
    and the ambient and we call it our theta
  • 00:11:21
    case to the ambient
  • 00:11:22
    okay but because that
  • 00:11:25
    case okay can also be attached to the
  • 00:11:28
    heatsink
  • 00:11:29
    if we choosing to install heatsink here
  • 00:11:32
    we have
  • 00:11:32
    another uh choice to make the heatsink
  • 00:11:37
    here
  • 00:11:37
    and there is another component between
  • 00:11:41
    the case and the heatsink which is
  • 00:11:43
    another thermal resistance
  • 00:11:44
    that resistance is called case to the
  • 00:11:47
    heatsink okay
  • 00:11:48
    if we made a good contact between that
  • 00:11:51
    case and the heatsink
  • 00:11:53
    and the the surface is finished very
  • 00:11:56
    well to make a very good
  • 00:11:57
    thermal contact for example we added
  • 00:11:59
    some grease
  • 00:12:01
    or some thermal sheets between these two
  • 00:12:04
    surfaces
  • 00:12:05
    this will increase the surface area
  • 00:12:08
    that can really radiate the heat and
  • 00:12:11
    that
  • 00:12:11
    will make this uh resistance very very
  • 00:12:15
    low
  • 00:12:16
    and that temperature developed in the
  • 00:12:18
    case will also go
  • 00:12:20
    and dissipated also by the heatsink
  • 00:12:23
    because the heatsink now will start
  • 00:12:25
    acquiring this temperature and this heat
  • 00:12:28
    and and raise the
  • 00:12:31
    it's simply above their fins here will
  • 00:12:33
    dissipate it to the ambient
  • 00:12:35
    so this is actually what we have and
  • 00:12:38
    and maybe the last point here we have
  • 00:12:40
    another
  • 00:12:41
    uh resistance which is from the heatsink
  • 00:12:44
    to the ambient okay so now the journey
  • 00:12:48
    from the junction to the ambient okay
  • 00:12:51
    it's also from the junction
  • 00:12:53
    through the junction to case thermal
  • 00:12:56
    resistance
  • 00:12:58
    to case uh to the um
  • 00:13:01
    case heatsink thermal resistance and
  • 00:13:03
    then heatsink to ambient thermal
  • 00:13:05
    resistance
  • 00:13:06
    this is the easy way to flow we have
  • 00:13:08
    another way here
  • 00:13:10
    okay but that resistance is considered
  • 00:13:12
    as very high and we know
  • 00:13:14
    the electrical current if it finds
  • 00:13:18
    two resistors it will go through the
  • 00:13:21
    least
  • 00:13:22
    uh uh resistance way uh in
  • 00:13:25
    in more proportion than the higher
  • 00:13:27
    resistance way okay
  • 00:13:28
    and the same for the heat the heat will
  • 00:13:31
    come here okay
  • 00:13:32
    and we'll find two ways the way to the
  • 00:13:35
    ambient and the way to the heatsink and
  • 00:13:37
    because we have done here
  • 00:13:39
    a good uh thermal
  • 00:13:42
    a contact with very
  • 00:13:46
    low resistance it will prefer to go to
  • 00:13:49
    the
  • 00:13:49
    to the heatsink and dissipated by the
  • 00:13:51
    heatsink okay
  • 00:13:52
    and the amount of heat will dissipate
  • 00:13:54
    directly by that case it will be very
  • 00:13:56
    tiny
  • 00:13:57
    and we will see this actually from the
  • 00:13:59
    data sheet where they specify this one
  • 00:14:02
    is much much higher than these two
  • 00:14:05
    and now after understanding the flow of
  • 00:14:07
    the heat from the junction to the
  • 00:14:08
    ambient
  • 00:14:09
    and we mentioned many times the
  • 00:14:11
    resistance resistance resistance and we
  • 00:14:13
    know there is a resistance
  • 00:14:14
    in the electrical also
  • 00:14:19
    circuits so is that really related to
  • 00:14:22
    electrical can we really
  • 00:14:24
    simulate the heat flow here and we know
  • 00:14:27
    the temperature of the junction or the
  • 00:14:29
    case or heatsink
  • 00:14:30
    by knowing the voltages for example yes
  • 00:14:34
    we can really mimic that flow from the
  • 00:14:37
    junction to the
  • 00:14:38
    ambient by another topology like this
  • 00:14:41
    one
  • 00:14:42
    okay that g is using a current source
  • 00:14:44
    that
  • 00:14:45
    the value of that current source is is
  • 00:14:47
    the same as power dissipated
  • 00:14:49
    so the participated here is translated
  • 00:14:52
    to heat
  • 00:14:52
    but here we are translating it to
  • 00:14:54
    current source okay
  • 00:14:56
    and that current source will push some
  • 00:14:58
    current through these resistances
  • 00:15:00
    which are the exact resistances from the
  • 00:15:03
    way
  • 00:15:04
    uh that the heat flow here okay so we
  • 00:15:06
    have here the junction
  • 00:15:07
    the resistance from the junction to the
  • 00:15:09
    case and then the resistance from the
  • 00:15:12
    case to heatsink
  • 00:15:13
    and then the resistance from the
  • 00:15:14
    heatsink to the ambient and the final
  • 00:15:17
    point here is the ambient
  • 00:15:19
    uh temperature and because we consider
  • 00:15:22
    sometimes the ambient temperature to be
  • 00:15:23
    a constant
  • 00:15:24
    for example 25 degree so that's why we
  • 00:15:27
    have
  • 00:15:28
    uh we have set here a voltage source
  • 00:15:31
    that voltage source
  • 00:15:32
    has a 25 volt and the volt here
  • 00:15:35
    it it means that the cylinders degree so
  • 00:15:38
    the temperature of the ambient
  • 00:15:40
    here will be 25 uh series use
  • 00:15:43
    degree celsius and if you look at the
  • 00:15:46
    circuit here
  • 00:15:47
    i think it's very very easy circuit
  • 00:15:50
    because you have
  • 00:15:51
    defined current okay and that current
  • 00:15:53
    will go through this resistance
  • 00:15:56
    and will develop some voltage okay that
  • 00:15:59
    voltage
  • 00:15:59
    it's the difference between that
  • 00:16:01
    junction
  • 00:16:02
    and that temperature case okay and will
  • 00:16:05
    also flow
  • 00:16:06
    through this resistor here and develop
  • 00:16:09
    also another voltage
  • 00:16:10
    and also we'll flow this uh through this
  • 00:16:12
    one and develop another
  • 00:16:14
    voltage and we know this ambient
  • 00:16:16
    temperature we know that
  • 00:16:18
    the the the current and the values of
  • 00:16:21
    this resistance so all the differences
  • 00:16:23
    here between these points and bridges
  • 00:16:25
    will be also known so some of this
  • 00:16:28
    resistance value will be taken
  • 00:16:29
    from data sheet the power dissipated
  • 00:16:31
    will be calculated by u
  • 00:16:34
    as we have explained before and the
  • 00:16:36
    ambient will be considered as
  • 00:16:38
    as constant as 25 or other um
  • 00:16:41
    temperature values according to what is
  • 00:16:43
    given and that enables
  • 00:16:45
    us to estimate the junction temperature
  • 00:16:48
    that we can't actually measure
  • 00:16:50
    okay directly we can estimate our
  • 00:16:52
    calculate the junction temperature
  • 00:16:54
    by knowing all these resistances and the
  • 00:16:57
    power dissipation
  • 00:16:58
    and also uh we can also estimate uh the
  • 00:17:01
    the the
  • 00:17:02
    temperatures and the case and also the
  • 00:17:05
    hissing
  • 00:17:06
    so let's now go another
  • 00:17:09
    step and see how we really translate
  • 00:17:12
    that
  • 00:17:13
    circuit to something that we can use in
  • 00:17:15
    any simulator
  • 00:17:17
    and we can run some simulation exactly
  • 00:17:19
    like
  • 00:17:20
    calculating ohm's law so the thermal
  • 00:17:22
    resistance is a component that
  • 00:17:25
    has two points difference
  • 00:17:28
    in temperature okay which is tj and tc
  • 00:17:32
    and that tj junction and case the
  • 00:17:34
    difference between
  • 00:17:36
    them will be directly proportional to
  • 00:17:39
    that
  • 00:17:39
    participated and after some experiments
  • 00:17:42
    you will find that
  • 00:17:44
    the relation between the difference of
  • 00:17:46
    temperatures here and power dissipation
  • 00:17:48
    is controlled by the thermal resistance
  • 00:17:51
    so now we have different uh temperatures
  • 00:17:55
    here
  • 00:17:55
    the difference between them is
  • 00:17:57
    controlled by the power dissipation
  • 00:17:59
    times the
  • 00:18:00
    thermal resistance by taking and
  • 00:18:02
    manipulating this relation
  • 00:18:03
    a little bit we will come up with this
  • 00:18:06
    relation which is
  • 00:18:07
    the thermal resistance equal the
  • 00:18:09
    temperature difference between these two
  • 00:18:11
    points
  • 00:18:12
    divided by the power dissipation
  • 00:18:15
    and if we compare it with the ohms
  • 00:18:18
    though electrical ohms law
  • 00:18:20
    we find that electrical ohm's law okay
  • 00:18:23
    electrical resistance equal the
  • 00:18:24
    difference in voltage between that point
  • 00:18:27
    and that point
  • 00:18:28
    divided by the current okay
  • 00:18:31
    but in the thermal the thermal
  • 00:18:34
    resistance equal the difference
  • 00:18:35
    in temperature here okay between that
  • 00:18:38
    point and that point so the temperature
  • 00:18:40
    difference is equal to the voltage
  • 00:18:42
    difference divided by the power
  • 00:18:44
    dissipation
  • 00:18:45
    so that's why we represented the power
  • 00:18:48
    dissipation by a current source because
  • 00:18:51
    it mimics the electrical current source
  • 00:18:54
    and now by taking this equation a little
  • 00:18:57
    bit
  • 00:18:58
    more we have the participation here
  • 00:19:00
    that's
  • 00:19:01
    considered as a current source and that
  • 00:19:03
    will go through the
  • 00:19:04
    uh junction to case thermal resistance
  • 00:19:07
    look at this one junction two case
  • 00:19:10
    thermal resistance
  • 00:19:11
    and after that we have two ways the
  • 00:19:13
    first way is
  • 00:19:14
    from the case to the ambient and the
  • 00:19:16
    second way is
  • 00:19:17
    from the case to the heatsink so one
  • 00:19:20
    once we just came up to the temperature
  • 00:19:22
    of the case we have two ways
  • 00:19:24
    the case to the ambient and it reached
  • 00:19:26
    the ambient temperature here
  • 00:19:28
    and also the case to the heat sink and
  • 00:19:30
    after going
  • 00:19:31
    from the case to the heatsink we have
  • 00:19:33
    also another one which is from the
  • 00:19:35
    heatsink to the
  • 00:19:36
    ambient okay and because this one was
  • 00:19:39
    very very very large so that's why i
  • 00:19:42
    uh ignored this in the first
  • 00:19:46
    graph but here i just want to consider
  • 00:19:49
    it because
  • 00:19:50
    i want to deliver my uh full view
  • 00:19:53
    okay so now we have current source and
  • 00:19:56
    we have voltage here
  • 00:19:57
    uh constant voltage okay that means that
  • 00:19:59
    makes this point
  • 00:20:00
    constant the temperature at any point
  • 00:20:03
    here
  • 00:20:04
    is the same voltage we calculate for
  • 00:20:07
    this
  • 00:20:07
    electrical circuit and the current
  • 00:20:11
    here the value of the current source
  • 00:20:13
    here okay is actually the same as the
  • 00:20:15
    power dissipated calculated electrically
  • 00:20:18
    and the temperature or the thermal uh
  • 00:20:21
    resistance here can be taken from the
  • 00:20:24
    data sheet or the
  • 00:20:26
    uh data sheet of the mosfet or the or
  • 00:20:28
    data sheet of the heatsink itself
  • 00:20:31
    and you will find some data sheets
  • 00:20:35
    calculated or presented as uh how many
  • 00:20:38
    degrees where what
  • 00:20:39
    or how many kelvins per watt if you find
  • 00:20:42
    this or find this
  • 00:20:43
    they are the same why because the the
  • 00:20:46
    increment
  • 00:20:46
    in kelvin pair while it's exactly the
  • 00:20:49
    same as
  • 00:20:50
    increment of degrees per watt so it's a
  • 00:20:53
    ratio
  • 00:20:54
    equals a ratio okay so that's why if you
  • 00:20:56
    if you found kelvin or degree
  • 00:20:58
    don't try to convert okay it's just take
  • 00:21:01
    it as it is because they are
  • 00:21:03
    equal and if you look at this model this
  • 00:21:05
    is the electrical model
  • 00:21:06
    and if you then throw some references
  • 00:21:09
    for example books or
  • 00:21:12
    papers you will find maybe a little bit
  • 00:21:15
    different models okay
  • 00:21:17
    one of them they use this uh
  • 00:21:21
    this current source and that was is
  • 00:21:23
    floating
  • 00:21:24
    but uh maybe the correct one is to
  • 00:21:27
    consider this
  • 00:21:29
    current source is is reference to the
  • 00:21:31
    ambient temperature because the
  • 00:21:33
    definition
  • 00:21:34
    of the power dissipation is
  • 00:21:37
    is the power dissipation that's
  • 00:21:38
    converted to heat to raise
  • 00:21:41
    the temperature of the junction above
  • 00:21:43
    the ambient okay
  • 00:21:44
    so that's why maybe this one is more
  • 00:21:46
    accurate and some
  • 00:21:48
    references they just attach to the
  • 00:21:50
    ground which is zero degree here okay
  • 00:21:52
    so if you consider this one or this one
  • 00:21:54
    or this one
  • 00:21:55
    the good news is they are bringing to
  • 00:21:58
    you the same answer so
  • 00:22:00
    don't worry about which one you find it
  • 00:22:02
    which one is correct or wrong no
  • 00:22:04
    all of them are right and uh correct and
  • 00:22:07
    they can consider
  • 00:22:08
    that they can be considered but maybe
  • 00:22:10
    the
  • 00:22:11
    this one and this one can be easily
  • 00:22:14
    drawn in
  • 00:22:14
    uh electrical simulator and the circuit
  • 00:22:17
    simulators
  • 00:22:18
    like lt spies and and can be used for a
  • 00:22:21
    calculation of these temperature
  • 00:22:23
    uh points here and maybe in in this
  • 00:22:25
    module i will consider this one
  • 00:22:27
    because it's easy uh for us just to draw
  • 00:22:30
    it and
  • 00:22:31
    just to bring all these uh
  • 00:22:34
    calculation very easily uh one important
  • 00:22:37
    point which is
  • 00:22:38
    all these models are steady state models
  • 00:22:41
    if you also gonna throw some references
  • 00:22:43
    you will find you will find
  • 00:22:45
    some references adding some capacitors
  • 00:22:48
    across these resistors because they want
  • 00:22:51
    to say the grow
  • 00:22:53
    okay over time of that temperature
  • 00:22:56
    but these models are giving us the final
  • 00:22:59
    temperature they don't actually
  • 00:23:01
    uh introduce us or show to us the
  • 00:23:04
    growth of the temperature over time like
  • 00:23:06
    the capacitor
  • 00:23:08
    charging okay so that's why we will
  • 00:23:10
    consider this just for design
  • 00:23:12
    we want to know what's the final value
  • 00:23:14
    to consider it if we want to
  • 00:23:17
    use heatsink or a fan or just uh we are
  • 00:23:20
    fine with it okay
  • 00:23:21
    so we don't or we we are not interested
  • 00:23:23
    here in the transient
  • 00:23:25
    and if you're gonna throw many data
  • 00:23:27
    sheets and for example rf
  • 00:23:29
    840 just to know where where are the
  • 00:23:32
    uh these thermal resistance uh
  • 00:23:36
    may be included so we have some some
  • 00:23:38
    parts of the tables they call
  • 00:23:40
    them resistance ratings and one of them
  • 00:23:42
    is called
  • 00:23:43
    junction to ambient that means it's the
  • 00:23:46
    r theta junction to ambient
  • 00:23:49
    okay from junction to the ambient does
  • 00:23:52
    it consider
  • 00:23:54
    the heatsink or no the answer is
  • 00:23:57
    no the junction to ambient means this
  • 00:24:00
    resistor
  • 00:24:01
    plus this resistor they are all
  • 00:24:03
    contained now
  • 00:24:04
    together all combined together as one
  • 00:24:07
    resistor
  • 00:24:08
    because they consider that you will not
  • 00:24:10
    use the heatsink so
  • 00:24:12
    all this part now is not there okay
  • 00:24:15
    for the first item here that means this
  • 00:24:18
    resistor plus this resistor
  • 00:24:20
    is 62 series per watt
  • 00:24:24
    okay and that value is taken
  • 00:24:27
    if you are considering your calculation
  • 00:24:30
    without heatsink you want to know
  • 00:24:32
    if you didn't use the heatsink how much
  • 00:24:34
    the
  • 00:24:35
    junction temperature okay so it's easy
  • 00:24:37
    you know the participation
  • 00:24:39
    you know this value plus this value is
  • 00:24:41
    62
  • 00:24:42
    and you know the ambient so it's easy to
  • 00:24:44
    calculate the junction
  • 00:24:46
    temperature and you will finally
  • 00:24:49
    decide whether it's more than 150 or no
  • 00:24:52
    but
  • 00:24:52
    now we have also different values this
  • 00:24:55
    value is called case to heatsink
  • 00:24:58
    so i think we mean this one okay
  • 00:25:01
    case to heat sink and it says here we
  • 00:25:04
    have a flat
  • 00:25:04
    surface and the greased that means it
  • 00:25:07
    look like this
  • 00:25:08
    okay so it's a flat surface and the
  • 00:25:11
    grease that means we have
  • 00:25:12
    some material that make a good and
  • 00:25:14
    perfect contact
  • 00:25:16
    between the two surfaces because we have
  • 00:25:18
    some defects and that
  • 00:25:19
    grease will will fill these defects and
  • 00:25:22
    make a good thermal contact
  • 00:25:24
    and this resistor here if we've done
  • 00:25:27
    this
  • 00:25:28
    we will bring the resistance to be
  • 00:25:31
    about 0.5 cylinders per watt which is
  • 00:25:34
    very very low
  • 00:25:35
    okay so this resistance is very low
  • 00:25:37
    sometimes we ignore it
  • 00:25:38
    if we made consider the thermal
  • 00:25:44
    greasing or or or sheet
  • 00:25:47
    okay maximum junction to case now we
  • 00:25:49
    have junction to case this one
  • 00:25:52
    this one is considered also alone if you
  • 00:25:55
    are considering a heat
  • 00:25:56
    um sink later on and that one is one
  • 00:26:00
    silicon cylinders per watt okay so the
  • 00:26:03
    the other two here are considering if i
  • 00:26:06
    want to use
  • 00:26:07
    the uh the heatsink okay or the first
  • 00:26:10
    one no
  • 00:26:11
    it just goes to the ambient uh
  • 00:26:14
    directly what about the heatsink the
  • 00:26:16
    heatsink
  • 00:26:18
    thermal resistant that one is brought
  • 00:26:21
    from the
  • 00:26:24
    data sheet of the heatsink itself so we
  • 00:26:27
    don't
  • 00:26:28
    we don't actually get it from the data
  • 00:26:30
    sheet of the mosfet and here is another
  • 00:26:32
    example which is
  • 00:26:33
    bgt transistor bd139
  • 00:26:37
    and we have now thermal resistance from
  • 00:26:39
    junction to case
  • 00:26:40
    junction to case this is the resistance
  • 00:26:43
    uh
  • 00:26:44
    value which is 10 series per watt and it
  • 00:26:47
    gives us the resistance between junction
  • 00:26:49
    to ambient
  • 00:26:50
    anything junction to ambient doesn't
  • 00:26:52
    consider the
  • 00:26:53
    uh heatsink so junction to ambient this
  • 00:26:56
    one and that one
  • 00:26:58
    is a hundred okay so now you can really
  • 00:27:01
    calculate the junction or to k
  • 00:27:05
    the case to the ambient as 90 why
  • 00:27:08
    because the junction to the case
  • 00:27:10
    is 10 and junction to ambient is 100
  • 00:27:14
    so the case to ambient should be 90 and
  • 00:27:17
    that
  • 00:27:18
    reveals that it's very very high that's
  • 00:27:20
    why we usually ignore it
  • 00:27:22
    but again you have to consider this
  • 00:27:24
    value if you are
  • 00:27:25
    using a heatsink and you have to
  • 00:27:27
    consider this value if you are not using
  • 00:27:29
    the heatsink
  • 00:27:31
    and another a third example we have this
  • 00:27:34
    mosfet as well and that mosfet has
  • 00:27:37
    three packages this is the first package
  • 00:27:41
    which is to263 or d-square pack
  • 00:27:44
    this is the second package which is 220
  • 00:27:47
    this is the shape of the package it's
  • 00:27:49
    it's uh this is the name of that shape
  • 00:27:52
    and we have a third package which is
  • 00:27:54
    t0247
  • 00:27:55
    what's the point here the point is the
  • 00:27:57
    data sheet is giving us different
  • 00:28:00
    thermal resistance for each package and
  • 00:28:02
    you have to consider
  • 00:28:04
    not just the mosfet itself you have to
  • 00:28:05
    consider also what package
  • 00:28:07
    you will get uh from the manufacturer
  • 00:28:10
    okay
  • 00:28:10
    so for example let's see the first one
  • 00:28:12
    thermal resistance
  • 00:28:14
    junction to case okay so from the
  • 00:28:17
    junction to the case
  • 00:28:19
    junction to the case junction to the
  • 00:28:21
    case okay
  • 00:28:22
    it's the same for all three because it's
  • 00:28:24
    very obvious that the structure is the
  • 00:28:26
    same
  • 00:28:27
    and the case may be the case uh is
  • 00:28:30
    optimized to also to deliver
  • 00:28:32
    the the the same resistance okay
  • 00:28:35
    between the junction and that case so
  • 00:28:38
    the value
  • 00:28:39
    of that resistance is 0.83
  • 00:28:42
    now look at the second one it's
  • 00:28:44
    resistance
  • 00:28:45
    junction to the bcb this is a new one
  • 00:28:49
    but it gives us just value for the first
  • 00:28:51
    package
  • 00:28:52
    not the second and the third why because
  • 00:28:55
    the first package
  • 00:28:56
    is considered to be soldered on the pcb
  • 00:28:59
    itself
  • 00:29:00
    and the pcb will be like like a heat
  • 00:29:03
    sink okay
  • 00:29:04
    so that's why it's like a smd
  • 00:29:08
    component and will be sorted on the
  • 00:29:10
    surface of that
  • 00:29:11
    pcb and it says here the junction to the
  • 00:29:14
    pcb
  • 00:29:15
    junction to the pcb through the case it
  • 00:29:18
    will be
  • 00:29:19
    30 okay and you have to maybe calculate
  • 00:29:22
    also the thermal resistance
  • 00:29:24
    of that pcb by some other ways
  • 00:29:27
    to get the final temperature flow
  • 00:29:30
    okay but we will not consider this now
  • 00:29:33
    we will consider that junction to
  • 00:29:34
    ambient
  • 00:29:35
    look at that junction to emit so if we
  • 00:29:37
    are going to the ambient that means we
  • 00:29:39
    are not considering heatsink
  • 00:29:40
    so from junction to the case to the
  • 00:29:43
    ambien directly without heat sink okay
  • 00:29:45
    and those two we have 62.5 for this one
  • 00:29:50
    and we have 50 which is lower for this
  • 00:29:52
    one
  • 00:29:53
    lower is bitter okay and that's that's
  • 00:29:56
    obvious because this one is bigger that
  • 00:29:57
    means bigger surface
  • 00:29:59
    more radiation and maybe it's optimized
  • 00:30:02
    more for for uh for dissipating that
  • 00:30:05
    heat okay
  • 00:30:07
    so i want just to highlight some
  • 00:30:09
    differences between data sheets and how
  • 00:30:11
    we read
  • 00:30:12
    these values from these data sheets and
  • 00:30:14
    finally is the heatsink and if you
  • 00:30:16
    consider hitting in your design
  • 00:30:18
    i think you will find various shapes
  • 00:30:20
    ratings and different
  • 00:30:23
    series among the manufacturers
  • 00:30:26
    and to be honest we can't actually bring
  • 00:30:28
    them all in one slide
  • 00:30:30
    but maybe some of them are very popular
  • 00:30:33
    like the e-series
  • 00:30:34
    okay where you have to fit the
  • 00:30:38
    to220 mosfet here and by some bolt and
  • 00:30:41
    also you can
  • 00:30:42
    grease it and then you consider it as a
  • 00:30:45
    heatsink for your mosfet
  • 00:30:47
    we have different shapes i will not
  • 00:30:48
    actually talk about them because
  • 00:30:50
    the everyone has has has its own um
  • 00:30:53
    pros and cons and uh we really it's not
  • 00:30:56
    it's not it's not an easy topic to cover
  • 00:30:59
    so we will consider one example which is
  • 00:31:01
    the e-series and that one if you look at
  • 00:31:04
    the
  • 00:31:04
    data sheet for one of them okay it will
  • 00:31:08
    it will tell you what is the thermal
  • 00:31:10
    resistance to be
  • 00:31:12
    to be considered a new calculation and
  • 00:31:14
    the thermal resistance here
  • 00:31:16
    for the first one it has different types
  • 00:31:19
    and different sizes as well
  • 00:31:21
    okay and they bring them here for us
  • 00:31:24
    okay
  • 00:31:25
    so the first one is different from the
  • 00:31:27
    second and the third series
  • 00:31:28
    is by the size height okay and the v
  • 00:31:32
    and a we have t okay we have v and the
  • 00:31:35
    v and the v and a it means the finish
  • 00:31:38
    the
  • 00:31:38
    the surface finish and if it's grease or
  • 00:31:41
    not grease or
  • 00:31:42
    other things okay but forget this we
  • 00:31:45
    are focusing now on the thermal
  • 00:31:46
    resistance for the first one it's about
  • 00:31:49
    11.4
  • 00:31:51
    okay and the second is 9.5
  • 00:31:54
    9 7.5 7.4 6.2
  • 00:31:58
    and those thermal resistances
  • 00:32:02
    have been calculated if the power
  • 00:32:05
    dissipated
  • 00:32:06
    is about 10 watt okay so
  • 00:32:09
    these values are specified at the tin
  • 00:32:12
    watt for example
  • 00:32:13
    but if i'm not considering tin what will
  • 00:32:16
    i find something that helped me
  • 00:32:17
    the specified thermal resistance for
  • 00:32:20
    that
  • 00:32:21
    uh participation which is different from
  • 00:32:23
    tinua and there is something here called
  • 00:32:26
    natural conviction what the meaning of
  • 00:32:29
    that
  • 00:32:29
    if you have gone to this heatsink data
  • 00:32:33
    sheet you will find something like this
  • 00:32:35
    and this is very common between the
  • 00:32:36
    heatsink
  • 00:32:37
    you have four axes two horizontal and
  • 00:32:41
    two vertical
  • 00:32:43
    the left side with the bottom side axis
  • 00:32:46
    that one and that one they are two
  • 00:32:48
    together and you might find these arrows
  • 00:32:50
    here that means
  • 00:32:51
    these three curves here okay are
  • 00:32:55
    read by this co this axis and that axis
  • 00:32:58
    okay and those three are considered if
  • 00:33:01
    you are considering natural cooling
  • 00:33:03
    what we mean by natural cooling that
  • 00:33:05
    means we don't use a fan
  • 00:33:07
    or any other cooling element okay so
  • 00:33:10
    it's just the heat sink
  • 00:33:11
    uh with contact to the natural ambient
  • 00:33:15
    okay
  • 00:33:15
    so that's why it's called natural
  • 00:33:17
    cooling and if we want to read
  • 00:33:19
    the natural cooling case we have to
  • 00:33:21
    consider these curves
  • 00:33:23
    and these axes for example
  • 00:33:27
    if i have 5 watt and i'm using
  • 00:33:30
    the second heat sink second heat sink
  • 00:33:34
    means the
  • 00:33:35
    middle curve and five word dissipation
  • 00:33:38
    means here if you gone like that and
  • 00:33:42
    there
  • 00:33:42
    you will find 40 40 watt it's
  • 00:33:45
    40 a degree difference
  • 00:33:49
    from uh from the ambient okay so the
  • 00:33:52
    temperature rise will be
  • 00:33:54
    40 and if you divide 40 by five
  • 00:33:57
    you will come up with eight it uh
  • 00:34:00
    silly zeus where what this is the value
  • 00:34:03
    of your resistance
  • 00:34:05
    uh or thermal resistance okay
  • 00:34:08
    now if you have more or less power
  • 00:34:11
    dissipation
  • 00:34:12
    you can also calculate that um in a
  • 00:34:14
    similar way
  • 00:34:16
    but if we have a fan or we want to use a
  • 00:34:20
    fan and we want to know if the thermal
  • 00:34:22
    resistance is different
  • 00:34:23
    we can consider the other three curves
  • 00:34:26
    here okay
  • 00:34:27
    this three here can be read by the right
  • 00:34:30
    axis this one
  • 00:34:31
    and the top x is that one the tube axis
  • 00:34:34
    is that
  • 00:34:34
    air velocity if you have a fan you can
  • 00:34:37
    sit it on some velocity
  • 00:34:39
    and you can use some sensors to see
  • 00:34:43
    what is the air velocity for example if
  • 00:34:45
    i have 500
  • 00:34:47
    feet per minute okay that 500 will go to
  • 00:34:50
    the same heatsink which is the middle
  • 00:34:52
    one
  • 00:34:53
    and then this one okay and go to the
  • 00:34:55
    right
  • 00:34:56
    and i find the value of the heat of the
  • 00:34:59
    thermal resistance
  • 00:35:00
    is four it was before eight without a
  • 00:35:03
    fan and now it's
  • 00:35:04
    four with a fan that means my fan
  • 00:35:07
    reduces the thermal resistance
  • 00:35:09
    and makes the heat sink dissipate and
  • 00:35:12
    makes the
  • 00:35:13
    transistor uh see the heatsink as
  • 00:35:17
    easy source easy sink for its
  • 00:35:19
    temperature and that will dissipate
  • 00:35:21
    more heat okay so these are very very
  • 00:35:24
    important to consider
  • 00:35:25
    if you are looking for heatsinks and
  • 00:35:28
    finally just a quick information about
  • 00:35:30
    the
  • 00:35:31
    heatsink sometimes you might consider
  • 00:35:33
    more
  • 00:35:34
    fins for the heatsink means more
  • 00:35:36
    radiation
  • 00:35:37
    and less thermal resistance which is not
  • 00:35:40
    actually
  • 00:35:41
    accurate because this figure now
  • 00:35:44
    shows to us uh the inside thin spacing
  • 00:35:48
    so if i have
  • 00:35:49
    many fins and they are very very close
  • 00:35:52
    to each other
  • 00:35:53
    the uh the thermal resistance start to
  • 00:35:56
    increase
  • 00:35:57
    by decreasing the distance uh of of
  • 00:36:00
    these fins okay
  • 00:36:01
    that increase increasing and that's due
  • 00:36:03
    to that closer proximity
  • 00:36:05
    of adjacent fence and uh there is no
  • 00:36:07
    flow or proper flow
  • 00:36:09
    will go between these fins and if you
  • 00:36:12
    start
  • 00:36:12
    increasing the distance between these
  • 00:36:14
    fins you will
  • 00:36:16
    bring the uh the the thermal resistance
  • 00:36:19
    to an optimum value but
  • 00:36:21
    more increasing you will end up with
  • 00:36:24
    less surface because if you're rid of
  • 00:36:26
    that one and rid of that one
  • 00:36:28
    and you have two uh
  • 00:36:31
    good spacing or highly spaced space fans
  • 00:36:35
    you will reduce the
  • 00:36:38
    surface that's exposed to the air and
  • 00:36:41
    this
  • 00:36:41
    is changing the heat with it so this is
  • 00:36:44
    the point of this figure it's not your
  • 00:36:45
    job to
  • 00:36:46
    look at the spacing for the fence but
  • 00:36:50
    maybe it's just a correction of some
  • 00:36:52
    concepts here okay and the
  • 00:36:54
    optimization of any heatsink is done by
  • 00:36:56
    the manufacturer
  • 00:36:58
    and also they finally bring to you the
  • 00:37:01
    curves that we have seen in the previous
  • 00:37:03
    slide to decide what is the thermal
  • 00:37:05
    resistance
  • 00:37:06
    for any power dissipation or uh for any
  • 00:37:09
    air velocity
  • 00:37:10
    and that brings me to the end of this
  • 00:37:12
    slide
  • 00:37:13
    uh before covering some examples next
  • 00:37:16
    time in the next video
  • 00:37:17
    uh for how we use that electrical model
  • 00:37:20
    to
  • 00:37:20
    calculate the junction temperature and
  • 00:37:22
    case temperature or any other things or
  • 00:37:25
    use it for the design as well and to
  • 00:37:27
    decide whether we need heatsink or a fan
  • 00:37:30
    or no so see you in the coming video
  • 00:37:33
    thank you
ć‚æ悰
  • Power Electronics
  • Thermal Consideration
  • MOSFET
  • Heat Dissipation
  • Thermal Resistance
  • Junction Temperature
  • Derating
  • Heatsink
  • Electrical Model
  • Cooling Design