series DF-47 · 2020. 9. 24. · . series Long-throw spherical diffusers DF-48 . DF-48 1 CONTENTS...
Transcript of series DF-47 · 2020. 9. 24. · . series Long-throw spherical diffusers DF-48 . DF-48 1 CONTENTS...
series
Long-throw rectangular diffusers
www.koolair.com
DF-47
DF-47 1
CONTENTS DF-47 rectangular diffuser 2Dimensions 3Selection table 4Selection and correction charts 5Symbols 14
Description The DF-47 long-throw rectangular diffuser is manufactured entirely of anodised aluminium with a natural finish. The diffuser is composed of a drum allowing the unit to be swiveled, thereby permitting the inlet airflow to be vertically positioned at an angle of ±20º. The unit is also equipped with deflecting blades for distributing the air in horizontal fan-shape or concentrating the inlet airflow in the desired direction. Application These long-throw, high-flow diffusers are particularly useful when the air jet should reach some distance or should be fanned out. They are specially recommended for sport centres, industrial warehouses, clean rooms, recording studios, discotheques, large premises, etc. Dimensions and mounting The dimensions correspond to the size of the opening. The diffuser is always screw-mounted, either directly to the surface or using the MM-47 mounting frame. Also available are 29-0-47 adjustment assemblies that can be accessed with a screwdriver from the front of the diffuser. See dimension tables on page 3. Identification The diffusers can be manually adjusted to adapt the inlet airflow to the needs of the room. The AE model is equipped with a motor that changes the direction of the air (up or down) for use with cold or hot air (summer or winter); this motor may be proportional or on-off (two positions).
DF-47 rectangular diffuser
2 DF-47
Rectangular, long-throw diffuser for manual operation.
Rectangular, long-throw diffuser for manual operation, adaptable to round duct. Five sizes (see page 3) Volume control damper. Metal mounting frame. Motorised mechanism. Thermoadjustable.
DF-47
DF-47-CC
23, 26 36 312, 410
29-O-47
MM-47
AE
TR
21
DV
O
MM Con MM Para
MM
DF-47 rectangular diffuser
DF-47 3
DF-47 dimensions
DF-47 dimensions
DF-47-AE dimensions (motorised)
The AE model with the motor drive is longer, due to the servo motor.
The CC model, constructed to be fitted directly to the round duct, can also be motor-driven (AE).
The diffusers can be swiveled ±20° around the horizontal symmetry axis.
DF-47 selection table
4 DF-47
Notes - This selection table is based on laboratory tests as per ISO 5219 (UNE 100.710) and ISO 5135 and 3741. - ∆T is equal to 0°C (isothermal air). - The behaviour of the air jet with different ∆t is shown in the following charts.
Size
(m3/h) (l/s) Ak (m2)
150 41,7 Vk (m/s)
X0,3 X0,5 X1,0 (m) 4,6 2,7 1,4
Pt (Pa)
LwA - dB(A)
300 83,3 Vk (m/s)
X0,3 X0,5 X1,0 (m) 9,1 5,5 2,7 6,6 3,9 2,0
Pt (Pa)
LwA - dB(A)
450 125,0 Vk (m/s)
X0,3 X0,5 X1,0 (m) 13,7 8,2 4,1 9,8 5,9 3,0 6,5 3,9 2,0
Pt (Pa)
LwA - dB(A)
600 166,7 Vk (m/s)
X0,3 X0,5 X1,0 (m) 18,3 11,0 5,5 13,1 7,9 3,9 8,7 5,2 2,6
Pt (Pa)
LwA - dB(A)
800 222,2 Vk (m/s)
X0,3 X0,5 X1,0 (m) 24,4 14,6 7,3 17,5 10,5 5,2 11,6 7,0 3,5 8,3 5,0 2,5
Pt (Pa)
LwA - dB(A)
1000 277,8 Vk (m/s)
X0,3 X0,5 X1,0 (m) >30 18,3 9,1 21,9 13,1 6,6 14,5 8,7 4,4 10,3 6,2 3,1 7,5 4,5 2,2
Pt (Pa)
LwA - dB(A)
2000 555,6 Vk (m/s)
X0,3 X0,5 X1,0 (m) >30 26,2 13,1 29,0 17,4 8,7 20,6 12,4 6,2 15,0 9,0 4,5
Pt (Pa)
LwA - dB(A)
3000 833,3 Vk (m/s)
X0,3 X0,5 X1,0 (m) >30 26,1 13,1 >30 18,6 9,3 22,4 13,5 6,7
Pt (Pa)
LwA - dB(A)
5000 1388,9 Vk (m/s)
X0,3 X0,5 X1,0 (m) >30 >30 15,5 >30 22,4 11,2
Pt (Pa)
LwA - dB(A)
6000 1666,7 Vk (m/s)
X0,3 X0,5 X1,0 (m) >30 26,9 13,5
Pt (Pa)
LwA - dB(A)
7000 1944,4 Vk (m/s)
X0,3 X0,5 X1,0 (m) >30 >30 15,7
Pt (Pa)
LwA - dB(A)
12,9
96
59
5,5
18
32
9,2
49
71
48
11,1
54
1067x380
0,1508
Q 610x165
0,0383
305x165
0,0198
6
<15
4,3
<15
2,7
11
18
5,8
27
20
123
<15
4,5
22
12
7,2
31
34
14,5
48
56
76
54
2,0
4
27
38
1,8
25
6,9
<15
2
1219x267
0,1213
610x267
0,0613
<15
2,1
3
6,3
24
27
4,2
10
<15
8,4
42
36
11,2
74
45
14,1
116
3,3
52
2,2
3
<15
<15
2
19
3,6
9,1
8
43
13,6
56
3
<15
3,7
8
4,6
12
11,5
107
2
<15
2,3 1,8
Symbols Q = Air flow VK = Effective velocity AK = Effective area ∆Pt = Total pressure drop LwA = Sound power X0,3 - X0,5 - X1,0 = Throw for a terminal air velocity of 0.3, 0.5 and 1.0 m/s, respectively.
DF-47 model
DF-47 5
Selection charts DF-47-1.-Maximum vertical penetration
DF-47 model
6 DF-47
DF-47-2.- Velocity of the air jet in the throw
DF-47 7
DF-47 model
DF-47-3.1.- Vertical deviation of the air jet (non-isothermal jets)
8 DF-47
DF-47 model
DF-47-3.2.- Vertical deviation of the air jet (non-isothermal jets)
DF-47 9
DF-47 model
DF-47-3.3.- Vertical deviation of the air jet (non-isothermal jets)
DF-47 model
10 DF-47
DF-47-3.4.- Vertical deviation of the air jet (non-isothermal jets)
DF-47 11
DF-47 model
DF-47-3.5.- Vertical deviation of the air jet (non-isothermal jets)
DF-47 model
12 DF-47
DF-47-4.- Ratio between air flow velocities.
DF-47-5.- Ratio between temperature differences.
DF-47 13
DF-47 model
DF-47-6.- Induction rate
DF-47-7.- Pressure drop and sound power level
Symbols
14 DF-47
Common symbols used in all tables and charts in the catalogue. I(m): Distance between the equipment to the impact point of the jets (with another jet or wall) under isothermal
conditions. αx(°): Supply angle. L(m): Horizontal distance from the equipment to the impact point of the jets (with another jet or wall). X(m): Throw of the air jet. Y(m): Deviation of the air jet caused by a temperature difference between the supply and ambient air. H(m): Installation height of the equipment. HH(m): Height of occupied area. HC(m): Height from the impact point of the jets (with another jet or wall) under isothermal conditions with respect
to the equipment location. HI(m): Height from the impact point of the jets (with another jet or wall) under isothermal conditions. HR(m): Height from impact point of the jets (with another jet or wall) with respect to the point where the air velocity and temperature are to be determined (generally the occupied area). Q(m3/h ó l/s): Supply air flow. AK(m2): Effective area. VX(m/s): Velocity of the jets at throw X. VH(m/s): Velocity of the jets in the occupied area. VK(m/s): Effective supply velocity. VHR(m/s): Velocity of the jets at a distance, HR, below the impact point of the jets (with another jet or wall). ∆TO(°C): Temperature difference between the supply jets and room air. ∆TX(°C): Temperature difference between the jets (for throw X) and room air. ∆Th(°C): Temperature difference between the jets (in occupied area) and room air. qx/qo: Induction rate. Quotient between the air flow for a throw X and the air flow supplied in the zone. Ymax(m): Maximum throw with vertical supply of hot air (Vx=0 m/s). ∆Pt(Pa): Total pressure drop. LwA[dB(A)]: Sound power level.
THIS CATALOGUE IS INTELLECTUAL PROPERTY. Reproduction, either partial or total, by any means, including electronic, is prohibited without prior written authorisation from KOOLAIR, S.L.
CEN-DF-47-0815-00
DF-47 15
KOOLAIR, S.L.
Calle Urano, 26Poligono industrial nº 2 – La Fuensanta 28936 Móstoles - Madrid - (España) Tel: +34 91 645 00 33Fax: +34 91 645 69 62e-mail: [email protected]
www.koolair.com
series
Long-throw spherical diffusers
DF-48
www.koolair.com
DF-48 1
CONTENTS DF-48 spherical diffuser 2 Dimensions 3 DF-48 selection table 4 Selection and correction charts 5 Symbols 16
2 DF-48
DF-48 spherical diffuser
Spherical long-throw diffuser, manual operation. Spherical long-throw diffuser, manual operation with direct coupling collar to flexible duct.
Seven sizes (see page 3)
Plenum or flan plate. Plenum box with connection to round duct. Integrated in plate to be adapted in round face duct. With “boot” to be installed in a round face duct.
DF-48
DF-48-C
3, 5, 8, 10, 12, 16 y 20
AC PAC PCL INJ
Description The DF-48 long-throw, spherical diffuser in its standard version is manufactured entirely of anodised aluminium with a natural finish. By special order, the diffuser can be painted in any RAL colour. The diffuser has a volume control damper at the outlet. Application The DF-48 diffusers allow long throws with an acceptable noise level. The diffuser releases an occasional air jet with a throw of over 30 metres. They can be used for spot cooling and are especially appropriate for sport centres, industrial warehouses, clean rooms, recording studios, discotheques and large premises, as well as any area requiring precisely targeted air jets. The configuration allows the diffuser to be swiveled in any direction up to a maximum of ±35° in the horizontal or vertical direction. Dimensions and mounting The diffusers must attached by screws. The units can be supplied with plenum boxes or a plate fitted in an assembly of up to six units. See dimensions on page 3. Identification Seven sizes.
DF-48 dimensions
Dimensions DF-48 and DF-48-C
DF-48 accessories
DIFFUSER Ø C Ø R Ø S5 145 138 2008 219 212 27010 269 262 31912 325 318 37416 432 425 49020 508 496 547
Dimensions of plenum boxes for connection to round duct
Dimensions of plates with diffuser assemblies
DF-48 3
DF-48 selection table
Notes - This selection table is based on laboratory tests as per ISO 5219 (UNE 100.710) and ISO 5135 and 3741 standards. - ∆t is equal to 0°C (isothermal air). - The behaviour of the air jet with different ∆t is shown in the following charts.
Symbols Q = Air flow VK = Effective velocity AK = Effective area ∆Pt = Total pressure drop LwA = Sound power X0,3 - X0,5 - X1,0 = Throw for a terminal air velocity of 0.3, 0.5 and 1.0 m/s, respectively.
Size
(m3/h) (l/s) Ak (m2)
25 6,9 Vk (m/s)
X0,3 X0,5 X1,0 (m) 3,3 2,0 1,0 2,1 1,3 0,6
Pt (Pa)
LwA - dB(A)
50 13,9 Vk (m/s)
X0,3 X0,5 X1,0 (m) 6,7 4,0 2,0 4,2 2,5 1,3
Pt (Pa)
LwA - dB(A)
100 27,8 Vk (m/s)
X0,3 X0,5 X1,0 (m) 13,4 8,0 4,0 8,4 5,0 2,5 5,4 3,3 1,6
Pt (Pa)
LwA - dB(A)
250 69,4 Vk (m/s)
X0,3 X0,5 X1,0 (m) 21,0 12,6 6,3 13,5 8,1 4,1 8,2 4,9 2,5
Pt (Pa)
LwA - dB(A)
500 138,9 Vk (m/s)
X0,3 X0,5 X1,0 (m) 27,1 16,3 8,1 16,5 9,9 4,9 11,8 7,1 3,5
Pt (Pa)
LwA - dB(A)
750 208,3 Vk (m/s)
X0,3 X0,5 X1,0 (m) 24,7 14,8 7,4 17,7 10,6 5,3 13,6 8,1 4,1
Pt (Pa)
LwA - dB(A)
1250 347,2 Vk (m/s)
X0,3 X0,5 X1,0 (m) >30 24,7 12,3 29,5 17,7 8,9 22,6 13,6 6,8
Pt (Pa)
LwA - dB(A)
2000 555,6 Vk (m/s)
X0,3 X0,5 X1,0 (m) >30 28,4 14,2 >30 21,7 10,9
Pt (Pa)
LwA - dB(A)
2750 763,9 Vk (m/s)
X0,3 X0,5 X1,0 (m) >30 29,9 14,9
Pt (Pa)
LwA - dB(A)
3500 972,2 Vk (m/s)
X0,3 X0,5 X1,0 (m) >30 >30 19,0
Pt (Pa)
LwA - dB(A)
12 16 20Q 3 5 8
0,0707
5,3 2,1
0,0013 0,0033 0,0079
3
0,04150,0214
<15 <15
17
68 11
10,7 4,2
25 <15
21,4 8,4 3,5
274 43
46 22 <15
7
27 <15
21,0 8,8 3,2
266 46 6
3,317,6 6,5
50
185
48 22
7
<15
25
15 5
5,0 2,9
57
9,7
<15
16,2 8,4 4,9
34 17
14
50 33 19
158 42
7,9
108 37
13,4
33
10,8
47
70
43
13,8
113
50
4 DF-48
DF-48 model
Selection charts DF-48-1.- Maximum vertical penetration.
DF-48 5
DF-48 model
DF-48-2.- Velocity of the air jet for the throw.
6 DF-48
DF-48 model
DF-48-3.1.- Vertical deviation of the air jet (non-isothermal jets).
DF-48 7
DF-48 model
DF-48-3.2.- Vertical deviation of the air jet (non-isothermal jets).
8 DF-48
DF-48 model
DF-48-3.3.- Vertical deviation of the air jet (non-isothermal jets).
DF-48 9
DF-48 model
DF-48-3.4.- Vertical deviation of the air jet (non-isothermal jets).
10 DF-48
DF-48 model
DF-48-3.4.- Vertical deviation of the air jet (non-isothermal jets).
DF-48 11
DF-48 model
DF-48-3.5.- Vertical deviation of air jet (non-isothermal jets).
12 DF-48
DF-48 model
DF-48-3.6.- Vertical deviation of the air jet (non-isothermal jets).
DF-48 13
DF-48 model
DF-48-4.- Ratio between air flow velocities.
DF-48-5.- Ratio between temperature differences.
14 DF-48
DF-48 model
DF-48-6.- Induction rate.
DF-48-7.- Pressure drop and sound power level.
DF-48 15
Symbols
Common symbols used in all tables and charts in the catalogue. I(m): Distance between the equipment to the impact point of the jets (with another jet or wall) under isothermal
conditions. αx(°): Supply angle. L(m): Horizontal distance from the equipment to the impact point of the jets (with another jet or wall). X(m): Throw of the air jet. Y(m): Deviation of the air jet caused by a temperature difference between the supply and ambient air. H(m): Installation height of the equipment. HH(m): Height of occupied area. HC(m): Height from the impact point of the jets (with another jet or wall) under isothermal conditions with respect
to the equipment location. HI(m): Height from the impact point of the jets (with another jet or wall) under isothermal conditions. HR(m): Height from impact point of the jets (with another jet or wall) with respect to the point where the air velocity and temperature are to be determined (generally the occupied area). Q(m3/h ó l/s): Supply air flow. AK(m2): Effective area. VX(m/s): Velocity of the jets at throw X. VH(m/s): Velocity of the jets in the occupied area. VK(m/s): Effective supply velocity. VHR(m/s): Velocity of the jets at a distance, HR, below the impact point of the jets (with another jet or wall). ∆TO(°C): Temperature difference between the supply jets and room air. ∆TX(°C): Temperature difference between the jets (for throw X) and room air. ∆Th(°C): Temperature difference between the jets (in occupied area) and room air. qx/qo: Induction rate. Quotient between the air flow for a throw X and the air flow supplied in the zone. Ymax(m): Maximum throw with vertical supply of hot air (Vx=0 m/s). ∆Pt(Pa): Total pressure drop. LwA[dB(A)]: Sound power level.
16 DF-48
THIS CATALOGUE IS INTELLECTUAL PROPERTY. Reproduction, either partial or total, by any means, including electronic, is prohibited without prior written authorisation from KOOLAIR, S.L.
CEN-DF-48-0815-00
DF-48 17
KOOLAIR, S.L.
Calle Urano, 26Poligono industrial nº 2 – La Fuensanta 28936 Móstoles - Madrid - (España) Tel: +34 91 645 00 33Fax: +34 91 645 69 62e-mail: [email protected]
www.koolair.com
series
Long-throw nozzles
www.koolair.com
DF-49
DF-49 1
CONTENTS DF-49 jet nozzle 2 Dimensions 3 DF-49 selection table 4 Selection and correction charts 5 Selection example 14 Symbols 16
DF-47 DF-49
DGV DVP
MM Con MM Para MM
2 DF-49
DF-49 long-throw nozzle
Description The DF-49 combines long-throw efficiency with a more harmonious design. The stylised lines of the nozzles and the possibility of matching current decorative styles make these diffusers a reliable, great-looking component for facilities with more stringent requirements in terms of design and comfort. Interior architecture are increasingly designing larger spaces for hotels, shopping malls, salons, convention centres, airport vestibules, passenger stations, social halls, etc. In addition to effective air blowing at a long distance through nozzles (originally designed for industrial facilities), the use of these terminal units in more comfortable surroundings requires utmost attention to the aesthetic design. The DF-49 long-throw nozzle and the decorative ring are manufactured in aluminium, with a standard paint finish in RAL 9010 white. The connection part is manufactured of galvanised steel sheet. The DF-49 nozzle has an extraordinarily good aesthetic design and can be painted by special order to fit any decorative need. Application The DF-49 nozzles provide long throws with a low noise level, releasing a long air jet with exceptional precision to a length of over 30 metres. They can be used for spot cooling and are especially appropriate for large rooms requiring a decorative look, for instance, large vestibules, nightclubs or entertainment areas, department stores, hotels, etc. The configuration allows the nozzle to swivel in all directions up to a maximum of ±30° in the horizontal or vertical direction. Dimensions and mounting The diffusers are attached by screws that are hidden by the decorative ring. See page 3. Identification Five sizes with manual swiveling. The motor drive swivels the nozzle in the vertical direction (up and down) at an angle of approximately ± 30°. For motor-driven operation one motor is required per nozzle, even in assemblies containing several units.
Long-throw nozzles, manual operation. Connection system. Six sizes (see page 3).
Motor drive. Thermoadjustable
Plenum or flan plate. Plenum box with connection to round duct. Integrated in plate to be adapted in round face duct. With “boot” to be installed in a round face duct.
DF-49
A or B
5, 8, 10, 12, 16, 20
AC PAC PCL INJ
AE TR
DF-49 Accessories
DF-49 3
DF-49 long-throw nozzle
DIFFUSER Ø C Ø R Ø S5 160 152 1828 230 222 25210 282 274 30412 335 329 35916 445 436 49420 517 508 536
Dimensions Version A of the DF-49 jet nozzles can be mounted directly to the duct, plenum box or surface. Version B allows a flexible duct of standard dimensions to be coupled directly to each nozzle. In both cases, the nozzles are fixed by screws, which are housed below a decorative ring which can be removed by simple pressure. In terms of the motor drive system, the motor may be placed inside or outside the unit, depending on the connection system and motor type (each case should be analysed separately). Please contact us for more information.
DF-49 selection table
Notes - This selection table is based on laboratory tests as per ISO 5219 (UNE 100.710) and ISO 5135 and 3741. - ∆T is equal to 0°C (isothermal air). - The behaviour of the air jet with different ∆t is shown in the following charts.
Symbols Q = Air flow VK = Effective velocity AK = Effective area ∆Pt = Total pressure drop LwA = Sound power X0,3 - X0,5 - X1,0 = Throw for a terminal air velocity of 0.3, 0.5 and 1.0 m/s, respectively.
Size
(m3/h) (l/s) Ak (m2)
75 20,8 Vk (m/s)
X0,3 X0,5 X1,0 (m) 11,4 6,9 3,4 6,9 4,1 2,1
Pt (Pa)
LwA - dB(A)
150 41,7 Vk (m/s)
X0,3 X0,5 X1,0 (m) 22,9 13,7 6,9 13,8 8,3 4,1 9,4 5,7 2,8
Pt (Pa)
LwA - dB(A)
250 69,4 Vk (m/s)
X0,3 X0,5 X1,0 (m) >30 22,9 11,4 22,9 13,8 6,9 15,7 9,4 4,7 12,9 7,8 3,9
Pt (Pa)
LwA - dB(A)
500 138,9 Vk (m/s)
X0,3 X0,5 X1,0 (m) >30 27,5 13,8 >30 18,9 9,4 25,9 15,5 7,8 17,3 10,4 5,2
Pt (Pa)
LwA - dB(A)
750 208,3 Vk (m/s)
X0,3 X0,5 X1,0 (m) >30 28,3 14,1 >30 23,3 11,6 26,0 15,6 7,8
Pt (Pa)
LwA - dB(A)
1000 277,8 Vk (m/s)
X0,3 X0,5 X1,0 (m) >30 >30 15,5 >30 20,8 10,4 25,5 15,3 7,6
Pt (Pa)
LwA - dB(A)
1500 416,7 Vk (m/s)
X0,3 X0,5 X1,0 (m) >30 >30 23,3 >30 >30 15,6 >30 22,9 11,5
Pt (Pa)
LwA - dB(A)
2000 555,6 Vk (m/s)
X0,3 X0,5 X1,0 (m) >30 >30 20,8 >30 >30 15,3
Pt (Pa)
LwA - dB(A)
2500 694,4 Vk (m/s)
X0,3 X0,5 X1,0 (m) >30 >30 26,0 >30 >30 19,1
Pt (Pa)
LwA - dB(A)
3000 833,3 Vk (m/s)
X0,3 X0,5 X1,0 (m) >30 >30 22,9
Pt (Pa)
LwA - dB(A)
3500 972,2 Vk (m/s)
X0,3 X0,5 X1,0 (m) >30 >30 26,7
Pt (Pa)
LwA - dB(A)
4000 1111,1 Vk (m/s)
X0,3 X0,5 X1,0 (m) >30 >30 >30
Pt (Pa)
LwA - dB(A)
69
42
37
15,3
90
46
13,4
35
32
11,5
51
7,7
23
25
9,6
<15
5,8
13
17
3,8
6
Q 5 8 1210
47
20
0,0724
5,5
11,0
<15
19
<15
0,0025 0,0060 0,0184 0,03900,01262
8,3 3,5
6,9
37
3,3
25 7
7,5
3,8
3,6
7
<15
<15
6
22,6
255
10,7
35
58
50
161
50
14,2
103
44
17,8
113 26
38 23
5,3
15
<15
15,1 7,1
64
29
28
11,3
274
1733
16,5
169
75
411 69
23,0
16
148
6
16,6
<15 <15
34
49
<15
26
47
27,7 11,5
4 DF-49
DF-49 model
Selection charts DF-49-1.- Maximum vertical penetration.
DF-49 5
DF-49 model
DF-49-2.- Velocity of the air jet for the throw.
6 DF-49
DF-49 model
DF-49-3.1.- Vertical deviation of the air jet (non-isothermal jets).
DF-49 7
DF-49 model
DF-49-3. 2.- Vertical deviation of the air jet (non-isothermal jets).
8 DF-49
DF-49 model
DF-49-3. 3.- Vertical deviation of the air jet (non-isothermal jets).
DF-49 9
DF-49 model
DF-49-3. 3.- Vertical deviation of the air jet (non-isothermal jets).
10 DF-49
DF-49 model
DF-49-3. 4.- Vertical deviation of the air jet (non-isothermal jets).
DF-49 11
DF-49 model
DF-49-4.- Ratio between air flow velocities.
DF-49-5.- Ratio between temperature differences.
12 DF-49
DF-49 model
DF-49-6.- Induction rate.
DF-49-7.- Pressure drop and sound power level.
DF-49 13
Selection in a sample project
Initial data Two DF-49 nozzles are located, one in front of the other at a distance of 24 m, with the following starting data based on the sketch attached in the Symbols section on page 16. - L = 12 m - H = 4 m (height from floor) - Qnozzle = 400 l/s - Supply temperature = 15° C - Room temperature = 25° C - ∆T0 = -10° C - HH = 2 m (height of occupied area) The diffuser should be selected to obtain the following: - Maximum velocity in the occupied area: 0,2 m/s. - The vertical temperature gradient must not exceed 3 ºC. - The sound power level of the selected equipment must not exceed 40 dB(A).
14 DF-49
Selection - DF-49 quick selection table (page 4) Based on the sound power limit, size 16 is preselected. - DF-49-7 chart (page 13) Using size 16 for 400 l/s, the following values are obtained: - ∆Pt = 54 Pa (pressure drop) - LwA = 34 dB(A) (sound power level) - DF-49-2 chart (page 6) For a supply angle of αX= +15° C, The throw will be I=L/cos 15°=12/0,966=12,42 m According to the chart, the velocity for this throw is VX=1,2 m/s - DF-49-3.4 chart (page 11) The impact point under isothermal conditions would be H+HC=H+(L x tan 15°)=4+(12x0,268)=7,2 m The chart indicates that for ∆Τ0 = -10° C, throw: 12,42 m and Q: 400 l/s the vertical deviation is Y = 1,6 m,
as the air jet is non-isothermal. Therefore, the air jets have an impact point situation at a height from the floor of: 7,2-1,6=5,6 m. - DF-49-4 chart (page 12)
For a height HR=5,6-2=3,6m, entering with VX=1,2 m/s gives a velocity of VHR=VH=0,17 m/s in the occupied area. - DF-49-6 chart (page 13) For a throw of I+HR=12,42+3,6=16,02 we have qx/qo=21,9. - DF-49-5 chart (page 12) For a throw of I+HR=12,42+3,6=16,02 we have ∆TX/∆T0=0,07. Therefore, the temperature of the air jet at its inlet in the occupied zone will be: ∆TX=TX-TTemperature TX=TTemperature+∆TX=25+[0,07x(-10)] TX= 24,3° C
DF-49 15
Symbols
Common symbols used in all tables and charts in the catalogue. I(m): Distance between the equipment to the impact point of the jets (with another jet or wall) under isothermal
conditions. αx(°): Supply angle. L(m): Horizontal distance from the equipment to the impact point of the jets (with another jet or wall). X(m): Throw of the air jet. Y(m): Deviation of the air jet caused by a temperature difference between the supply and ambient air. H(m): Installation height of the equipment. HH(m): Height of occupied area. HC(m): Height from the impact point of the jets (with another jet or wall) under isothermal conditions with respect
to the equipment location. HI(m): Height from the impact point of the jets (with another jet or wall) under isothermal conditions. HR(m): Height from impact point of the jets (with another jet or wall) with respect to the point where the air velocity and temperature are to be determined (generally the occupied area). Q(m3/h ó l/s): Supply air flow. AK(m2): Effective area. VX(m/s): Velocity of the jets at throw X. VH(m/s): Velocity of the jets in the occupied area. VK(m/s): Effective supply velocity. VHR(m/s): Velocity of the jets at a distance, HR, below the impact point of the jets (with another jet or wall). ∆TO(°C): Temperature difference between the supply jets and room air. ∆TX(°C): Temperature difference between the jets (for throw X) and room air. ∆Th(°C): Temperature difference between the jets (in occupied area) and room air. qx/qo: Induction rate. Quotient between the air flow for a throw X and the air flow supplied in the zone. Ymax(m): Maximum throw with vertical supply of hot air (Vx=0 m/s). ∆Pt(Pa): Total pressure drop. LwA[dB(A)]: Sound power level.
16 DF-49
THIS CATALOGUE IS INTELLECTUAL PROPERTY. Reproduction, either partial or total, by any means, including electronic, is prohibited without prior written authorisation from KOOLAIR, S.L.
CEN-DF-49-0815-00
DF-49 17
KOOLAIR, S.L.
Calle Urano, 26Poligono industrial nº 2 – La Fuensanta 28936 Móstoles - Madrid - (España) Tel: +34 91 645 00 33Fax: +34 91 645 69 62e-mail: [email protected]
www.koolair.com
series
Long-throw nozzles
www.koolair.com
DF-49-ROT
DF-49-ROT 1
CONTENTS Long-throw jet nozzle DF-49-ROT 2 Selection table 3
Long-throw jet nozzle DF-49-ROT
2 DF-49-ROT
MODEL ØA ØB ØC ØD ØE F G H J8 268 209 90 235 217 34 93 127 17
10 317 258 123 284 268 48 112 160 1712 376 313 155 343 323 56 125 181 2016 511 422 220 478 433 78 149 227 2020 584 595 290 552 605 80 156 236 20
Description The new DF-49-ROT combines long-throw efficiency with a more harmonious design, the novelty in this model relative to the nozzle DF49 is the inclusion of a rotational element that reduces air jet for applications where you need shorter throw. The stylised lines of the nozzles and the possibility of matching current decorative styles make these diffusers a reliable, great-looking component for facilities with more stringent requirements in terms of design and comfort. In addition to effective air blowing at a long distance through nozzles (originally designed for industrial facilities), the use of these terminal units in more comfortable surroundings requires utmost attention to the aesthetic design. Interior architecture are increasingly designing larger spaces for hotels, shopping malls, salons, convention centres, airport vestibules, passenger stations, social halls, etc. The DF-49-ROT long-throw nozzle and the decorative ring are manufactured in aluminium, with a standard paint finish in RAL 9010 white. The fixed blade swirl element and the connection part is manufactured of galvanised steel sheet. The DF-49-ROT nozzle has an extraordinarily good aesthetic design and can be painted by special order to fit any decorative need. Application The DF-49-ROT nozzles provide medium throws with a low noise level, releasing a long air jet with exceptional precision to a length of over 20 metres. They can be used for spot cooling and are especially appropriate for large rooms requiring a decorative look, for instance, large vestibules, nightclubs or entertainment areas, department stores, hotels, etc. The configuration allows the nozzle to swivel in all directions up to a maximum of ±30° in the horizontal or vertical direction, the angle of rotation can be determined in steps of 5° adapting specifically to the needs of each installation. Identification Five sizes with manual swiveling. The motor drive swivels the nozzle in the vertical direction (up and down) at an angle of approximately ± 30°. For motor-driven operation one motor is required per nozzle, even in assemblies containing several units. There is also the possibility of thermo-adjustable version.
Long-throw jet nozzle DF-49-ROT
DF-49-ROT 3
Size
(m3/h) (l/s) Ak (m2)
150 41,7 Vk (m/s)
X0,3 X0,5 X1,0 (m) 11,0 6,6 3,3 7,5 4,5 2,3 6,2 3,7 1,9 4,2 2,5 1,2 3,1 1,8 0,9
Pt (Pa)
LwA - dB(A)
250 69,4 Vk (m/s)
X0,3 X0,5 X1,0 (m) 18,3 11,0 5,5 12,6 7,5 3,8 10,3 6,2 3,1 6,9 4,2 2,1 5,1 3,1 1,5
Pt (Pa)
LwA - dB(A)
350 97,2 Vk (m/s)
X0,3 X0,5 X1,0 (m) 25,7 15,4 7,7 17,6 10,6 5,3 14,5 8,7 4,3 9,7 5,8 2,9 7,1 4,3 2,1
Pt (Pa)
LwA - dB(A)
500 138,9 Vk (m/s)
X0,3 X0,5 X1,0 (m) 25,2 15,1 7,5 20,7 12,4 6,2 13,9 8,3 4,2 10,2 6,1 3,1
Pt (Pa)
LwA - dB(A)
750 208,3 Vk (m/s)
X0,3 X0,5 X1,0 (m) >30 18,6 9,3 20,8 12,5 6,2 15,3 9,2 4,6
Pt (Pa)
LwA - dB(A)
1000 277,8 Vk (m/s)
X0,3 X0,5 X1,0 (m) >30 24,8 12,4 27,7 16,6 8,3 20,4 12,2 6,1
Pt (Pa)
LwA - dB(A)
1250 347,2 Vk (m/s)
X0,3 X0,5 X1,0 (m) >30 20,8 10,4 25,5 15,3 7,6
Pt (Pa)
LwA - dB(A)
1500 416,7 Vk (m/s)
X0,3 X0,5 X1,0 (m) >30 25,0 12,5 >30 18,3 9,2
Pt (Pa)
LwA - dB(A)
2000 555,6 Vk (m/s)
X0,3 X0,5 X1,0 (m) >30 >30 16,6 >30 24,4 12,2
Pt (Pa)
LwA - dB(A)
2500 694,4 Vk (m/s)
X0,3 X0,5 X1,0 (m) >30 >30 15,3
Pt (Pa)
LwA - dB(A)
3000 833,3 Vk (m/s)
X0,3 X0,5 X1,0 (m) >30 >30 18,3
Pt (Pa)
LwA - dB(A)
56
47
9,6
39
42
11,5
27
7,7
25
35
10
21
5,8
14
3,8
6
<15
4,8
36
46
16,1
151
77 21
20
19
<15
15
16
8 2
3,8 1,8
<15 <15
<15
11,3
2743
84
5,3
16
24
15,1 7,1
71
39
126 29
48 33
116
8,9
40
45
10,7
65
45
14,2
54
20
0,0724
0,6
0
<15
1,0
0
<15
1,3
1
<15
7
4
3,6
<15
1,9
2
<15
2,9
4
<15
7,5
5,3 2,57,7
11,0
41
31
32
16
<15
11,5
<15
5,5
3 1
6,9 2,3 1,1
8
3,3
28
0,0060 0,0184 0,03900,01262
Q 8 1210
Symbols Q = Air flow VK = Effective velocity AK = Effective area ∆Pt = Total pressure drop LwA = Sound power X0,3 - X0,5 - X1,0 = Throw for a terminal air velocity of 0.3, 0.5 and 1.0 m/s, respectively.
THIS CATALOGUE IS INTELLECTUAL PROPERTY. Reproduction, either partial or total, by any means, including electronic, is prohibited without prior written authorisation from KOOLAIR, S.L.
CEN-DF-49-ROT-0815-00
4 DF-49-ROT
KOOLAIR, S.L.
Calle Urano, 26Poligono industrial nº 2 – La Fuensanta 28936 Móstoles - Madrid - (España) Tel: +34 91 645 00 33Fax: +34 91 645 69 62e-mail: [email protected]
www.koolair.com
series
Long-throw nozzles
www.koolair.com
DF-89
DF-89 1
CONTENTS DF-89 jet nozzle 2 Dimensions 3 DF-89 selection table 4 Selection and correction charts 5 Selection example 14 Symbols 16
DF-47 DF-89
DGV DVP
DF-89-B
DF-89-A
MM Con MM Para MM
2 DF-89
Long-throw jet nozzle DF-89
Long-throw nozzles, manual operation. Connection system. Five sizes (see page 3).
Plenum or flan plate. Plenum box with connection to round duct. Integrated in plate to be adapted in round face duct. With “boot” to be installed in a round face duct.
DF-89
A or C
5, 8, 10, 12, 16, 20
AC
PAC PCL INJ
Description The DF-89 long-throw jet nozzle and its flange are made of aluminium painted white RAL 9010 as standard finish. The connection part is manufactured of galvanised steel sheet. The DF-89 nozzle has an extraordinarily good aesthetic design and can be painted by special order to fit any decorative need Application The DF-89 nozzles provide long throws with a low noise level, releasing a long air jet with exceptional precision to a length of over 30 metres. They can be used for spot cooling and are especially appropriate for large rooms requiring a decorative look, for instance, large vestibules, nightclubs or entertainment areas, department stores, hotels, etc. The configuration allows the nozzle to swivel in all directions up to a maximum of ±30° in the horizontal or vertical direction. Identification Five sizes with manual swiveling. The motor drive swivels the nozzle in the vertical direction (up and down) at an angle of approximately ± 30°. For motor-driven operation one motor is required per nozzle, even in assemblies containing several units.
DF-89 Accessories
DF-89 3
Long-throw jet nozzle DF-89
Dimensions Version A of the DF-89 jet nozzles can be mounted directly to the duct, plenum box or surface. Version B allows a flexible duct of standard dimensions to be coupled directly to each nozzle. In both cases, the nozzles are fixed by screws. In terms of the motor drive system, the motor may be placed inside or outside the unit, depending on the connection system and motor type (each case should be analysed separately). Please contact us for more information.
MODEL ØA ØB ØC ØD ØE F ØG5 205 182 55 143 123 68 488 276 254 90 215 198 80 5010 324 301 123 265 248 105 7912 380 356 155 322 313 132 7416 495 470 220 425 398 170 11320 553 526 290 500 498 185 135
DIFFUSER Ø C Ø R Ø S 5 145 138 200 8 219 212 270 10 269 262 319 12 325 318 374 16 432 425 490 20 508 496 547
DF-89-A DF-89-B
DF-89 selection table
Notes - This selection table is based on laboratory tests as per ISO 5219 (UNE 100.710) and ISO 5135 and 3741. - ∆T is equal to 0°C (isothermal air). - The behaviour of the air jet with different ∆t is shown in the following charts.
Symbols Q = Air flow VK = Effective velocity AK = Effective area ∆Pt = Total pressure drop LwA = Sound power X0,3 - X0,5 - X1,0 = Throw for a terminal air velocity of 0.3, 0.5 and 1.0 m/s, respectively.
Size
(m3/h) (l/s) Ak (m2)
75 20,8 Vk (m/s)
X0,3 X0,5 X1,0 (m) 11,4 6,9 3,4 6,9 4,1 2,1
Pt (Pa)
LwA - dB(A)
150 41,7 Vk (m/s)
X0,3 X0,5 X1,0 (m) 22,9 13,7 6,9 13,8 8,3 4,1 9,4 5,7 2,8
Pt (Pa)
LwA - dB(A)
250 69,4 Vk (m/s)
X0,3 X0,5 X1,0 (m) >30 22,9 11,4 22,9 13,8 6,9 15,7 9,4 4,7 12,9 7,8 3,9
Pt (Pa)
LwA - dB(A)
500 138,9 Vk (m/s)
X0,3 X0,5 X1,0 (m) >30 27,5 13,8 >30 18,9 9,4 25,9 15,5 7,8 17,3 10,4 5,2
Pt (Pa)
LwA - dB(A)
750 208,3 Vk (m/s)
X0,3 X0,5 X1,0 (m) >30 28,3 14,1 >30 23,3 11,6 26,0 15,6 7,8
Pt (Pa)
LwA - dB(A)
1000 277,8 Vk (m/s)
X0,3 X0,5 X1,0 (m) >30 >30 15,5 >30 20,8 10,4 25,5 15,3 7,6
Pt (Pa)
LwA - dB(A)
1500 416,7 Vk (m/s)
X0,3 X0,5 X1,0 (m) >30 >30 23,3 >30 >30 15,6 >30 22,9 11,5
Pt (Pa)
LwA - dB(A)
2000 555,6 Vk (m/s)
X0,3 X0,5 X1,0 (m) >30 >30 20,8 >30 >30 15,3
Pt (Pa)
LwA - dB(A)
2500 694,4 Vk (m/s)
X0,3 X0,5 X1,0 (m) >30 >30 26,0 >30 >30 19,1
Pt (Pa)
LwA - dB(A)
3000 833,3 Vk (m/s)
X0,3 X0,5 X1,0 (m) >30 >30 22,9
Pt (Pa)
LwA - dB(A)
3500 972,2 Vk (m/s)
X0,3 X0,5 X1,0 (m) >30 >30 26,7
Pt (Pa)
LwA - dB(A)
4000 1111,1 Vk (m/s)
X0,3 X0,5 X1,0 (m) >30 >30 >30
Pt (Pa)
LwA - dB(A)
69
42
37
15,3
90
46
13,4
35
32
11,5
51
7,7
23
25
9,6
<15
5,8
13
17
3,8
6
Q 5 8 1210
47
20
0,0724
5,5
11,0
<15
19
<15
0,0025 0,0060 0,0184 0,03900,01262
8,3 3,5
6,9
37
3,3
25 7
7,5
3,8
3,6
7
<15
<15
6
22,6
255
10,7
35
58
50
161
50
14,2
103
44
17,8
113 26
38 23
5,3
15
<15
15,1 7,1
64
29
28
11,3
274
1733
16,5
169
75
411 69
23,0
16
148
6
16,6
<15 <15
34
49
<15
26
47
27,7 11,5
4 DF-89
DF-89 model
Selection charts DF-89-1.- Maximum vertical penetration.
DF-89 5
DF-89 model
DF-89-2.- Velocity of the air jet for the throw.
6 DF-89
DF-89 model
DF-89-3.1.- Vertical deviation of the air jet (non-isothermal jets).
DF-89 7
DF-89 model
DF-89-3. 2.- Vertical deviation of the air jet (non-isothermal jets).
8 DF-89
DF-89 model
DF-89-3. 3.- Vertical deviation of the air jet (non-isothermal jets).
DF-89 9
DF-89 model
DF-89-3. 3.- Vertical deviation of the air jet (non-isothermal jets).
10 DF-89
DF-89 model
DF-89-3. 4.- Vertical deviation of the air jet (non-isothermal jets).
DF-89 11
DF-89 model
DF-89-4.- Ratio between air flow velocities.
DF-89-5.- Ratio between temperature differences.
12 DF-89
DF-89 model
DF-89-6.- Induction rate.
DF-89-7.- Pressure drop and sound power level.
DF-89 13
Selection in a sample project
Initial data Two DF-89 nozzles are located, one in front of the other at a distance of 24 m, with the following starting data based on the sketch attached in the Symbols section on page 16. - L = 12 m - H = 4 m (height from floor) - Qnozzle = 400 l/s - Supply temperature = 15° C - Room temperature = 25° C - ∆T0 = -10° C - HH = 2 m (height of occupied area) The diffuser should be selected to obtain the following: - Maximum velocity in the occupied area: 0,2 m/s. - The vertical temperature gradient must not exceed 3 ºC. - The sound power level of the selected equipment must not exceed 40 dB(A).
14 DF-89
Selection - DF-89 quick selection table (page 4) Based on the sound power limit, size 16 is preselected. - DF-89-7 chart (page 13) Using size 16 for 400 l/s, the following values are obtained: - ∆Pt = 54 Pa (pressure drop) - LwA = 34 dB(A) (sound power level) - DF-89-2 chart (page 6) For a supply angle of αX= +15° C, The throw will be I=L/cos 15°=12/0,966=12,42 m According to the chart, the velocity for this throw is VX=1,2 m/s - DF-89-3.4 chart (page 11) The impact point under isothermal conditions would be H+HC=H+(L x tan 15°)=4+(12x0,268)=7,2 m The chart indicates that for ∆Τ0 = -10° C, throw: 12,42 m and Q: 400 l/s the vertical deviation is Y = 1,6 m,
as the air jet is non-isothermal. Therefore, the air jets have an impact point situation at a height from the floor of: 7,2-1,6=5,6 m. - DF-89-4 chart (page 12)
For a height HR=5,6-2=3,6m, entering with VX=1,2 m/s gives a velocity of VHR=VH=0,17 m/s in the occupied area. - DF-89-6 chart (page 13) For a throw of I+HR=12,42+3,6=16,02 we have qx/qo=21,9. - DF-89-5 chart (page 12) For a throw of I+HR=12,42+3,6=16,02 we have ∆TX/∆T0=0,07. Therefore, the temperature of the air jet at its inlet in the occupied zone will be: ∆TX=TX-TTemperature TX=TTemperature+∆TX=25+[0,07x(-10)] TX= 24,3° C
DF-89 15
Symbols
Common symbols used in all tables and charts in the catalogue.
I(m): Distance between the equipment to the impact point of the jets (with another jet or wall) under isothermal conditions.
αx(°): Supply angle. L(m): Horizontal distance from the equipment to the impact point of the jets (with another jet or wall). X(m): Throw of the air jet. Y(m): Deviation of the air jet caused by a temperature difference between the supply and ambient air. H(m): Installation height of the equipment. HH(m): Height of occupied area. HC(m): Height from the impact point of the jets (with another jet or wall) under isothermal conditions with respect
to the equipment location. HI(m): Height from the impact point of the jets (with another jet or wall) under isothermal conditions. HR(m): Height from impact point of the jets (with another jet or wall) with respect to the point where the air
velocity and temperature are to be determined (generally the occupied area). Q(m3/h ó l/s): Supply air flow. AK(m2): Effective area. VX(m/s): Velocity of the jets at throw X. VH(m/s): Velocity of the jets in the occupied area. VK(m/s): Effective supply velocity. VHR(m/s): Velocity of the jets at a distance, HR, below the impact point of the jets (with another jet or wall). ∆TO(°C): Temperature difference between the supply jets and room air. ∆TX(°C): Temperature difference between the jets (for throw X) and room air. ∆Th(°C): Temperature difference between the jets (in occupied area) and room air. qx/qo: Induction rate. Quotient between the air flow for a throw X and the air flow supplied in the zone. Ymax(m): Maximum throw with vertical supply of hot air (Vx=0 m/s). ∆Pt(Pa): Total pressure drop. LwA[dB(A)]: Sound power level.
16 DF-89
THIS CATALOGUE IS INTELLECTUAL PROPERTY. Reproduction, either partial or total, by any means, including electronic, is prohibited without prior written authorisation from KOOLAIR, S.L.
CEN-DF-89-0815-00
DF-89 17
KOOLAIR, S.L.
Calle Urano, 26Poligono industrial nº 2 – La Fuensanta 28936 Móstoles - Madrid - (España) Tel: +34 91 645 00 33Fax: +34 91 645 69 62e-mail: [email protected]
www.koolair.com
series
Variable geometry diffusers
www.koolair.com
DGV
Series DGV 1
CONTENTS DGV variable geometry diffuser 2 General information 3 Quick selection charts 5 Selection example 6 Selection charts 11
DF-48 DF-89
1
2 Series DGV
DGV variable geometry diffuser
MODEL Ø C F250 249 440315 314 440400 399 440500 499 440630 629 580
DIMENSIONS IN mm.
Description DGV round, variable-geometry diffuser constructed of steel plate. The standard finish is RAL 9010 white paint. By special order, the diffuser can be painted in any RAL colour. Operation The DGV diffuser is composed of two concentric modules. The inner module is moveable, and can be moved manually or by a servo drive. This sliding inner module was designed such that, when moved, it simply and efficiently changes the direction of the outlet airflow. The flow direction may be horizontal (for cold air) or vertical (for hot air) as well as any intermediate position, allowing the operation to be precisely adjusted to meet the necessary requirements. Applications The DGV variable-geometry diffusers are perfectly adaptable to industrial applications as well as areas requiring more comfortable conditions, and can be installed at heights of up to 15 metres (in drop and suspended ceilings). The variation in the air direction for cold or hot air (either manually or automatically with a servo drive or thermoadjustable) makes these units particularly suitable for the air conditioning of large spaces such as large vestibules, sport centres, industrial warehouses, airports, entertainment areas, etc. Dimensions and operation The attached table lists the overall dimensions of the diffusers. The overall dimensions of diffuser-plenum box assembly are also shown on page 4. Identification The code allows the various sizes and models of the DGV diffusers to be identified. The servo drive can be accessed through the diffuser, preventing the need for access through the drop ceiling. The plenum boxes contains several suspension tabs. By special order, the plenum boxes contain internal insulation.
Round, variable-geometry diffuser series.
With plenum box plus manual. Without plenum box.
With motor-driven operation. Thermoadjustable.
From 250 to 630, according to table.
DGV
P -
MT TR
Size
Series DGV 3
General information
- The DGV-type diffusers have a variable geometry and were designed to meet the air conditioning needs of areas which, depending on the thermal loads during the various seasons of the year, require cold or hot isothermal air. By changing the positioning of an internal device, the direction of the outlet airflow is changed, thereby achieving a horizontal or vertical throw, as well as adjustment within several intermediate positions. - The DGV-type diffuser was designed by the Research & Development Department of KOOLAIR, S.A., and tested and calibrated in our own Distribution and Acoustic Laboratory, which is equipped with the most advanced control and measurement systems. The most advanced theories on air diffusion in rooms have been used in its application, based on experiments and studies performed at the KOOLAIR laboratory in Spain.
Operating recommendations
Heating mode
Cooling mode
HOT AIR (ΔT>O) (central core in high position)
ISOTHERMAL AIR (ΔT=O) (central core in middle position)
COLD AIR (ΔT<O) (central core in low position)
Photographs of DGV diffuser tests in the R&D Laboratory of KOOLAIR S.A.
Plenum box for "DGV" diffuser (dimensions)
MOD. A E Ø D Ø C F G
250 255 320 250 250 480 800315 320 385 315 315 480 865400 405 425 355 400 495 920500 505 470 400 500 495 965630 635 570 500 630 635 1205
DIMENSIONS IN mm
4 Series DGV
Series DGV 5
Selection
1) DGV quick selection chart
2) DGV noise level and pressure drop chart
Selection in a sample project
Symbols • Hdif = Distance from the supply mouth of the diffuser to the floor. • Hzo = Height of occupied area. • A = Distance between diffuser axes. • Q = Air flow in each diffuser. • Ti = Air supply temperature. • Tr = Room temperature. • ∆T = Difference between supply and room temperature. • Lw = Sound power. • P = Pressure drop. • Vz = Maximum velocity in occupied area.
Conditions • Hdif = 6.0 m • Hzo = 1.8 m • A = 5m • Q = 800m3/h • Ti = 35°C • ∆T = 15°C • Tr = 20°C • Lw < 40 dB (A) • P < 30 Pa • Vz = 0.25 m/s The above data are used for the selection, following the steps indicated below:
6 Series DGV
Series DGV 7
Step 1. Quick selection tips for the model Based on the flow rate and the distance, Hdiff, from the diffuser supply outlet to the floor, the 250 or 315 models can be chosen.
Step 2. Verification by noise level and pressure drop. The data are obtained from the flow rate and the diffuser model.
Comparison Thus, the charts indicate that the selected diffuser is DGV 315. Step 3. Determination of the temperature correction factor (Cy). It is necessary to know if the diffuser throw is within the operating limits. The next step (nº4) , is used to determine if the diffuser (in terms of throw) meets the needs required. This is determined by the temperature differenc ∆T (°C) and the maximum velocity in the occupied area. Vz (m/s), both specified in the conditions of the selection in the sample project.
In this case, the factor «Cy» = 0,8 Step 4. Verification of throw within the operating limits. «Ac», is obtained from the following equation: Ac = [(Hdif - Hzo) / Cy ]+ Hzo Ac = [(6 - 1,8) / 0,8 ]+ 1,8 = 7,05 m
8 Series DGV
Once the value of «Ac», is determined, the following figure shows that the diffuser is within the operating limits (within the minimum and maximum lines). Likewise, it allows us to find the stroke (in mm) of the servo motor shaft that will keep the central core fixed at a convenient height, in order to ensure the performance for which it has been selected.
Step 5. Determination of the correction factor to calculate the minimum distance between diffusers. This factor is known as Ca. and is obtained from the following chart, using the air flow per diffuser (Q m3/h) and the maximum velocity in the occupied area (Vz m/s).
Series DGV 9
Where the factor Ca = 3.8 from the following equation, yielding the following minimum distance, A, between diffusers: A = Ca / (Hdif - H zo) A = 3,8 / (6 - 1,8) A = 0,9 m As in the selection example, the projected distance between diffusers, A, is 5 m and the minimum distance recommended by the chart is 0.9 m. Therefore, the selection is correct. Conclusion Diffuser selected: DGV-315 Air flow rate: 800 m3/h Pressure loss: 24 Pa Sound power: 38 dB (A) Temperature difference ∆T: 15°C Maximum velocity in occupied area: 0,25 m/s. Stroke of the electrical servo drive: 50 mm.
10 Series DGV
Selection charts to determine the factor, Ac (operating limits)
Series DGV 11
12 Series DGV
Where Ac is the vertical throw over the floor. The stroke (in mm) of the diffuser disc required to obtain the specified throw is shown on the curves. The minimum and maximum values are the limits between which the throw can be changed.
Series DGV 13
Selection charts to determine the factor, Ca (minimum distance between diffusers)
14 Series DGV
Series DGV 15
Motor-driven operation The motor-driven operation system should be determined for each specific case. Please contact our Technical Department to carry out the respective study.
16 Series DGV
THIS CATALOGUE IS INTELLECTUAL PROPERTY. Reproduction, either partial or total, by any means, including electronic, is prohibited without prior written authorisation from KOOLAIR, S.L.
CEN-DGV-0815-00
Series DGV 17
KOOLAIR, S.L.
Calle Urano, 26Poligono industrial nº 2 – La Fuensanta 28936 Móstoles - Madrid - (España) Tel: +34 91 645 00 33Fax: +34 91 645 69 62e-mail: [email protected]
www.koolair.com
series
Variable geometrydiffusers
www.koolair.com
DVP
21
DV
O
MM Con MM Para
MM
Series DVP 1
CONTENTS Adjustable blade variable geometry diffuser DVP 2 Quick selection table 4 Selection graphs 6
DF-47
2 Series DVP
Adjustable blade variable geometry diffuser DVP
Description The adjustable blade variable geometry diffuser Model DVP provides an optimum discharge in cooling (horizontal discharge) and heating (vertical discharge) enabling the diffuser to meet the required comfort criteria .by moving its blades The diffuser is available in 9 sizes ranging from Ø160 mm to Ø 800 mm in manually version and 6 sizes from Ø250 mm to Ø630 mm either motorised or thermo-adjustable versions Operation The adjustable blade variable geometry diffuser allows the air discharge horizontal, inclined and vertical by moving its blades. This movement can be carried out manually, by an electric motor or by a thermal element which positions the blades depending on the supply air temperature Application DVP diffusers should ideally be mounted at heights in excess of 3.5 m for supplying cooled, isothermal and heated air. This diffuser is an ideal choice for high ceilings applications in areas such as airports, factories and public buildings due to its high aesthetic appeal, ease of installation, regulation, and high air volume capacity Dimensions DVP is available in 9 sizes which are shows on page 63, both overall dimensions as the set of plenum plus diffuser. There are three models, DVP, movement of blades manually, DVP-TR self-adjusting blade moving through the a thermal element, and movement by electric motor, DVP-M. Finishes The outer ring and the blades are made of steel sheet. Standard finish - painted RAL 9010, other colours are available upon request. Plenum boxes to suit are also available. Identification The code allows the various sizes and models of the DVP diffusers to be identified. The thermo-adjustable and motorised versions are from Ø 250 mm to Ø800 mm sizes. The servo drive can be accessed through the duct. The plenum boxes contain several suspension tabs. By special order, the plenum boxes can be supplied with internal insulation.
Round, variable-geometry diffuser series.
With plenum box plus manual f. Without plenum box. With manual operation. Actuator P / N 24V optional 230V (160 to 315 mm) Actuator P / N 24V optional 230V (355 to 630 mm) Proportional (0-10V) 24V (160 to 315 mm) Proportional (0-10V) 24V (355 to 630 mm) Thermoadjustable. From 160 to 800, according to table.
DVP
P -
TR
Size
- M-CM24 M-LM24
M-CM24-SX M-LM24A-MF
Series DVP 3
Dimesions
The DVP-type diffusers have a variable geometry and were designed to meet the air conditioning needs of areas which, depending on the thermal loads during the various seasons of the year, require cold or hot isothermal air. By changing the positioning of its blades, the direction of the outlet airflow is changed, thereby achieving a horizontal or vertical throw, as well as adjustment within several intermediate positions. - The DVP-type diffuser was designed by the Research & Development Department of KOOLAIR, S.A., and tested and calibrated in our own Distribution and Acoustic Laboratory, which is equipped with the most advanced control and measurement systems. The most advanced theories on air diffusion in rooms have been used in its application, based on experiments and studies performed at the KOOLAIR laboratory in Spain. Here are three versions available of the diffuser, DVP (manual movement of blades), DVP-M (movement of the blades by electric motor) and DVP-TR (movement of the blades through the action of a thermal element).
DVP
DVP-TR
4 Series DVP
Quick selection table horizontal discharge
Legend -Q (m3/h): Air flow. -Vc (m/s): Neck velocity. -X (m): Throw for a maximun velocity of 0,25 m/s at the occupied zone. -∆Pt (Pa): Pressure drop. -LwA [dB(A)]: Sound power level.
Blade position for horizontal air discharge at 30º.
m3/h l/s
150 41,7 2,1 1,3 0,9
150 41,7 1,2 1,0 1,0
32 13 5
31 19 <15
200 55,6 2,8 1,8 1,1 0,7
200 55,6 1,6 1,4 1,3 1,0
58 23 9 4
39 27 16 <15
250 69,4 3,5 2,2 1,4 0,9 0,7 0,6
250 69,4 2,1 1,7 1,6 1,3 1,2 1,2
90 36 14 6 4 3
46 34 22 <15 <15 <15
300 83,3 4,2 2,7 1,7 1,1 0,8 0,7
300 83,3 2,5 2,1 1,9 1,5 1,4 1,4
130 51 20 9 6 4
51 39 28 <15 <15 <15
400 111,1 3,6 2,3 1,4 1,1 0,9 0,6
400 111,1 2,8 2,5 2,0 1,9 1,9 1,5
91 36 16 10 7 3
48 36 19 15 <15 <15
500 138,9 4,5 2,9 1,8 1,4 1,1 0,7
500 138,9 3,4 3,2 2,5 2,3 2,3 1,8
143 56 25 16 11 4
54 43 26 22 19 <15
750 208,3 4,3 2,7 2,1 1,7 1,1 0,7
750 208,3 4,8 3,8 3,5 3,5 2,8 1,9
127 56 36 24 9 4
55 39 35 31 20 <15
1.000 277,8 3,6 2,8 2,2 1,4 0,9 0,6
1.000 277,8 5,0 4,7 4,6 3,7 2,6 1,9
99 65 42 16 6 3
48 44 40 29 18 <15
1.500 416,7 4,2 3,3 2,1 1,3 0,8
1.500 416,7 7,0 6,9 5,5 3,9 2,8
146 95 36 15 6
57 53 42 31 22
2.000 555,6 2,8 1,8 1,1
2.000 555,6 7,4 5,2 3,8
65 26 11
51 40 31
3.000 833,3 2,7 1,7
3.000 833,3 7,8 5,6
58 25
53 43
4.000 1111,1 2,2
4.000 1111,1 7,5
44
52LWA
X
Vc
X
P t
630 800
Vc
X
250 315 400 500355160Size 200
P t
LWA
Vc
X
Vc
X
Vc
P t
X
Vc
LWA
P t
Q
X
Vc
X
P t
LWA
P t
LWA
P t
LWA
P t
LWA
X
P t
LWA
P t
LWA
Vc
Vc
P t
LWA
LWA
Vc
P t
LWA
Vc
X
X
X
Vc
m3/h l/s
100 27,8 vt = 0 ,3 1,5100 27,8 vt = 0 ,5 0,9100 27,8 vt = 1,0 0,5
5<15
200 55,6 vt = 0 ,3 3,0 2,4200 55,6 vt = 0 ,5 1,8 1,4200 55,6 vt = 1,0 0,9 0,7
19 833 19
300 83,3 vt = 0 ,3 4,5 3,5 2,5 1,6 1,4300 83,3 vt = 0 ,5 2,7 2,1 1,5 1,0 0,9300 83,3 vt = 1,0 1,4 1,1 0,8 0,5 0,4
42 17 10 3 245 31 15 <15 <15
400 111,1 vt = 0 ,3 6,0 4,7 3,4 2,1 1,9400 111,1 vt = 0 ,5 3,6 2,8 2,0 1,3 1,1400 111,1 vt = 1,0 1,8 1,4 1,0 0,6 0,6
75 31 17 5 354 40 25 <15 <15
500 138,9 vt = 0 ,3 5,9 4,2 2,7 2,4 1,6 1,2500 138,9 vt = 0 ,5 3,5 2,5 1,6 1,4 1,0 0,7500 138,9 vt = 1,0 1,8 1,3 0,8 0,7 0,5 0,3
48 27 8 5 3 147 32 16 <15 <15 <15
600 166,7 vt = 0 ,3 5,0 3,2 2,8 2,0 1,4600 166,7 vt = 0 ,5 3,0 1,9 1,7 1,2 0,8600 166,7 vt = 1,0 1,5 1,0 0,9 0,6 0,4
39 12 7 5 237 22 17 <15 <15
800 222,2 vt = 0 ,3 6,7 4,3 3,8 2,6 1,8 1,3800 222,2 vt = 0 ,5 4,0 2,6 2,3 1,6 1,1 0,8800 222,2 vt = 1,0 2,0 1,3 1,1 0,8 0,6 0,4
69 21 13 8 3 146 31 26 20 <15 <15
1.000 277,8 vt = 0 ,3 8,4 5,3 4,7 3,3 2,3 1,71.000 277,8 vt = 0 ,5 5,0 3,2 2,8 2,0 1,4 1,0
1.000 277,8 vt = 1,0 2,5 1,6 1,4 1,0 0,7 0,5108 33 21 13 4 153 38 33 27 <15 <15
2.000 555,6 vt = 0 ,3 10,6 9,4 6,5 4,6 3,3 2,42.000 555,6 vt = 0 ,5 6,4 5,7 3,9 2,8 2,0 1,4
2.000 555,6 vt = 1,0 3,2 2,8 2,0 1,4 1,0 0,7134 83 50 18 6 259 54 49 35 21 <15
3.000 833,3 vt = 0 ,3 9,8 6,9 5,0 3,53.000 833,3 vt = 0 ,5 5,9 4,1 3,0 2,1
3.000 833,3 vt = 1,0 2,9 2,1 1,5 1,1113 40 13 461 47 33 19
4.000 1111,1 vt = 0 ,3 9,2 6,6 4,74.000 1111,1 vt = 0 ,5 5,5 4,0 2,8
4.000 1111,1 vt = 1,0 2,8 2,0 1,471 23 756 42 28
5.000 1388,9 vt = 0 ,3 8,3 5,95.000 1388,9 vt = 0 ,5 5,0 3,5
5.000 1388,9 vt = 1,0 2,5 1,836 1149 34
6.000 1666,7 vt = 0 ,3 10,0 7,16.000 1666,7 vt = 0 ,5 6,0 4,2
6.000 1666,7 vt = 1,0 3,0 2,152 1655 40
8.000 2222,2 vt = 0 ,3 9,4
8.000 2222,2 vt = 0 ,5 5,6
8.000 2222,2 vt = 1,0 2,8
28
49
10.000 2777,8 vt = 0 ,3 11,8
10.000 2777,8 vt = 0 ,5 7,1
10.000 2777,8 vt = 1,0 3,5
44
56
800250 315 400 500355Size 160 200 630
X
Pt
LWA
X
Pt
LWA
Q
LWA
X
Pt
X
Pt
LWA
X
X
X
X
X
Pt
LWA
X
X
Pt
LWA
Pt
LWA
Pt
LWA
Pt
LWA
Pt
LWA
X
X
Pt
LWA
X
Pt
LWA
LWA
Pt
Pt
LWA
X
Pt
LWA
Series DVP 5
Quick selection table vertical discharge
Blade position for vertical air discharge at 90º.
Legend -Q (m3/h): Air flow. -Vc (m/s): Neck velocity. -X (m): Throw for a maximun velocity of 0,25 m/s at the occupied zone. -∆Pt (Pa): Pressure drop. -LwA [dB(A)]: Sound power level.
6 Series DVP
Noise level selection graphs
1
10
100
100 1000 10000
Pt [
Pa
]
Q [m3/h]
DVP HORIZONTALNoise and pressure drop
45
15
20
30
25
35
40
50
LWA [dB(A)]
160 200 800250 630400 500315
1
10
100
100 1000 10000
P
t [P
a]
Q [m3/h]
DVP VERTICALNoise and pressure drop
45
15
20
30
25
35
40
LWA [dB(A)]
160 200
800
250 630400 500315
55
THIS CATALOGUE IS INTELLECTUAL PROPERTY. Reproduction, either partial or total, by any means, including electronic, is prohibited without prior written authorisation from KOOLAIR, S.L.
CEN-DVP-0815-00
Series DVP 7
KOOLAIR, S.L.
Calle Urano, 26Poligono industrial nº 2 – La Fuensanta 28936 Móstoles - Madrid - (España) Tel: +34 91 645 00 33Fax: +34 91 645 69 62e-mail: [email protected]
www.koolair.com
series
MULTINOZZLES
Multinozzles diffusers
www.koolair.com
3Multinozzle Diffuser
Multinozzle Diffusers DF49MT3
TABLE OF CONTENTS Page
Multinozzle Diffuser DF49MT3 __________________________________ 4Types and sizes _____________________________________________ 5Key to symbols ______________________________________________ 9Technical data_______________________________________________ 10Example of selection _________________________________________ 18Coding ____________________________________________________ 19
4 Multinozzle Diffuser
INTRODUCTION
Due to the growing demand in the market for buildinglarge spaces in hotels, shopping malls, theatres, etc., wehave developed a diffuser which is able to combine designand efficiency.
The long range offered by the DF49MT3 multinozzlediffusers coupled with their low noise level and their aestheticsmake this diffuser a benchmark in the current marketplace.
DESCRIPTION
The long-range multinozzle diffusers of the DF49MT3series comprise a rectangular faceplate in steel sheet where3 to 10 nozzles can be incorporated per row in a maximumof 3 rows in a standard execution. The nozzles aremanufactured in ABS, class V1 material, according to UL 94standars.
There are several types of construction; on a platewithout a frame or on a plate with a frame, which can bemounted on both the wall and the ceiling .
There is also a model which can be adapted to differentduct diameters for a maximum of 2 rows of nozzles in astandard execution.
These diffusers can be finished in black (Ral 9005) orin white (Ral 9010).
The diffuser can be fixed by using either screws or amounting frame. If you decide to fix it to the wall or a plasterceiling with screws, it is also advisable to use a mountingframe so that the plaster is not damaged.
APPLICATIONS
The multinozzle diffusers of the DF49MT3 series allowlong ranges of air to be obtained with a low noise level. Theyare designed to air-condition shopping-malls, museums,theatres, cinemas, large halls, etc.
The shape of the nozzles allows them to be pointedseparately, in all directions, up to a maximum of 30O.
All the different models can have a removable plenumfitted.
Multinozzle diffuser DF49MT3
5Multinozzle Diffuser
DF49MT3 SB (Without frame)
SIZES
106 87 9NOZZLES 3 4 5
L 325 425 525 625 725 825 925 1025
A 353 453 553 653 753 853 953 1053
ROWS H B
3 325 353
1 125 153
2 225 253
6 Multinozzle Diffuser
SIZES
DF49MT3 CB (With frame)
NOZZLES 3 4 5 6 7 8 9 10
L 325 425 525 625 725 825 925 1025
A 353 453 553 653 753 853 953 1053
ROWS H B
1 125 153
2 225 253
3 325 353
7Multinozzle Diffuser
SIZES
DF49MT3 E (Plaster)
NOZZLES 3 4 5
925 1025
6 7 8 9
460 560
10
L 325 425 525 625 725 825
1060660 760 860 960C 360
ROWS H D
3 325 360
1 125 160
2 225 260
8 Multinozzle Diffuser
DF49MT3 CC (Circular duct)
SIZES
NOZZLES 3 4 5 6 7 8 9 10
L 325 425 525 625 725 825 925 1025
A 355 455 555 1055655 755 855 955
2 225 253
ROWS H B
1 125 153
43
Ø315 Ø900
Ø630 Ø1400
DUCT
G
34
MINIMUM MAXIMUM
9Multinozzle Diffuser
Key to symbolsl (m) Distance travelled from the equipment to the impact point of the air jet (with another air jet or the wall)
in isothermal conditions.αααααX (
O) Discharge angle.L (m) Horizontal distance from the equipment to the impact point of the air jet (with another air jet or the
wall).X (m) Air jet range.Y (m) Deviation in the air jet caused by the difference in temperature between the supplied air and the
environment.H (m) Equipment location height.HH (m) Height of habitability area.HC (m) Height from the impact point of the air jet (with another air jet or the wall) in isothermal conditions in
respect of the location of the equipment.HI (m) Height from the impact point of the air jet (with another air jet or the wall) in isothermal conditions.HR (m) Height from the impact point of the air jet (with another air jet or the wall) in respect of the point at
which we want to know the air speed and temperature (generally in the habitability area).Q (m3/h o l/s) Air flow.AK (m2) Effective supply area.VX (m/s) Speed of the corresponding air jet to range X.VH (m/s) Speed on the air jet in the habitability area.VK (m/s) Effective supply speed.VHR (m/s) Speed of the air jet to a distance H
R below the impact point of the air jet (with another air jet or the
wall).ΔΔΔΔΔTO (oC) Difference in temperature between the air jet being supplied and the enclosure to be air conditioned.ΔΔΔΔΔTX (
oC) Difference in temperature between the air jet (for range X) and the enclosure to be air conditioned.ΔΔΔΔΔTh (
oC) Difference in temperature between the air jet (in the habitability area) and the enclosure to be airconditioned.
qX / qO Induction rate. Quotient between the air jet volume for range X and the air volume supplied in theenclosure
ΔΔΔΔΔPest (Pa) Pressure drop.LWA dB(A) Sound power.X0,3 - X0,5 - X1,0 Range. For end air speed of 0,3, 0,5 y 1,0 m/s
10 Multinozzle Diffuser
Selection tableBy using the quick selection table, we can obtain data on range, pressure drop and sound power in isothermal
conditions and for different end speeds.The data are for different lengths and for one row of nozzles. For a larger number of nozzles, apply the constants
on the table.
Table of correction quotients for noise output (FL) and range (F
X), static pressure does not have to be corrected.
Size(m3/h) (l/s) Ak (m2)120 33,3 X0,3 X0,5 X1,0 (m) 9,5 5,7 2,8
Vk (m/s)
∆Pest (Pa)
LwA - dB(A)
150 41,7 X0,3 X0,5 X1,0 (m) 11,8 7,1 3,5
Vk (m/s)
∆Pest (Pa)
LwA - dB(A)
200 55,6 X0,3 X0,5 X1,0 (m) 15,8 9,5 4,7 12,2 7,3 3,7 11,2 6,7 3,3
Vk (m/s)
∆Pest (Pa)
LwA - dB(A)
250 69,4 X0,3 X0,5 X1,0 (m) 19,7 11,8 5,9 15,3 9,2 4,6 13,9 8,4 4,2 12,1 7,2 3,6
Vk (m/s)
∆Pest (Pa)
LwA - dB(A)
300 83,3 X0,3 X0,5 X1,0 (m) 23,7 14,2 7,1 18,3 11,0 5,5 16,7 10,0 5,0 14,5 8,7 4,3
Vk (m/s)
∆Pest (Pa)
LwA - dB(A)
350 97,2 X0,3 X0,5 X1,0 (m) 27,6 16,6 8,3 21,4 12,8 6,4 19,5 11,7 5,9 16,9 10,1 5,1 15,1 9,1 4,5
Vk (m/s)
∆Pest (Pa)
LwA - dB(A)
400 111,1 X0,3 X0,5 X1,0 (m) 24,4 14,7 7,3 22,3 13,4 6,7 19,3 11,6 5,8 17,3 10,4 5,2
Vk (m/s)
∆Pest (Pa)
LwA - dB(A)
500 138,9 X0,3 X0,5 X1,0 (m) >30 18,3 9,2 27,9 16,7 8,4 24,1 14,5 7,2 21,6 13,0 6,5
Vk (m/s)
Pest (Pa)
LwA - dB(A)
600 166,7 X0,3 X0,5 X1,0 (m) >30 22,0 11,0 >30 20,1 10,0 29,0 17,4 8,7 25,9 15,6 7,8
Vk (m/s)
∆Pest (Pa)
LwA - dB(A)
700 194,4 X0,3 X0,5 X1,0 (m) >30 23,4 11,7 >30 20,3 10,1 >30 18,1 9,1
Vk (m/s)
∆Pest (Pa)
LwA - dB(A)
800 222,2 X0,3 X0,5 X1,0 (m) >30 23,2 11,6 >30 20,7 10,4
Vk (m/s)
∆Pest (Pa)
LwA - dB(A)
1000 277,8 X0,3 X0,5 X1,0 (m) >30 25,9 13,0
Vk (m/s)
∆Pest (Pa)
LwA - dB(A)
Q
0,003770 0,006283 0,007540
3 5 6 8
<20
47 27
22
30
46
174
38
20
40
272
44
391
39
153
49
25,8
272
49
272 189 106
370 208
34
45
11,1
35
6898
2631
<20
37
<20
43
26
<20
22,1 13,3
189 68
121 43
18,4
31
11,1 9,2 6,9
10
23
MULTINOZZLE DIFFUSER DF49MT3 QUICK SELECTION TABLE1 ROW
68
0,010053 0,012566
8,8
<20
7,7
33
98
34
38
43
68
29
23
133
13,3
47
174
272
41
22,1
13,8
370 133 92 52
24
121 68
31
46
14,7 8,8 7,4
11,1 8,3
42
272 38
8,8
25,8 15,5 12,9 9,7
11,1
17,7 14,7 11,1
34 28
22,1 18,4
26,5 22,1 16,6
19,3 15,5
22,1 17,7
43
Nº Rows 1 2 3FX 1 1,414 1,732FL 0 3 4,8
XTOTAL = XTABLE x FX
LWTOTAL = LWTABLE + FL
11Multinozzle Diffuser
The graphs which are shown bellow all correspond to 1 row of nozzles. If you would like to make a study of 2 or 3rows, you must choose the air flow volume corresponding to 1 row and then apply the correction quotients which appearon the respective tables which are shown with the graphs.
For example, if we have an air flow volume of 1000 m3/h and we want to install a 2-row multinozzle diffuser, on thegraph we must select an air flow volume of 500 m3/h (the volume which would correspond to one row) and apply thecorresponding correction quotient, in this case 3, fron which we can deduce that the noise output would be 36,8 dB(A).
Table of correction quotients for noise output (FL), the static pressure does not have to be corrected:
Graph 1. Noise output
Selection Graphs
Nº of Rows 1 2 3FL 0 3 4,8Fp 1 1 1
LWTOTAL = LWGRAPH + FL
20
80
140
200
260
320
380
0 200 400 600 800 1000Qrow [m3/h]
Pest
[Pa]
20
30
35
40
45
Nº of nozzles per row
9
10
50
83 4 5 6 7
106
500
33.8L
WA[dB(A)]
12 Multinozzle Diffuser
Graph 2. Maximum vertical penetration
Correction quotient table
Nº of rows 1 2 3Fy 1 1,189 1,316
(YMÁX)TOTAL = (YMÁX)GRAPH x Fy
100
200
300
400
500
600
700
800
900
1000
2 5 8 11 14 17
Qro
w (m
3 /h)
9
10
3
4
5
6
7
8
Nº of nozzles per row
2
4
6
8
10
12
14
16
2 5 8 11 14 17
Y max
(m)
2 4 6 8 10 12 16
20
T (K)
9,15
ΔΔΔΔΔT (K)
13Multinozzle Diffuser
Graph 3. Speed of the air jet within the range
Correction quotient table
100
200
300
400
500
600
700
800
900
1000
1100
1200
1,5 4,3 7,1 9,9 12,7 15,5
Qro
w (m
3 /h)
910
3
4
5
678
Nºof
noz
zles
per
row
0,1
1
10
1,5 4,3 7,1 9,9 12,7 15,5
V (m
/s)
5 68101215202530
X (m)
0,2
0,4
0,60,8
2
4
68
0,48
Nº of rows 1 2 3Fv 1 1,414 1,732
VTOTAL = VGRAPH x Fv
14 Multinozzle Diffuser
Graph 4. Vertical deviation of the air jet
Correction quotient table
100
1000
Qro
w (m
3 /h)
200
800
600
400
300
10987
65
500
43Nº of nozzles
T (K) 1210 86
16
42
20
0,01 0,10 1,00 10,00y (m)
X (m
)
30
56
8
10
1215
20
25
2,6
Nº of rows 1 2 3Fd 1 0,707 0,577
Y TOTAL = Y GRAPH x Fd
15Multinozzle Diffuser
0,01
0,10
1,00
0,2 0,4 0,6 0,8 1 1,2 1,4 1,6 1,8 2
Vx (m/s)
V HR (m
/s)
1,5
0,20
0,30
0,50
0,70
0,03
0,05
0,07
2
34568
10
15
0,15
HR (m)
1,6
0,48
Graph 5. Relationship between air flow speeds
16 Multinozzle Diffuser
Graph 6. Induction rate
Correction quotient table
Nº of rows 1 2 3Fq 1 0,707 0,577
(qx/q0)TOTAL = (qx/q0)GRAPH x Fq
10
20
30
40
50
60
70
80
90
100
110
120
130
140
150
160
170
180
190
2 6 10 14 18 22 26 30
X (m)
qx /q
0
Nº of nozzles per row
3
109
8
7
6
5
4
63.3
16.6
17Multinozzle Diffuser
Graph 7. Temperature quotient
Correction quotient table
Nº of rows 1 2 3FT 1 1,414 1,732
(Tx/T0)TOTAL = (Tx/T0)GRAPH x FT
0,01
0,10
2 6 10 14 18 22 26 30
X (m)
TX/
T O
3
0,024
0,04
0,05
0,06
0,09
0,08
0,07
0,03
0,02
45
6
78910
16,6
ΔΔΔΔ ΔTx
/ Δ
/ Δ / Δ
/ Δ
/ Δ
To
18 Multinozzle Diffuser
Example of selection
Input data:
L = 15 mH = 6 m (Height of location above the floor)Q
MULTINOZZLE =
500 m3/h
Supply temperature = 19 OCAmbient temperature = 25 OCΔT
O = - 6 OC
HH = 1,8 m (Height of the habitability area)
We must make a selection in order to obtain:
- A maximum speed in the habitability area of 0,2 m/s.- The vertical temperature gradient must not exceed 3 OC.- The noise output level must not exceed 35 dB(A).
Selection:
With the air flow volume we have and on the basis of the noise output limit, on the quick selection table we obtain amultinozzle diffuser of 1 row with 8 nozzles per row.
With graph 1, showing load loss and noise output level, we obtain:
ΔPEst
= 106 Pa (Load loss)L
WA = 33,8 dB(A) (Noise output level)
In graph 3 showing the speed of the air jet in the range, we take a discharge angle α = 0O, and thus we have:The range will be I = L/cos 0O = 15/1 = 15 m
looking at the graph, the speed corresponding to this range is VX = 0,48 m/s
Due to the thermal step (we are supplying cold air), a deviation in the air jet occurs. Looking at graph 4, the impactpoint in isothermal conditions would be:
H + HC = H + (L x tan 0O) = 6 + (15 x 0) = 6 m
Fron the graph, we also get that for a ΔTO
= - 6 OC, a range of 15 m and a volume of Q = 500 m3/h, the verticaldeviation for being a non-isothermal air jet is Y = 2,6 m
Therefore, the air jet impact point occurs at a height above the floor of: 6 - 2,6 = 3,4 m
On the air flow speed graph, (graph 5), for a height of HR = 3,4 - 1,8 = 1,6 m, using V
X = 0,48 m/s, our result is that
the speed in the habitability area will be VHR
= VH = 0,15 m/s.
Graph 6 or the induction graph gives us, for a range of I + HR = 15 + 1,6 = 16,6, un qX/q
O = 63,3
Using graph 7 or the temperature quotient graph, we can see that ΔTX / ΔT
O = 0,026, therefore, the temperature of the
air jet on entering the habitability area will be:
ΔTX = T
X - T
AMBIENT
TX = T
AMBIENT + ΔT
X = 25 + [ 0,026 x (- 6) ] = 24,84 OC
19Multinozzle Diffuser
Coding. ExampleThe coding describes the model ordered by the customer.
DF49MT3 SB Multinozzle without frame
CB With frame
CC For circular duct
E For ceiling or plaster wall
MM With mounting frame
T With screw holes
1...3 Nº of rows
3...10 Nº of nozzles per row
Ral Diffuser finish
Example of coding:
DF49MT3 - CB - 1 - 05 - Ral 9005
Long-range multinozzle diffuser, withframe, with 1 row and 5 nozzles per row,painted in Ral 9005
20 Multinozzle Diffuser
CATALOGUE Nº 1007
KOOLAIR, S.L.
Calle Urano, 26Poligono industrial nº 2 – La Fuensanta 28936 Móstoles - Madrid - (España) Tel: +34 91 645 00 33Fax: +34 91 645 69 62e-mail: [email protected]
www.koolair.com
series
Linear nozzles with a medium-to-long throw
www.koolair.com
DF-47NARROW
DF-47-NARROW
TABLE OF CONTENTS
Introduction DF-47-NARROW 2Dimensions DF-47-NARROW 3Types and connection system DF-47-NARROW 5Mounting DF-47-NARROW 6Introduction DF-47-NARROW-LT 7Dimensions DF-47-NARROW-LT 8Connection system and mounting DF-47-NARROW-LT 9Selection table 10Product codes 12
1
DF-47-NARROW
DF-47-NARROW (-S) high induction linear diffuser for medium-to-long throw
DescriptionHigh induction linear diffuser for medium-to-long throw, DF-47-Narrow model, with length L mm and slot H mm for air flow.Allows ±30º vertical turn of core (linear nozzle), due to a narrow slot that makes it possible to cover medium and long throws, achieving comfort with both cooling and heating and providing an excellent aesthetics.They are suitable for both ceiling and wall installation. Particularly appropriate for variable air volume, although the design allows excellent operation with constant air volume as well.
ApplicationThese medium-to-long throw diffusers are very appropriate in cases that require a long-distance air jet or a medium-distance air jet with low sound levels.They are especially indicated for commercial facilities, mezzanines, shops, residences, etc.This diffuser is suitable for both supply and return. High-quality aesthetics and performance are further enhanced by alternating the return diffusers with supply diffusers in the same continuous line.
FinishesManufactured entirely of extruded aluminium sections.The unit can include a directional (29-O), directional blades (G) (not available in slot size 15) volume control damper and plenum box of galvanized steel sheet (internally insulated (-PFA) or uninsulated (-PF)). There are two types of plenum box: fixed or detachable.If a plenum box is included, a volume control damper can be included in the connection inlet, annulling the 29-O damper.
In the DF-47-Narrow-IC and DF-47-Narrow-CC models, the frame or duct is constructed of galvanized steel and the diffuser is made of aluminium.
Standard finish in anodized or painted in RAL-9010 glossy white.
Operating mechanisms and mountingThe mounting systems available for the diffuser element are shown in detail on page 5.The diffuser is specified by the slot length and slot width. The -MT motor-driven mechanism moves the nozzle in the vertical direction (up and down) at an angle of approximately ± 30°. The required motorization is provided by one motor per diffuser, even in groups containing several units. Thermal self-adjustment is also possible.
2
H H1 H2 HD
15 85 100 60
20 90 105 61
30 100 115 63
40 110 125 65
50 120 135 67
H H1 H2 H3 ØD HP HT
15 85 100 110 Ø158 233 285
20 90 105 115 Ø198 273 325
30 100 115 125 Ø248 323 375
40 110 125190 Ø313
(OVAL) 273 32550 120 135
H H1 H2 H3 ØD HP HT
15 87 100 112 Ø158 235 291
20 92 105 117 Ø198 275 331
30 102 115 127 Ø248 325 381
40 112 125192 Ø313
(OVAL) 275 33150 122 135
DF-47-NARROW
Dimensions
DF-47-NARROW
L = NOMINAL LENGTH (OUTLET)H1 = NOMINAL HEIGHT (OUTLET)LT = NOMINAL + 15
DF-47-NARROW FIXED PLENUM
L > 1001: 2 DISCHARGESLT = N +15LP = N - 33L = NOMINAL LENGTH (OUTLET)) H1 = NOMINAL HEIGHT (OUTLET)
DF-47-NARROW PLENUM DETACHABLE
L > 1001: 2 DISCHARGESLT = N +15LP = N - 3L = NOMINAL LENGTH (OUTLET)) H1 = NOMINAL HEIGHT (OUTLET)
3
H H1 H2 H3 ØD HP HT
15 85 88 110 Ø158 233 283
20 90 93 115 Ø198 273 323
30 100 103 120 Ø248 323 373
40 110 113190 Ø313
(OVAL) 273 32350 120 123
H H1 H2 HD
15 78 88 60
20 83 93 61
30 93 103 63
40 103 113 65
50 113 123 67
A 15 20 30 40 50B
200 85 88 97 107 -113 115 123 130 -
250 84 89 97 106 115113 118 123 133 138
300 84 89 97 106 115113 118 126 133 141
315 83 89 97 106 116113 118 126 136 146
355 83 88 97 107 116113 118 126 136 146
400 83 88 97 107 117113 118 126 136 146
450 83 88 96 106 117114 119 126 136 146
500 83 88 96 106 117114 119 126 136 146
560 83 88 96 106 117114 119 126 136 146
630 83 88 96 104 116114 119 127 135 146
710 83 88 96 104 116114 119 127 135 146
800 83 88 96 104 116114 119 127 135 146
900 83 88 96 104 116114 119 127 135 146
DF-47-NARROW
LT = N +10LP = N - 3
Dimensions
DF-47-NARROW-S PLENUM
DF-47-NARROW-S
NOMINAL =< 1000 (1 SPIGOT)
NOMINAL > 1001 (2 SPIGOTS)
DF-47-NARROW-CCDUCT (CUSTOMER CONDUIT HUB)
DUCT WITH DF-47-NARROW-CC
Ø DUC
T
MODEL C D
500 500 525
600 600 625
700 700 725
800 800 825
900 900 925
1000 1000 1025
1100 1100 1125
1200 1200 1225
LT = NOMINAL + 10
4
DF-47-NARROW-MTDF-47-NARROW-TRDF-47-NARROW
DF-47-NARROW
Types
Connection system
DF-47-NARROW DF-47-NARROW
ALIGNMENT PLATES FOR SECTIONS
For IC and CC the maximum section length is 2 m, not available for formation of continuous lines.
5
DF-47-NARROW
Mounting
DF-47-NARROW + MMWITH MOUNTING FRAME (MM)
DF-47-NARROW-TWITH SCREWS (NOMINAL - 8)
DF-47-NARROW-PMWITH MOUNTING BRIDGE (PM)
DF-47-NARROW-IC INTEGRATED WITH DUCT
DF-47-NARROW-CC ADAPTATION FOR DUCT
6
DF-47-NARROW
Hidden high induction linear diffuser for medium-long throw DF-47-NARROW-LT
DescriptionKoolair hidden high induction linear diffuser for medium-long throw, model DF-47-NARROW-LT: length mm; air flow slot of mm.Characterised by the lack of profile on show. Its narrow slot allows medium and long throw air distribution, providing comfort when supplying either hot or cold air, while having a very pleasing aesthetic appearance.Designed for installation in both ceilings and walls.
UseThese medium-long throw diffusers are perfect for installations which require a jet of air to be supplied over either long or medium distances at low sound levels.They are especially suited to commercial premises, mezzanines, shops, homes, etc.This diffuser can be used for both supply and return air. Installing supply and return diffusers alternately in one continuous line ensures a high level of aesthetics and functionality.
FinishesManufactured entirely of extruded aluminium sections.The unit can include a directional (29-O), directional blades (G) (not available in slot size 15) volume control damper and plenum box of galvanized steel sheet (internally insulated (-PFA) or uninsulated (-PF)). There are two types of plenum box: fixed or detachable.If a plenum box is included, a volume control damper can be included in the connection inlet, annulling the 29-O damper. Standard finish painted in matt RAL-9005.
7
H H1 H2
15 81 136
20 86 141
30 96 151
40 106 161
50 116 171
H H1 H2 H3 ØD HT HP
15 81 136 110 Ø159 227,5 285
20 86 141 115 Ø199 267,5 325
30 96 151 125 Ø249 317,5 375
40 106 161190 Ø314
(OVAL) 267,5 32550 116 171
DF-47-NARROW
Dimensions
DF-47-NARROW-LT
L = NOMINAL LENGTH (OUTLET)H1 = NOMINAL HEIGHT (OUTLET)
DF-47-NARROW-LT FIXED PLENUM
L > 1001: 2 DISCHARGES
L = NOMINAL LENGTH (OUTLET)) H1 = NOMINAL HEIGHT (OUTLET)
SECTION A-A’
NOMINAL
PROFILE FOR CONNECTING SECTIONS AND FIXING TO PLASTERBOARD
8
DF-47-NARROW
Connection system
Mounting
SLIDING PROFILE TO CONNECT SECTIONS
PLASTERBOARD SCREW
FILLING MASTIC 12.5 mm AND 15 mm PLASTERBOARD
PROFILE DEVISED FOR CONNECTING SECTIONS AND FIXING TO PLASTERBOARD
9
Q 15 - 1000 20 - 1000 30 - 1000 40 - 1000 50 - 1000
(m3/h) (l/s) Ak (m2) 0,011 0,014 0,028 0,037 0,047
200 55,6 X0,3 X0,5 X1,0 (m) 6,0 3,6 1,8
∆Pst (Pa) 10
LwA - dB(A) 18
300 83,3 X0,3 X0,5 X1,0 (m) 8,9 5,4 2,7 7,7 4,6 2,3
∆Pst (Pa) 23 12
LwA - dB(A) 25 18
400 111,1 X0,3 X0,5 X1,0 (m) 11,9 7,1 3,6 10,3 6,2 3,1 7,4 4,4 2,2
∆Pst (Pa) 41 21 9
LwA - dB(A) 30 24 19
500 138,9 X0,3 X0,5 X1,0 (m) 14,9 8,9 4,5 12,9 7,7 3,9 9,3 5,6 2,8 8,0 4,8 2,4
∆Pst (Pa) 64 33 15 8
LwA - dB(A) 34 29 25 20
600 166,7 X0,3 X0,5 X1,0 (m) 17,9 10,7 5,4 15,5 9,3 4,6 11,1 6,7 3,3 9,6 5,8 2,9 8,6 5,1 2,6
∆Pst (Pa) 91 48 21 12 8
LwA - dB(A) 37 33 29 24 23
700 194,4 X0,3 X0,5 X1,0 (m) 20,8 12,5 6,2 18,1 10,8 5,4 13,0 7,8 3,9 11,2 6,7 3,4 10,0 6,0 3,0
∆Pst (Pa) 124 65 29 16 11
LwA - dB(A) 40 37 33 28 26
800 222,2 X0,3 X0,5 X1,0 (m) 23,8 14,3 7,1 20,7 12,4 6,2 14,8 8,9 4,4 12,8 7,7 3,8 11,4 6,9 3,4
∆Pst (Pa) 163 85 38 21 14
LwA - dB(A) 42 40 36 31 29
1000 277,8 X0,3 X0,5 X1,0 (m) 25,8 15,5 7,7 18,5 11,1 5,6 16,0 9,6 4,8 14,3 8,6 4,3
∆Pst (Pa) 133 59 33 22
LwA - dB(A) 45 42 37 34
1250 347,2 X0,3 X0,5 X1,0 (m) 23,2 13,9 7,0 20,0 12,0 6,0 17,9 10,7 5,4
∆Pst (Pa) 93 51 34
LwA - dB(A) 48 42 38
1500 416,7 X0,3 X0,5 X1,0 (m) 24,0 14,4 7,2 21,4 12,9 6,4
∆Pst (Pa) 74 49
LwA - dB(A) 46 42
1750 486,1 X0,3 X0,5 X1,0 (m) 28,0 16,8 8,4 25,0 15,0 7,5
∆Pst (Pa) 101 66
LwA - dB(A) 50 45
2000 555,6 X0,3 X0,5 X1,0 (m) 28,6 17,2 8,6
∆Pst (Pa) 87
LwA - dB(A) 48
DF-47-NARROW
Selection table DF-47-NARROW / -LT
X0.3, X0.5 and X1.0 Horizontal throw of air jet for a mean end velocity of 0.3, 0.5 and 1 m/s for isotherm air ΔPst Static pressure lossLWA Sound power level
Size
Technical data listed in this table are for DF-47-NARROW without components.For effective speeds (Vk) higher than 6 m/s, consider a noise increase of +4 dB (A) due to regulation behavior (without plenum), 100% open.
HORIZONTAL IMPULSION (FROM WALL)
10
Q 15 - 1000 20 - 1000 30 - 1000 40 - 1000 50 - 1000
(m3/h) (l/s) Ak (m2) 0,011 0,014 0,028 0,037 0,047
100 27,7 Ymax 2,0
∆Pst (Pa) 3
LwA - dB(A) <20
200 55,6 Ymax 3,9 3,2
∆Pst (Pa) 10 5
LwA - dB(A) <20 <20
300 83,3 Ymax 5,9 4,7 2,9
∆Pst (Pa) 23 12 5
LwA - dB(A) 25 <20 <20
400 111,1 Ymax 7,8 6,3 3,8 3,1
∆Pst (Pa) 41 21 9 5
LwA - dB(A) 30 24 <20 <20
500 138,9 Ymax 9,8 7,9 4,8 3,9 3,2
∆Pst (Pa) 64 33 15 8 5
LwA - dB(A) 34 29 25 20 <20
600 166,7 Ymax 9,5 5,8 4,6 3,9
∆Pst (Pa) 48 21 12 8
LwA - dB(A) 34 29 24 23
700 194,4 Ymax 6,7 5,4 4,6
∆Pst (Pa) 29 16 11
LwA - dB(A) 33 28 26
800 222,2 Ymax 7,7 6,2 5,2
∆Pst (Pa) 38 21 14
LwA - dB(A) 36 31 29
900 250,0 Ymax 8,7 6,9 5,9
∆Pst (Pa) 48 27 22
LwA - dB(A) 39 34 34
1000 277,7 Ymax 7,7 6,5
∆Pst (Pa) 33 22
LwA - dB(A) 37 34
1250 305,5 Ymax 9,6 8,1
∆Pst (Pa) 51 34
LwA - dB(A) 42 38
1500 333,3 Ymax 9,8
∆Pst (Pa) 49
LwA - dB(A) 42
DF-47-NARROW
Selection table DF-47-NARROW / -LT
X0.3, X0.5 and X1.0 Horizontal throw of air jet for a mean end velocity of 0.3, 0.5 and 1 m/s for isotherm air ΔPst Static pressure lossLWA Sound power level
Size
Technical data listed in this table are for DF-47-NARROW without components.For effective speeds (Vk) higher than 6 m/s, consider a noise increase of +4 dB (A) due to regulation behavior (without plenum), 100% open.
VERTICAL IMPULSION (FROM ROOF)
11
DF-47-NARROW
Product Codes DF-47-NARROW
Coding example
DF-47-NARROW - 15 - 1500 - RFS-06 -T - RAL 9010Manual DF-47-NARROW diffuser, with air passage 15, of 1500 mm with RFS-06 damper, with screws, finish in glossy RAL-9010.
Model - manual movement, frame 20x6. S manual movement, frame 14x4. IC integrated with duct. CC with adaptation to duct. Actuation - manual operation TR self-regulating by means of a thermal element MT with 2-position, 3-position or proportional (0-10 V) electric servomotor, with 24 V or 230 V supply. Specify in order.
Air passage 15, 20, 30, 40 or 50 air passage
Length 200-L in mm, in a maximum stretch of 2000 mm to form continuous lines
Components MM With Mounting frame. T With holes for fixing screws. PM With mounting bridge. PFL-RL Fixed plenum box made in galvanised steel sheet, without insulation. PFL-A-RL Fixed plenum box made in galvanised steel sheet, insulated. PDL-RL Removable plenum box made in galvanised steel sheet, without insulation. PDL-A-RL Removable plenum box made in galvanised steel sheet, insulated. RFS06 Slide control damper. O With opposed blade control damper. G 2nd row of individually moving vertical blades. PR Complete with decorative perforated sheet metal painted in black to block vision through sections of diffuser with no plenum (decorative or unconnected return).
Angle of supply - option for manual operation with no angle adjustment AF(-30º..30º) option -TR or -MT. Cooling angle, range from -30º C to 30º C AC(-30º..30º) option -TR or -MT. Heating angle, range from -30º C to 30º C
Finish No treatment (galvanised sheet steel frame and aluminium diffuser, model DF-47-NARROW-CC) Matt anodised aluminium natural matt anodised aluminium finish RAL 9010 finish in RAL-9010 gloss polished RAL ... finish in RAL to be defined
12
DF-47-NARROW
Product Codes DF-47-NARROW-LT
Coding example
DF-47-NARROW-LT - 30 - 1000 - PFL-A-RL - RAL 9005 mattDF-47-NARROW-LT diffuser, with 30 mm air passage, 1000 mm long with a fixed insulated plenum and regulation damper on spigot that is accessible from below, finished in RAL 9005 matt.
Model DF-47-NARROW-LT Hidden linear diffuser for medium-long throw CRUZ-DF-47-NARROW-LT Decorative cross-shaped hidden linear diffuser for medium-long throw T-DF-47-NARROW-LT Decorative T-shaped hidden linear diffuser for medium-long throw ESQUNA-DF-47-NARROW-LT Decorative corner-shaped hidden linear diffuser for medium-long throw Air passage 15, 20, 30, 40 or 50 air passage
Length 200-L in mm, in a maximum stretch of 2000 mm to form continuous lines Components PFL-RL Fixed plenum box made in galvanised steel sheet, without insulation. PFL-A-RL Fixed plenum box made in galvanised steel sheet, insulated. RFS06 Slide control damper. O With opposed blade control damper. G 2nd row of individually moving vertical blades. PR Complete with decorative perforated sheet metal painted in black to block vision through sections of diffuser with no plenum (decorative or unconnected return). Finish RAL-9005 matt finish in RAL-9005 matt RAL ... finish in RAL to be defined
13
DF-47-NARROW
THIS CATALOGUE IS COPYRIGHTED. Partial or full reproduction of its content is strictly prohibited without express written authorisation from KOOLAIR, S.L. CEN-DF47NARROW-0618-00
14
KOOLAIR, S.L.
Calle Urano, 26Poligono industrial nº 2 – La Fuensanta 28936 Móstoles - Madrid - (España) Tel: +34 91 645 00 33Fax: +34 91 645 69 62e-mail: [email protected]
www.koolair.com