::: Tegnon Jones :::

Model Mp	Airflow rate	nominal absorbed power	maximum absorbed power	Power supply	air connections
	m³/min	kW	kW	V/Ph?hz
5MP0070	0.7	0.15	0.20	230/1/50	1/2"
5MP0120	1.2	0.18	0.32	230/1/50	1/2"
5MP0160	1.6	0.29	0.37	230/1/50	1/2"
5MP0270	2.7	0.39	0.44	230/1/50	3/4"
5MPP0480	4.8	0.55	0.72	230/1/50	1"
5MP0600	6.0	0.82	1.10	230/1/50	1"
5MP0900	9.0	0.84	1.10	230/1/50	1 1/2"
5MP1200	12	1.10	1.60	230/1/50	1 1/2"
5MP1600	16	1.85	3.00	400/3/50	2"
5MP1900	19	2.22	3.60	400/3/50	2"
5MP2400	24	3.16	5.00	400/3.50	2 1/2"
5MP3000	30	3.55	6.00	400/3/50	PN16 DN80
5MP3500	35	4.57	6.90	400/3/50	PN16 DN80
5MP4400	44	6.11	8.20	400/3/50	PN16 DN100

B) Large Capacity Mabellano Range - 22,0 to 190 m³/min

Model MG	Air flow		Dimensions [mm]
Model MG	[m³/h]	[m³/min]	A	B	C	D	E	F	G
MG022/A	1320	22.0	660	1230	1400	315	350	408.5	89
MG028/A	1680	28.0	660	1230	1400	315	350	408.5	89
MG037/A	2220	37.0	660	1230	1400	315	350	408.5	89
MG045/A	2700	45.0	660	1230	1400	315	335	416.0	54.5
MG060/A	3600	60.0	660	1230	1400	315	335	416.0	55
MG077/A	4620	77.0	910	1790	1447	315	365	229.0	120
MG090/A	5400	90.0	910	1790	1447	315	365	229.0	120
MG110/A	6600	110.0	910	1790	1447	315	365	229.0	120
MG150/A	9000	150.0	930	2860	2064	305	390	243.0	111
MG190/A	11400	190.0	930	2860	2064	305	390	243.0	111
MG022/W	1320	22.0	660	1230	1264	315	350	408.5	89
MG028/W	1680	28.0	660	1230	1264	315	350	408.5	89
MG037/W	2220	37.0	660	1230	1264	315	350	408.5	89
MG045/W	2700	45.0	660	1230	1264	315	335	416.0	55
MG060/W	3600	60.0	660	1790	1264	315	335	416.0	55
MG077/W	4620	77.0	910	1790	1310	315	365	229.0	120
MG090/W	5400	90.0	910	1790	1310	315	365	229.0	120
MG110/W	6600	110.0	910	1790	1310	315	365	229.0	120
MG150/W	9000	150.0	930	2860	1927	305	390	243.0	111
MG190/W	11400	190.0	930	2860	1927	305	390	243.0	111

Notes:

Airflow refers to the following conditions FAD 20°C/1 bar, air inlet temp. 35°C, pressure 7 barg, RH 100%, PDP 3°C, ambient temp. 25°C
Approximate data, for different operating conditions use the factors correction table below; please consult the selection software

Working pressure[barg]:

Correction factor:

Air inlet temperature [°C]:

Correction factor:

Ambient temp/cooling fluid [°C]:

Correction factor:

Pressure dew point [°C]:

Correction factor:

3	4	5	6	7	8	9	10	11	12
0.69	0.80	0.88	0.95	1.00	1.05	1.09	1.14	1.17	1.20
30	35	40	45	50	55	60	65
1.26	1.00	0.82	0.67	0.55	0.47	0.45	0.43
20	25	30	35	40	43
1.08	1.00	0.93	0.87	0.80	0.75
3	4	5	6	7	8	9	10
1.00	1.07	1.12	1.18	1.24	1.32	1.38	1.47

All dryers are supplied with R407C refrigerant and for maximum working pressure 12 barg as standard.
maximum ambient temperature 43°C
maximum air inlet temperature 65°C
Power supply:
- 50 Hz version 400V/3Ph/50 Hz.
- 60 Hz version 460V/3Ph/60 Hz
- For 60 Hz version please add the 7% over the std 50 Hz price.

C) Unique Heat Transfer System

Thermal mass and direct expansion systems in a single unit

GTS technology for heat transfer from compressed air to refrigerant air is exclusive to Tegnon. Thanks to the special design of the evaporator: a finned coil nestling in a bed of silica, heat is transfered from the compressed air to the refrigerant both directly, through the fins, and indirectly, through the silica thermal mass. The heat exchanger geometry was optimised to obtain maximum efficiency and consistent high performance.

The GTS principle

The main advantages of GTS

In full load operation (100% air flow and summer conditions) cooling takes place directly through the aluminium fins

In part load operation the refrigerant transfers part of its cooling energy to the silica.

Energy saving: the refrigerant compressor only works when it needs to, thereby offering energy savings of up to 80% in normal operting conditions.
Extremely simple and reliable cooling circuit, like a domestic refrigerator.
Constant dewpoint, even during sudden variations in load.
The unit does not need the pre-start period of traditional thermal mass dryers
The dryer can be left permanently switched on without wasting energy.
Constant performance over time: there is no hot gas valve that may need adjustment.
Longer working life: refrigerant compressor motor runs cooler and less hours

With the refrigerant compressor stopped (energy saving phase) heat is transfered from the compressed air to the previously cooled silica.

Other advantages

There is no water and glycol tank for storing cooling energy: no risk of leakage.
Lower delta-t between evaporating temperature and dewpoint than traditional thermal mass dryers
No risk of contamination of the compressed air circuit by refrigerant or vice-versa in the event of a tube leak.
Silica sand thermal mass: a totally non-toxic substance that does not require special disposal measures.
Fewer brazed connections in the refrigerant circuit with consequent reduction in the risk of leaks.

D) Other Products

Water cooled aftercoolers for compressed air

Compressed air flows through the tubes of the heat exchanger in counter-flow to the cooling water flowing through the shell. As the compressed air cools, some of the water vapour it contains condenses. The condensed moisture is precipitated out of the airstream in the separator where it is discharged from the system.

Air cooled aftercoolers for compressed air

Air cooled aftercoolers for compressed air Compressed air flows through the tubes of the heat exchanger in counter-flow to the ambient air streamblown across the fins by the fan. As the compressed air cools, some of the water vapour it contains condenses. The condensed moisture is precipitated out of the air stream in the separator where it is discharged from the system.

Automatic condensate discharge

Automatic Drains - Mechanical float & lever, timer controlled solenoid or capacitance measurement types available for pressure up to 50 Bar