Thermal cameras aren't that great at accurately measuring temperature particularly when comparing different materials. The emissivity of the metal with be very different to that of the other materials and so a different temperature will be measured.

Infrared cameras measure the temperature by measuring the amount of infrared radiation emitted by a surface. But metal surfaces inherently emit less (it had low emissivity) so the infrared camera reads low. Try putting a temperature sensor (RTD, thermistor or thermocouple) on the metal and it should read 105C. Or put a dab of paint or piece of tape on the metal and aim the IR camera at that.

Yeah, as previously said, you should put tape or paint on the metallic surface to measure its temperature with your thermal camera.
In my engineering school we did an experiment to measure the emissivity of different type of surfaces .

We could see that without entering the emissivity values, the IR camera would show 64°c for a polished metal plate even if the real temperature (measured with a thermo-couple sticked to the surface) was 74°c .

Hot air cannot cool something that's at a lower temperature. Convective heat transfer can only occur when the object and the air flowing around it are at different temperatures. And heat will always flow from the hot thing to the cold thing. It will never flow the other direction. Also you should use a thermocouple for this, it will be more accurate. Just gotta make sure you dont short out the pcb with the metal thermocouple tho.

>I was talking to a coworker and he said that the hot air in the chamber was cooling the part because it was flowing.

This can be true only for a part that's perspiring.

Reflectivity. The metal housing is reflecting the cooler temperatures behind the thermal camera and including it in the imaging.

Relatable similar occurance: I was working on an offshore oil platform once using a thermal gun to try to identify a leaking valve and found out pretty quickly that the polished steel gasket between the valve and pipe would reflect the temperature of open sky. I thought I found a leak when the gun registered a chilly 32F but was actually at like 100F on contact.

That shouldn't be true unless there's something being evaporated from the surface, in which case flowing air might speed evaporative cooling. By itself, there's no way for warm air to cool an object to below its own temperature.

As others have said, the metal part isn't cooler - it's an artifact of the thermal camera.

It comes down to emissivity, and reflections.

A "thermal camera" or "(non-contact) IR thermometer" measures the radiated heat (long-wavelength thermal energy) emitted by the object you're pointing it at.

All objects emit the same spectrum (strictly spectral distribution) of radiation, depending only on their temperature - look up Blackbody radiator and colour-temperature.

The absolute amount of energy ("brightness") also varies strongly with temperature, but depends also on a property of the material, known as its emissivity.

For simplicity, IR cameras typically only measure the strength of emission at one wavelength (usually somewhere around 3-12µm), and determine the temperature by the "brightness" at that wavelength.

For most common matt/dielectric (non-metal) materials, the emissivity is 97-99% - which is the default calibration for an IR thermometer.... but metals, especially polished shiny ones, and especially gold has a lower emissivity, so the IR thermometer will under-read.

You can look up the emissivity for different materials and set the IR thermometer calibration accordingly, to get correct readings ... but be aware that metals can also look like mirrors, and you may "read" the temperature of the thing in the reflection in the metal, rather than the metal itself - or somewhere between the two.

If you wear a metal ring (especially a gold one) on your finger an point the thermal camera at your hand, you'll see the ring is darker (and reads "colder") - even though its true temperature is likely to be close to that of your fingers.

This is something that not enough people know about IR thermometers and IR cameras.

It's a physics thing! :-)

Answer: Your question is a bit of a misnomer in itself and your coworker doesn't seem to understand thermodynamics - The real question is why the center of the oven is warmer than the outsides of the oven, which yes, is partially due to convection (the movement of the fluid in the oven circulating away heat as it travels) and the design of the oven (where latent 'pools' of fluid allow heat to build up), but is mostly due to the fact that the fluid being circulated is AIR which is an insulator due to the nature of the gas composition and it being in gaseous form. Air insulates regardless of its velocity, but as father Bernoulli taught us, the faster it moves under constant pressure, the less entropy is able to pool into measurable heat. For this oven, it makes sense that the outsides would be cooler than the insides, since the whole point of an oven is to concentrate high heat within a container that won't combust. There are other issues at play such as the difference conductivity and radiation constants of different elements, but that's another reason why oven's are constructed with materials that melt far above the safety limits, such as sand/acrylics. You can measure this yourself by going into a temperature controlled environment (read: "in-doors") and touch a wooden surface, then touch a metal surface, noting that the metal surface will always seem cooler to the touch because metal is a poor insulator and will emit heat calories to entropy at a much greater rate than wood, which is carbon-based and has evolved to literally be pockets of air at the molecular level.

If all the air is the same temp, such as in your explanation, air flowing would do the opposite from cooling. The kinetic energy of the flowing air would actually lose kinetic energy to heat stuff up more. Now it is very negligible, but it certainly isn't cooling anything down.

Your coworker is wrong. The thermal camera measures temperature based on the amount of radiation (I) it senses:

I = s e T^4

Where T is temperature in Kelvin, s is a constant (5.67E-8), and e is emissivity, a value between 0 and 1. For most objects, emissivity is between 0.9 and 1, so the camera assumes an emissivity in that range and solves for T using that equation (T = (I/(s e))^1/4 ). However, metals have low emissivity, often in the range of 0.3 or lower!

Thermal cameras see IR, metals, especially bare metals have a really low emissivity, meaning that they radiate very little IR and reflect the rest. (what the camera sees)

Think of it as a mirror, aluminum foil for example has emissivity of under 0.1 (it's a scale of 0-1, 1 being 100% radiating/absorbing) so only 10% of the total possible energy is being radiated and 90% are being reflected.

What you're seeing is a combination of the reflected IR + the radiated IR.

So the surface reflected is likely what you're seeing + the housing.

Take an aluminum foil and literal look at yourself with the camera. Foil is basically a mirror for IR as a glass mirror is for white light (what we see)

Emissivity is affected by material/color/surface. To get a better reading you want to paint it with a black body color, something black with a rough surface and very little visible shine (matte black)

Temperature is one of the most difficult things to measure. For example it is not just to put a thermometer inside an oven an do readings if you want a correct value. But if you are satisfied with an approximate value, this is ok.

materials have different emissivity. Plastic on wire is ~1, metals are way different.

Metals also reflect heat from different sources. You can tell if you're measuring a reflection by moving yourself around and measuring from different angles. reflections will change but the emited ir wont

You need to put a bit of black insulation tape on the metal and use that for temperature. Or use it to work out the emissivity of the metal.

Theres another setting for specular reflectance. You crumple up some tinfoil and take a reading from that for background reflectance

What you are describing is called thermal dynamics. We all know hot air rises, and cool air sinks. As long as the air is moving you have an exchange of energy. As the hot air rises, it creates a vacuum below it that pulls in colder air from below. The cooler air saps energy from the hot parts and gains heat. It then takes the heat and rises with the hot air above creating another vacuum below. That also pulls in fresh new cooler air to surround the hot parts. This continuous movement creates a convection or cycle if you will that keeps air from becoming stagnant. When you have stagnant air the air can only absorb so much heat. Circulating air can absorb more heat away from hot parts do to it being in motion. Thats how fans typically work is to force a convection of cool air to push stagnated hot air out of the way, so cool low energy air can absorb heat energy and travel away from the hot surface.

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The other comments basically reveal that every physical problem we try to understand requires approaching the solution using a mental model with built in assumptions and limitations. So, perhaps when we have a question or face a challenge when something doesn't make sense, it is good to look deep down through our pyramid of assumptions upon which we place our understanding. Unless we solve the problem, then all assumptions are suspect. For example, while others point out the probable main issue here (the metal's emissivity), there are other assumptions. There is the assumption that the metal, the other parts and air should all be at the same temperature. In fact, the problem is a bit complicated when you get into the slight differences. The objects each lose energy at a different rate by emitting (mostly) IR photons at different rates (paramaterized as "emissivity"). Additionally, the objects conduct heat at different rates. Since they all lose heat via IR to the cooler environment outside the chamber (which also irradiates the same parts, but with fewer IR photons), the parts will never purely reach the temperature of the air in the chamber. What equilibrium temperature each one reaches, down to the hundredths of a degree perhaps, depends on how quickly the parts can conductively and radiatively absorb heat compared to how quickly they lose heat via the same processes to the outer environment (via) IR, the inside air (via conduction and IR), and the parts they touch (via conduction) and the parts within line-of-sight (via IR). So, the problem is actually quite complex and only simplified if we don't care about small temperature differences. Plus, if we did care about such small differences, the measuring device would have to be highly accurate.

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Everyone has already mentioned the flaws with the temperature gun so I won't delve into that. Instead I'll explain "wind chill". Temperatures feel colder when there is wind for 2 main reasons.

One of them being evaporation on a wet surface. This is why licking your finger and holding it to the wind helps you tell the wind direction by which side the cold part of your finger is facing. Wind accelerates evaporation which is an endothermic process (absorbs heat).

The second reason is that heat transfered through conduction happens when two molecules bump into each other and exchange their individual kinetic energy. Much like two balls in billiards hitting each other. When a while material is subjected to this the kinetic energy of each molecule is represented as heat. So wind allows more molecules to bump into each other and thus more heat transfer.

Now, it is incredibly important to note that this process of heat transfer through conduction works in a specific way to AVERAGE the temperatures between two materials. So cold air cools and hot hair heats up. Don't believe me? Hold your hand in front of a hair dryer. 😆 Given your material isn't wet evaporation can be dismissed and temperatures will only average. So that means your hot oven is definitely heating any material you throw in it that is at a lesser temperature until they reach a state of equilibrium and the convection (wind) accelerates this process.

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Is the PCB in use or is it off?

The operating temperature of any PCB is going to be higher than it’s environment because the electrical currents create heat through the part. So if you’re measuring 105C at a powered on PCB, then I would argue the chamber itself is not actually 105C, but lower.

When you say the chamber was set to 105C is it regulating the temperature with a thermocouple that is actually measuring the temperature? If so where is that thermocouple? And where is the heat source? Is there one heat source or multiple? Is the chamber being heated by driving heated air through it? Also how insulated is the chamber?

It seems likely that the air in the chamber isn’t actually 105C. This could be for a lot of reasons, like if the chamber isn’t insulated very well or if the heating element is too small or the heat transfer from the element to the air isn’t very efficient or if the feedback loop that targets a temperature setting has a bias from poor temp sensor placement or calibration. Any or all of these things could lead to inaccuracies in the chamber temperature. And it’s very likely that you don’t actually reach thermal equilibrium no matter how much you “soak” if the chamber is losing heat energy, which it almost certainly is.

Think about a 3D printer, the bed temperature is regulated with a thermocouple that is attached to the bed. If you set that to 105C bed temperature, the air in the enclosure is absolutely not going to be 105C no matter how long you soak for. Because the thermal losses from the chamber are too great.

My guess is that this is what’s happening to your chamber. I’d put an old fashioned thermometer in there with no PCB and see how close the air temperature is to the setting after a 30 minute to one hour “soak”

Edit: if you want to tell me more about the chamber (ie answer some of my questions about how it’s heated) I can help get more specific. Also knowing what the chamber exterior is made of would be helpful.

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Your coworker is not correct, unless the item is evaporating a liquid like water or something. If it's completely dry, 105c air is going to bring the object up to 105c whether it's blowing or not, but if it's blowing it will actually be quicker because the cooled air from the object is being removed and replaced by new hot air

Heat cannot of itself pass from one body to a hotter body. If two bodies of different temperatures are in contact then heat will flow from the hotter body to the cooler body until the thermal energy is equalized. This will continue until the universe stops functioning.

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They way I think about it, is that it loses energy density and gains electrons. There’s someone known as Renzo who did plasma electrolysis and synthesized oxygen from sulphur at low current on YouTube. I think that usually we describe this as solely an electron exchange but that the electron configuration can be broken down by photo-disintegration and measured by decay of any atom into helium concentrations. Imagine electron configurations with like 2[He] and think about an electron shell being a cloud of probability with resistance being relative to the radiant energy. Radiant energy is primarily responsible for black holes

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If you are scanning through a port window, it might be a reflectivity issue, like others have stated. Pop-open the chamber door (briefly) and take a scan or cross-check with a quick responding contact thermocouple probe.

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Heat=energy.

How much energy is required to raise the temp of silver is less than steel because one is more conductive than the other. Properties of the material being heated play a role but heat is lost over time. Assuming you are not putting any more energy (heat) into the system.

Barring fans and other means of heat transfer, your answer is flow. Heat flows. The PCB is hot, and the room ambient air is probably around 70F. The casing is heated by the PCB but cooled by the ambient air as the heat flows outward.

This can actually be quite accurately modeled, but I'd probably want a better picture of your solid state system before attempting to do so.