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jakabus
20-11-2010, 11:53 PM
Ever since i started doing this job I'e been told that pressure and temperature go hand in hand, pressure goes up so does temp and same thing for loosing heat. I am going to tafe now and im getting taught something differant. There can only be two pressures in the system at any given time regardless of the temp.

For argument sake we will say the system is running on R134a, give 10K subcooling and 10K superheat leaving evap and 12K superheat leaving comp. LP 241kpa and HP 977kpa

Therefore our condensing temp is 42*C and evap would be 4*C
dischage line is 42*C + 12K = 54*C BUT pressure is STILL 977kpa. why wouldnt it be 1370kpa???
AGAIN
liquid line is 42*C - 10K = 32*C while pressure remains at 977kpa???

On the other side
suction line is 4*C + 10K = 14*C / 241kpa instead of 379kpa

discharge 54*C 977kpa
condenser 42*C 977kpa
liquid line 32*C 977kpa
evaporator 4*C 241kpa
suction 14*C 241kpa

I can't see how that works out... can anyone explain it better then my teacher?

DTLarca
21-11-2010, 12:00 AM
Ever since i started doing this job I'e been told that pressure and temperature go hand in hand, pressure goes up so does temp and same thing for loosing heat. I am going to tafe now and im getting taught something differant. There can only be two pressures in the system at any given time regardless of the temp.

For argument sake we will say the system is running on R134a, give 10K subcooling and 10K superheat leaving evap and 12K superheat leaving comp. LP 241kpa and HP 977kpa

Therefore our condensing temp is 42*C and evap would be 4*C
dischage line is 42*C + 12K = 54*C BUT pressure is STILL 977kpa. why wouldnt it be 1370kpa???
AGAIN
liquid line is 42*C - 10K = 32*C while pressure remains at 977kpa???

On the other side
suction line is 4*C + 10K = 14*C / 241kpa instead of 379kpa

discharge 54*C 977kpa
condenser 42*C 977kpa
liquid line 32*C 977kpa
evaporator 4*C 241kpa
suction 14*C 241kpa

I can't see how that works out... can anyone explain it better then my teacher?

Saturated temperature varies with pressure and visa verse.

Subcool is how much cooler the liquid is than saturated and superheated is how far warmer the vapour is than saturated.

It is not easy to have subcooling in the presence of vapour and it is not easy to have superheat in the presence of liquid but both are possible under particular conditions in close proximity to saturated temperature.

Magoo
21-11-2010, 01:27 AM
Air or non condensibles in a system can screw up the pressure temperature theory.

cool runings
21-11-2010, 02:40 AM
Ever since i started doing this job I'e been told that pressure and temperature go hand in hand, pressure goes up so does temp and same thing for loosing heat. I am going to tafe now and im getting taught something differant. There can only be two pressures in the system at any given time regardless of the temp.

For argument sake we will say the system is running on R134a, give 10K subcooling and 10K superheat leaving evap and 12K superheat leaving comp. LP 241kpa and HP 977kpa

Therefore our condensing temp is 42*C and evap would be 4*C
dischage line is 42*C + 12K = 54*C BUT pressure is STILL 977kpa. why wouldnt it be 1370kpa???
AGAIN
liquid line is 42*C - 10K = 32*C while pressure remains at 977kpa???

On the other side
suction line is 4*C + 10K = 14*C / 241kpa instead of 379kpa

discharge 54*C 977kpa
condenser 42*C 977kpa
liquid line 32*C 977kpa
evaporator 4*C 241kpa
suction 14*C 241kpa

I can't see how that works out... can anyone explain it better then my teacher?


I think you are confusing temperature and the boiling temp (or condensing temp) known as saturation temperature.

Pressure and temp are related but the temp in question is the saturation temp (boiling or condensing).

So if a liquid is colder than the condensing temp then the liquid must be sub cooled.

If the vapour is hotter than the evaporation temp then it must be superheated.

All the best

coolrunnings

.

Peter_1
21-11-2010, 10:00 AM
Good you question this as a young tech

I will try to explain it to you with water.
Have you ever seen a log p/h?
This is the log p/h of waterhttp://farm3.static.flickr.com/2092/2340753221_e09a487155_d.jpg
The same exists for all refrigerants and it has +/- the same size, only the numbers differ.

Then you know that the bubble in that diagram is the transition from liquid (left side of the bubble) to gas (right side of the bubble) of a refrigerant, water in this diagram.

If you look at the right vertical axis side and you take 1 bar absolute or atmospheric pressure, then you will notice on the left side of the bubble 100°C (red numbers)
Water start to boil at 100°C and has a heat content of 417 kJ/kg of water (horizontal lower axis)
You further add heat to the water and the water always boils more and further until you have added 2257 kJ/kg water. But.. the temperature remains the same.
Then, after adding 2257 kJ/kg heat, all the water is vaporized at the same pressure of 1 bar and same temperature of 100°C. But you changed the water from liquid state to vapor state. So changing state happens always at the same pressure and temperature but at a different heat content.

To understand your problem: we go back to the left side of the bubble where the water of 100°C just came from 99.9999°C and started to boil.
We cool the water down now along the 1 bar pressure line, so going horizontal to the left. The energy content decreases (the water becomes colder) but we don't have a phase change state now. So we subcool the water from 100°C to 95°C, 90°C always further down but at the same atmospheric pressure of 1 bar. The relation between temperature and pressure is gone now, same pressure, different temperature. It's gone because you don't have a phase change now.
So, the relation of the temperature with the pressure is only valid within the bubble. Or it is only valid when the liquid changes from 100% liquid to 100% vapor. Reducing heat content of a 100% liquid will subcool the liquid and once all vaporized, you then superheat the vapor when further adding heat.
Or compared with water: water always boils at 100°C when pressure is at 1 bar and water boils at (+/-) 85 °C on the Mont Blanc where pressure is +/- 0.6 bar and it boils in an old household steamer at 120°C when pressure is at 2 bar in the casserole.
http://www.comparestoreprices.co.uk/images/to/tower-aluminium-speed-7-pressure-cooker.jpg

Same for refrigerants, relation is only valid when the refrigerant is on its boiling phase, at the beginning of it till the end and where only the heat content of the refrigerant changes.

Hopes this clarified a little bit your big question marks in your head.

Tayters
22-11-2010, 01:27 AM
So you've got the 2 pressures in your system. At those pressures the refrigerant will be at the point of turning from liquid to gas (evaporator) or gas to liquid (condensor). Those are called the saturation points amongst other names.
Anything above or below this will enter into superheated gas or subcooled liquid territory.

In your example:

Therefore our condensing temp is 42*C and evap would be 4*C
dischage line is 42*C + 12K = 54*C BUT pressure is STILL 977kpa. why wouldnt it be 1370kpa???
Because the pressure in the high side is 977kPa, R134a condenses at 42*C. Leaving the compressor it's a gas superheated 12K

AGAIN
liquid line is 42*C - 10K = 32*C while pressure remains at 977kpa???
Same again. R134a condenses at 42*C then gets cooled 10K. The saturation temp remains the same.
It's pressure wouldn't get lower. It stays the same and the liquid becomes subcooled.

On the other side
suction line is 4*C + 10K = 14*C / 241kpa instead of 379kpa
R134a is boiling at 4*C. In the evaporator it's changing state (latent heat) at 4*C. Heat it until it's 14*C and it's now superheated gas by 10K.


Like Peter says you can boil water at home at 100*C. Give it more heat and it still boils at 100*C. Depends on the pressure and in your kitchen it wont alter so neither will the boiling (or condensing) point.
Pour 10*C water out the tap, it's subcooled by 90K at atmospheric pressure. There's an example of a liquid and the same pressure but a different temperature.

Hope that helps,

Andy.

jakabus
26-11-2010, 07:47 AM
thanks guys, you all helpped out heaps... wish i looked at an enthalpy chart before i asked the question but >.> I know know, cheers!

Magoo
27-11-2010, 03:45 AM
Hi jakadus.
so what was the problem and how did you resolve it. magoo

chilliwilly
28-11-2010, 01:08 AM
So you've got the 2 pressures in your system. At those pressures the refrigerant will be at the point of turning from liquid to gas (evaporator) or gas to liquid (condensor). Those are called the saturation points amongst other names.
Anything above or below this will enter into superheated gas or subcooled liquid territory.

In your example:

Therefore our condensing temp is 42*C and evap would be 4*C
dischage line is 42*C + 12K = 54*C BUT pressure is STILL 977kpa. why wouldnt it be 1370kpa???
Because the pressure in the high side is 977kPa, R134a condenses at 42*C. Leaving the compressor it's a gas superheated 12K

AGAIN
liquid line is 42*C - 10K = 32*C while pressure remains at 977kpa???
Same again. R134a condenses at 42*C then gets cooled 10K. The saturation temp remains the same.
It's pressure wouldn't get lower. It stays the same and the liquid becomes subcooled.

On the other side
suction line is 4*C + 10K = 14*C / 241kpa instead of 379kpa
R134a is boiling at 4*C. In the evaporator it's changing state (latent heat) at 4*C. Heat it until it's 14*C and it's now superheated gas by 10K.


Like Peter says you can boil water at home at 100*C. Give it more heat and it still boils at 100*C. Depends on the pressure and in your kitchen it wont alter so neither will the boiling (or condensing) point.
Pour 10*C water out the tap, it's subcooled by 90K at atmospheric pressure. There's an example of a liquid and the same pressure but a different temperature.

Hope that helps,

Andy.

Very well put.

Tayters
28-11-2010, 01:32 AM
Spank your hairy crutch! :D

chilliwilly
28-11-2010, 03:06 PM
Fairy fluff, carry your bag for you someday sir!

jakabus
28-04-2011, 11:58 AM
Hi Magoo,

After peter was talking about an anthelpy chart for water I realised my error. At first i didn't even consider the state of the substance (refrigerant or water) and a PT chart reads in the saturation temp. it doesn't cover all three states.

Fri3Oil System
28-04-2011, 12:42 PM
Great lesson chaps! thanks!!