1 Cleaning, Vacuum & Refrigerant Charge Procedures.

1

Cleaning, Vacuum & Cleaning, Vacuum & Refrigerant Charge Refrigerant Charge ProceduresProcedures

2

Monitoring Operative ParametersMonitoring Operative Parameters

Suction pressure at the compressor

Discharge pressureat the compressor

Suction temperature at the compressor (total superheat);

Suction temperatureat the evaporator outlet(evaporator superheat)

Liquid temperatureat the expansion valve inlet(liquid subcooling)

Discharge temperatureat the compressor

EVAPORATOR

CONDENSER

3

Basic InstrumentationBasic Instrumentation

A Vacuum Pump that removes moisture and non-condensable gases after the system has been opened for maintenance and repair.

Refrigeration Storage Tankwith two connection ports to enable charging of liquid and extraction of vapour simultaneously

Recovery Unit with oil-free compressor and pressure manometers

A Digital Weighing Platform used to avoid overfilling the Recovery Cylinder and ensuring that the exact amount of refrigerant charged into the system can be logged. This aids monitoring of consumption and leakage.

Manifold with pressure and suction gauges and connection hoses. This gives a full overview of system performance and visually monitoring the system during refrigerant recharging.

A Vacuum Gaugeused to determine if proper vacuum has been obtained. It will also help indicate if the system is not leak-tight. An Electronic Leak Detector

can detect up to 5 ppm and features a six-segment visual leak size indicator and a variable frequency audible alarm.

A basic refrigerant recovery equipment is required:

4

Cleaning the Refrigerant CircuitCleaning the Refrigerant Circuit

1) The circuit must be flushed with nitrogen in order to remove oil residues and other impurities.

2) Close the rotalocks connections.

3) Remove the filter drier and let both the low and high pressure sides opened.

4) Start flushing both sided with nitrogen at least 3 times.

NITROGEN

REMOVENITROGEN

5

Visible Moisture• Water Droplets (uncommon, but it can occur)

Invisible Moisture•Water Vapor (found in all gases and solids)• Air in the piping• “Wet” Refrigerant• Leaks Under a Vacuum Condition• Copper and Brass Components• System components exposed to atmosphere during assembly

Moisture in Refrigeration SystemsMoisture in Refrigeration Systems

6

Moisture in Refrigeration SystemsMoisture in Refrigeration Systems

Visible Moisture ProblemsFREEZEOBSTRUCTS THE PROPER FUNCTIONING OF THE COMPRESSOR

AND THE REFRIGERATION SYSTEMICE CRYSTAL FORMATION AT THE POINT OF EXPANSIONCAP TUBE BLOCKEDEXPANSION VALVE

Invisible Moisture ProblemsMOISTURE + METALS = CORROSIONMOISTURE + REFRIGERANT = ACID•CFC & HCFC & HFC: Hydrolyze to form Hydrochloric Acid or Hydrofluoric Acid•Acid formation is accelerated by heat•Copper and brass will be attacked (hot surfaces and bearings)MOISTURE + REFRIGERANT + OIL = SLUDGEREDUCE SERVICE LIFE AND INCREASE CONDENSING PRESSUREHIGH DISCHARGE PRESSURE AND TEMPERATUREMECHANICAL AND ELECTRICAL COMPRESSOR FAILURE

7

VacuumVacuum

How can we get the water out?

We must boil itWe can’t raise the system temperature to 100 °C.We can lower the system pressure to a point that water boils at ambient temperatures (vacuum )

Absolute pressure

Positive pressure

Negative pressure(vacuum)

Zero absolute pressure

Atmospheric pressure

(0 barg or 1.013 bara)

Measured pressure

Absolute vacuum

Differential pressure

8

Basic Physics:

AS PRESSURE DECREASES, THE BOILING POINT DECREASES

1.013 bara

100 °C

0.98 bara

26 °C

VacuumVacuum

9

Vacuum PumpVacuum Pump

Two stage rotary vacuum pumpsmost common for service;larger cubic meter per minute capacity;slightly heavier than single stage of same capacity;can achieve deeper vacuum than single stage because second stage takes over at the level first stage stops;can pull to one micron of Mercury vacuum.

1st stage

2nd stage

10

Vacuum ProcedureVacuum Procedure

1) First of all, the compressor must be isolated from the system. It is essential to connect the vacuum pump to both the LP & HP side in order to avoid dead-ending parts of the system.

2) Pull down the refrigeration circuit under a vacuum of:R407C, R410A 0.1 mbar (10 Pa, 0.075 Torr)R22 1 mbar (100 Pa, 0.75 Torr)

(A) Low-pressure gauge (B) High-pressure gauge(C) Slowly open(D) Vacuum pump turn on

11

Vacuum ProcedureVacuum Procedure

3) When the correct vacuum level is reached, the circuit must be isolated from the pump. 4) Wait at least for 30 minutes. 5) If the pressure rapidly increases, then the circuit is not leak tight. Locate and repair leaks.

Restart from step 1). If the pressure slowly increases, then the circuit contains moisture. Break the vacuum with nitrogen gas and repeat steps 1), 2), 3).

The vacuum level should be reached and maintained for at least 4 hours (it depends on the length and size of the circuit): it will guarantee that the circuit is both tight and fully dehydrated.

Leakage

Moisture

Tight & dry

Time [min]

Pre

ssu

re [

bar

, Pa,

To

rr]

Vacuum level

12

Refrigerant ChargeRefrigerant Charge

Zeotropic refrigerant mixtures (i.e. not defined by a single pressure-temperature relationship) such as R407C must always be charged in liquid phase. For the initial charge, the compressor must be stopped and service valves must be closed.

Charge refrigerant as close to the nominal system charge as possible before starting the compressor; then, slowly add refrigerant in liquid phase on the low-pressure side, as far away as possible from the running compressor.

Connections size for R22-R407C-R410A: 1/4“

13

The refrigerant ruler is used to calculate the pressure and temperature of refrigerants.

Set the cursor on the refrigerant pressure and read off the corresponding temperature. The values are shown in metric and US units.

Refrigerant RulerRefrigerant Ruler

14

Subcooling is defined as the difference between the refrigerant liquid temperature and its saturation temperature. It can be used to check the correct refrigerant charge.Subcooling can be measured by:

1)placing a thermometer on the expansion valve inlet, reading the liquid temperature Tliq.2)placing a pressure gauge on the inlet (or outlet) of the condenser coil, reading the condensing pressure pcond. This pressure is strictly linked to the saturation temperature of the refrigerant Tsat cond (bubble point temperature if zeotropic mixtures, like R407C).

Thermometer Tliq

Pressure gauge pcond

Tsat cond

Tsat cond – Tliq = SBC ≈ 5 – 10 °C

SubcoolingSubcooling

15

Superheat is defined as the difference between the refrigerant vapor temperature and its saturation temperature. It can be used to monitor the functioning of the expansion valve.Superheat can be measured by:

1)placing a thermometer on the evaporator outlet, reading the vapor temperature Tvap.2)placing a pressure gauge on the evaporator outlet, reading the evaporating pressure pevap. This pressure is strictly linked to the saturation temperature of the refrigerant Tsat evap (dew point temperature if zeotropic mixture, as R407C).

Tasp ThermometerTsat evap

Tasp – Tsat evap = SPH ≈ 5 °C

SuperheatSuperheat

pevap Pressure gauge

16

Subcooling & Superheat for R22Subcooling & Superheat for R22

17

Subcooling & Superheat for R407CSubcooling & Superheat for R407C

18

Pump Down ProcedurePump Down Procedure

The term means the operation by which all the refrigerant inside the circuit is pumped on the high pressure side (i.e. on the condenser side), making it possible both to operate on the low pressure side and to recover the major amount of refrigerant.

When a leak is detected or a compressor replacement is required, it could be useful to perform a “pump down” procedure.

19


1) Close the shut off valve placed after the liquid receiver at the output of the condenser coil.

2) Let the compressor run until the low-pressure manometer goes down to 0.5-1 bar; the lower is this pressure, the minimum is the refrigerant loss.

ON CLOSED

0.5-1.0 bar

20


3) Switch the main circuit breaker off.

4) Close the rotalock on the discharge side of the compressor; if the compressor miss rotalocks, close the shut off valve on the high pressure side.

OFF CLOSED

21

Removing Liquid RefrigerantRemoving Liquid Refrigerant

5) Remove the refrigerant from the HP side of the system through any connection or valve located on the liquid line by using a refrigerant recovery unit and storage tanks.

6) Make a note of the weight of refrigerant mass reclaimed.

OFF

22

Refrigerant Charge OverviewRefrigerant Charge Overview

R22 R407C – R410A

1Open any shut-off valves present in the machine to ensure that all of the components will be evacuated;

2Connect a pump to empty the schrader connections efficiently, or to the 1/4" SAE connections present on the intake and delivery sides of the compressors;

3 Connect the refrigerant cylinder to the loading connections;

4

Create a vacuum within the lines while maintaining the pressure below 100 Pa absolute (0,7 mm Hg) for a long time in order to evacuate the air as well as any traces of humidity. It is preferable that the vacuum is reached slowly and maintained for a long period of time;

Create a vacuum within the lines whilst maintaining the pressure below 10 Pa absolute (0,07 mm Hg) for a long time in order to evacuate the air as well as any trace of humidity. It is preferable that the vacuum is reached slowly and maintained for a long period of time;

5

Wait for a build up period of 100 seconds and check that the pressure has not exceeded 200 Pa absolute. Generally, in the case of suspicion of strong hydration of the circuit or an extremely extensive system, it will be necessary to break the vacuum with anhydrous nitrogen and then repeat the evacuation procedure as described;

6Break the vacuum by performing a preload from the R22 coolant cylinder;

Break the vacuum by performing a preload in liquid phase from the R407C or R410A coolant cylinder;

23

Refrigerant Charge OverviewRefrigerant Charge Overview

R22 R407C – R410A

7After having started the compressor, slowly complete the loading phase until the pressure within the lines has been stabilized and the gaseous bubbles have disappeared from the flow sight glass;

8

The loading process must be controlled in environmental conditions with a delivery pressure of approximately 18 bar (equivalent to a saturated temperature of 48°C); in the case of units with ON/OFF condensation controls, avoid switching the condenser fan on and off, which may partially obstruct the intake surface. It is wise to check that the sub-cooling of the liquid at the entry of the thermostatic valve is between 3 and 5°C below the condensation temperature read on the scale of the pressure gauge and that the overheating of the vapour at the exit of the evaporator is equal to 5-8°C.

The loading process must be controlled in environmental conditions with a delivery pressure of approximately 18 bar (equivalent to a dew temperature of 48 °C and a bubble temperature of 43°C); in the case of units with ON/OFF condensation controls, avoid switching the condenser fan on and off, which may partially obstruct the intake surface. It is wise to check that the sub-cooling of the liquid at the entry of the thermostatic valve is between 3 and 5 °C below the condensation temperature read on the scale of the pressure gauge and that the overheating of the vapour at the exit of the evaporator is equal to 5-8°C.

24

Lubrication & Oil AdjustmentLubrication & Oil Adjustment

Compressor oil drain

• Open the suction port, or the sight glass port (when fitted); • Move the compressor slowly to a horizontal position and recover the oil through the compressor suction connection port, or from the oil sight glass opening. • Note: the large scroll compressor is equipped with an oil drain connection and can therefore be drained of its lubricant in a vertical position. In this case, pressurize the LP side of the compressor (by using dry nitrogen). • Pick an oil sample for analysis if needed (i.e. operational installation). • Before re-installing the compressor, or replacing the sight glass, replace the gaskets by new ones (suction & discharge ports, sight glass gasket). Check the old lubricant for acid content using an acid test kit. • Install a new filter drier. An anti-acid type cartridge has to be used if the acid test is positive. The anti-acid filter drier has to be replaced by a standard cartridge after a few days when the system is acid free.

Oil drain

25


26


It is not required to add oil whenever the refrigerant lines don’t exceed 30 meters.

When the lines exceed 30 meters, and vertical lines are also present, it is advisable to add oil according to the number of siphons along the gas line.

Fill in with water one siphon, pour it in a graduate cup and multiply this quantity for the number of siphons: this is the amount

of oil to add to the system.

OK!NO NO

27


Additional recommendations • After adding oil, allow the compressor to run fully loaded for 20 minutes and re-check the level in the oil sight glass. This level should be between 2/4 and 3/4.

• Be careful not to add more oil than necessary. The following adverse conditions can occur if excessive oil is present:

- Failure of valves and pistons or scroll involutes due to oil slugging.- Excessive carry over of oil loss of evaporator performance due to oil level built-up in the low side of the system.

1 Cleaning, Vacuum & Refrigerant Charge Procedures.

Documents

Transcript of 1 Cleaning, Vacuum & Refrigerant Charge Procedures.