Energy savings from improved air distribution in chilled food manufacturing facilities arlos maris esearch Fellow, arlos.amaris@brunel.ac.uk Demetris Parpas PhD Student, Demetris.parpas@brunel.ac.uk Savvas Tassou Director SEF, Savvas.Tassou@brunel.ac.uk UK National entre for Sustainable Energy Use in Food hains (SEF), nstitute of Energy Futures, Brunel University London 1
ONTENTS 1. NTODUTON 1.1 hilled Food Manufacturing Facilities 1.2 ir Distribution mportance 1.3 Scope of The esearch 1.4 esearch Methodology 2. SE STUDY 3. SLED TEST FLTY 3.1 Experimental Test Facility 3.2 Experimental esults 3.3 FD Model 3.4 mproved air temperature distribution 4. ONLUSONS 2
1. NTODUTON 1.1 hilled Food Manufacturing Facilities ely heavily on refrigeration in order to maintain low temperatures during processing of chilled food products. Facilities are normally maintained at temperatures in the range between +4 to +12 o depending on the type of product. efrigeration can account for up to 60% of the total energy consumption of the facility. hilled food processing normally takes place in large spaces with high ceilings. ooling is normally provided by ceiling mounted fan coil units or diffusers using the air mixing principle. 3
1. NTODUTON 1.2 ir Distribution mportance reate an environment capable of maintaining food quality. Temperature and humidity homogeneity around the food product in order to maintain its quality. Provide an acceptable environment for the workers in terms of thermal comfort. 1.3 Scope Of The esearch ims to improve the efficiency of cold air temperature distribution in chilled food processing areas. eduction of the overall energy consumption of the refrigeration plant. ssociated O 2 emissions. 4 4
1. NTODUTON 1.4 esearch Methodology Understanding, modelling and replication of the air flow and the temperature distribution in existing chilled food facilities. Development of a tree-dimensional model based on computational fluid dynamics (FD). Validation of the model. Building of a scaled experimental test rig and FD model. Use of the model to investigate different air distribution solutions. mplementation of most promising solution at the laboratory. ndustrial application of prototype. 5 5
2. SE STUDY hilled Food Processing Facility ir distribution via fabric ducts ir temperature and velocity measurements 6 6
2. SE STUDY hilled Food Processing Facility 3D Model of the Processing Facility Numerical model description Steady state 3-dimensional FD model solved using the commercial NSYS FLUENT package. Model was designed using the actual dimensions of the chilled food processing area. The SST-k-ω turbulence model was used to predict actual measured data. 7 7
2. SE STUDY FD modelling of air temperature in the space (º). 3D Model validation FD modelling of air velocity in the space (m.s -1 ). 8 8
3. SLED TEST FLTY 3.1 Experimental Test Facility Outline of the experimental test facility with air distribution via fabric duct at ceiling level, reference case. Test facility, reference case. The chamber volume, 2.9 m () x 6.6 m (L) x 3.5 m (W). The fabric duct, 50 cm in diameter and 500 cm in length. Temperature sensors (T) were located at knee level, head level and ceiling level (± 0.5 º). ir velocity measured with an air flow meter TS T465-P (± 3 % ). The air temperature in the test chamber set to 9.7 º. 9 9
3. SLED TEST FLTY 3.2 Experimental esults Temperature profiles at different heights, [a] Knee Level, [b] ead Level and [c] eiling Level. Temperatures varied from 8.1 º and 13.9 º while the average temperature values measured at knee, head and ceiling level were 10 9.9 º, 10.6 º and 12.4 º, respectively. The lowest temperatures were measured at knee level and highest at ceiling level. 10
3. SLED TEST FLTY 3.2 Experimental esults Velocity profiles at different heights, [a] Knee Level, [b] ead Level and [c] eiling Level. Velocities varied between 0.02 and 0.25 m.s -1 with the highest values observed at knee level. 11 11
3. SLED TEST FLTY 3.3 FD Model [a] 3-D model and [b] Model mesh cross section. Numerical model Boundary conditions ir supply temperature was set at 7 º. Each occupant was defined as a rectangular box with 1.57 m 2 surface area with 150 W sensible thermal load. Lighting heat load was set at 30 W.m -2 floor area. The thermal boundary conditions of the surrounding walls were estimated considering a wall temperature of 13 º. 12 12
3. SLED TEST FLTY 3.3 FD Model FD modelling of air temperature in the space (º). Supply temperature from the air fabric duct at 7 º ir velocities were very low and varied between 0.01 and 0.3 m.s -1 The temperature in the bulk of the space varied between of 8.9 º and 13.0 º FD modelling of air velocity in the space (m.s -1 ). 3D Model validation 13 13
3. SLED TEST FLTY 3.3 FD Model 3-D models [a] air distribution via displacement ventilation with one diffuser, [b] air distribution using displacement ventilation system with two 1-way supply 14 diffusers, [c] air distribution system with a half fabric duct at a medium level, [d] air distribution system via slot diffusers and [e] air distribution via fabric duct at medium level. 14
3. SLED TEST FLTY 3.3 FD Model ir distribution system with a half-fabric duct at a medium level ir distribution via whole fabric duct at medium level. 15 For both, air temperature varied between 7 º and 14.0 º. The temperature at the production line level up was to 7-7.5 º. omogeneous flow pattern along the occupied area with increased temperature stratification. 15
3. SLED TEST FLTY 3.4 mproved air temperature distribution Temperature profiles at different heights Fabric duct alf-fabric duct eference: Temperature (from 8.1 º and 13.9 º), average temperature values measured at knee, head and ceiling level were 9.9 º, 10.6 º and 12.4 º, respectively. alf-fabric duct at medium level: Temperature (from 7.5 º and 15.1 º), average temperature values at knee, head and ceiling level were 9.3 º, 10.5 16 º and 14.3 º, respectively. Fabric duct at medium level: Temperature (from 6.5 º and 16.0 º), average temperature values at knee, head and ceiling level were 9.8 º, 10.7 º and 15.2 º, respectively. 16
3. SLED TEST FLTY 3.5 Energy consumption 17 hour experimental period power consumptions Fabric duct at eiling Fabric duct at level medium level alf-fabric duct at medium level Total consumption (kwh) 25.28 22.88055556 23.50822222 ourly average ( kwh) 1.49 1.345915033 1.383062592 Energy saving (%) eference case 9% 7% 6000.00 5000.00 4000.00 3000.00 2000.00 1000.00 0.00 Fabric duct at eiling level 17 19:00:00 19:03:00 19:06:00 19:09:00 19:12:00 19:15:00 19:18:00 19:21:00 19:24:00 19:27:00 19:30:00 19:33:00 19:36:00 19:39:00 19:42:00 19:45:00 19:48:00 19:51:00 19:54:00 19:57:00 20:00:00 power (W) 6000.00 5000.00 4000.00 3000.00 2000.00 1000.00 0.00 Fabric duct at medium level 6000 5000 4000 3000 2000 1000 0 alf-fabric duct at medium level 17 19:00:05.994 19:03:45.994 19:07:25.994 19:11:05.994 19:14:45.994 19:18:25.994 19:22:05.994 19:25:45.994 19:29:25.994 19:33:05.994 19:36:45.994 19:40:25.994 19:44:05.994 19:47:45.994 19:51:25.994 19:55:05.994 19:58:45.994 19:00:05.088 19:03:55.088 19:07:45.088 19:11:35.088 19:15:25.088 19:19:15.088 19:23:05.088 19:26:55.088 19:30:45.088 19:34:35.088 19:38:25.088 19:42:15.088 19:46:05.088 19:49:55.088 19:53:45.088 19:57:35.088 power (W) power (W)
4. ONLUSONS urrent configurations of air distribution systems in food processing factories tend to cool the whole processing room. Fabric ducts provide air flow more uniformly and at lower velocities than conventional fan coil air distribution systems. Low velocity air distribution at low level provides more localized cooling - lower temperature at low level in the manufacturing area and higher temperatures at higher level. Localized cooling and temperature stratification reduces space to be cooled to low temperature and leads to lower refrigeration system energy consumption. Next step Metal based prototype is being installed and will be monitored in a food processing facility. cknowledgements: nnovate UK, UK, Bakkavor, Waterloo ir Products 18 Ltd. 18
Thank you for your attention Questions? 19 19