Example: (imperial), Example: (metric) – Greenheck Fan Canopy Type Kitchen Hoods 452413 User Manual

18

Kitchen Hoods • Type I and Type II

Grease-X-Tractor™ High Efficiency Filters or
Grease Grabber™ Multi-Filtration System
Rotating Vane Method

A. Exhaust

With all the filters in place, determine the total hood
exhaust volume with a rotating vane anemometer as
follows:

1. All cooking equipment should be off. If the hood has

internal short circuit make-up air, it should be turned
off.

2. Measure velocities

Measurement should be taken at six locations per
filter. They must be over the inlet opening as shown
in Fig. 13.

Measure the velocity of each location. A digital
2.75 in. (69.85 mm) rotating vane anemometer
or its equivalent is suggested. The center of the
anemometer should be held 2 in. (50.8 mm) from
the face of the filters as in Fig. 14. It is helpful to
make brackets to keep the anemometer at the 2 in.
(50.8 mm) distance and parallel to the filter. Both
squareness and distance are important for accuracy.

3. Calculate the average velocity for the filter.

4. Determine the filter’s conversion factor from the

table.

5. Calculate each filter’s volumetric flow rate in CFM by

multiplying the average velocity for each filter by the
conversion factor.

2 in.

(50.8 mm)

Rotating Vane
Anemometer

Fig. 14

Nominal Filter Size (H x L)

Imperial

Conversion

Factor

Metric

Conversion

Factor

Inches

Millimeters

16 x 16

400 x 400

1.31

ft

2

.122

m

2

16 x 20

400 x 500

1.65

ft

2

.153

m

2

20 x 16

500 x 400

1.23

ft

2

.114

m

2

20 x 20

500 x 500

1.65

ft

2

.153

m

2

1/2 Width

1/4 Width

1/4 Width

1/2 Height

Fig. 13

Filter 1

225

201

187

210

238

197

Filter 2

228

222

226

237

240

220

Filter 3

230

245

240

250

223

219

Filter 4

225

265

219

245

221

200

Average slot velocity for Filter 1

=

Sum of Velocity Readings

Number of Readings

=

1258

6

=

209.7 ft/min.

(repeat for each filter)

For a nominal filter size of 20 x 20, the conversion factor is 1.65

Volume for Filter 1 = Conversion Factor x Average Velocity

=

1.65 ft

2

x

209.7 ft/min.

=

346.0 cfm (repeat for each filter)

Example: (Imperial)

Hood Length: 7 feet 0 inches with four 20 x 20 filters.

Measure the velocities in ft/min. for each 20 x 20 filter
(six readings per filter)

Total hood volume

=

Filter 1

Volume

+

Filter 2

Volume

+

Filter 3

Volume

+

Filter 4

Volume

=

346.0

+

377.6

+

386.9

+

378.1

= 1488.6 cfm

Filter 1

4114.80

3675.88

3419.86

3840.48

4352.54

3602.74

Filter 2

4169.66

4059.94

4133.08

4334.26

4389.21

4023.36

Filter 3

4420.12

4480.56

4389.12

4572.00

4078.22

4005.07

Filter 4

4114.80

4846.52

4005.07

4480.56

4041.65

3657.60

Example: (Metric)

Hood Length: 2.13 meters, with four 500 x 500 mm filters.

Measure the velocities in m/hr for each 500 x 500 mm filter
(six readings per filter)

Average slot velocity for Filter 1

=

Sum of Velocity Readings

Number of Readings

=

23006

6

=

3834 m/hr

(repeat for each filter)

For a nominal filter size of 500 x 500, the conversion factor is .153

Volume for Filter 1 = Conversion Factor x

Average Velocity

=

.153 m

2

x

3834 m/hr

=

586.7 m

3

/hr (repeat for each filter)

Total hood volume

=

Filter 1

Volume

+

Filter 2

Volume

+

Filter 3

Volume

+

Filter 4

Volume

=

587

+

642

+

657

+

642

= 2528 m

3

/hr

®