C:\Users\raoh\Desktop\Paper_1.xps TJER 2012, Vol. 9, No. 1, 1-10 ________________________________________ *Corresponding author’s e-mail:drkarimaa@yahoo.com Thermal Performance of Solar Hot Water Systems Using a Flat Plate Collector of Accelerated Risers KE Amori* and NS Jabouri Department of Mechanical Engineering, Nahrain University, University of Baghdad, Baghdad, Iraq Received 3 May 2010; accepted 27 September 2010 Abstract: This study focuses on a comparison of the performance of two similar locally-fabricated solar water heaters. One of the collectors features a new design for accelerated absorber; its risers are made of converging ducts whose exit area is half that of the entrance. The other collector is a conventional absorber, with risers of the same cross sectional area along its length. Each collector is the primary part of an indirect thermosyphon circulation solar hot water system. Both collectors face south with a fixed tilt angle of 33.3 from the horizontal. A side-by-side experiment was conducted on the two solar water heaters from January to April of 2009 for different water withdrawal profiles, continuous, interrupted and no load, as well as for horizontal and vertical storage tank orientations. Two types of storage tanks were investigated, those with two concentric cylinders, and those with helically-coiled tubes in the cylin- der. Results show that a considerable enhancement of thermal performance (approximately 60%) of absorbed heat (useful gain) at solar noon was obtained for the new design, in comparison with the con- ventional type. The instantaneous efficiency was 31.5% for the accelerated absorbed flat plate at solar noon, while that of conventional absorber was (16.5%). The longitudinal water temperature variations in the risers of accelerated absorber were larger than that of the conventional absorber. The stratification in the storage tank was significantly improved for the solar hot water system, with the new absorber design in which the maximum temperature measured was 50 C (vertical storage tank), while that for conventional absorber was 37 C. The stratification obtained for a coiled tube in a cylinder storage tank indicated a good thermal performance with less space requirements. Also, the circulation rate in the accelerated absorber was higher when it was connected to a coiled tube than when it was connected to the concentric cylinders. Keywords: Solar, Accelerated flat plate collector, Storage tank, Coiled tube, Stratification 2 KE Amori and NS Jabouri 1. Introduction Solar hot water systems function as heat exchang- ers. They receive solar radiant energy and transfer it to the flowing fluid. The performance of solar systems varies as the design variables change, so it is therefore necessary to identify the parameters affecting this design and the operational variables. Keltt et al. (1984) studied through experimentation the thermal performance of submerged coil heat exchangers for single wall coil and double wall coil for different tank sizes namely (300 L and 450 L) for dif- ferent load flow rates. Khalifa (1999) investigated a thermosyphon domestic hot water system to show the important variables that affect the performance of the solar system such as the temperature variation along the absorber fins, tubes and in the flow direction as well as the thermosyphonic mass flow rate. The design of an efficient storage tank heat exchanger has been investigated by (Shokouhmand et al. 2008) with dif- ferent coil pitches and curvature ratios. An enhance- ment in the heat transfer rate is obtained due to the centrifugal force due to the curvature of the tube, resulting in the secondary flow development. The objective of the present work is to compare experi- mentally thermal performance of a locally-made new solar flat plate collector (named here as accelerated solar collector) to a flat plate collector of straight ris- ers the conventional type hot water system for a dif- ferent water withdrawal pattern. Additionally, the study will show the stratification in the storage tank. In order to carry out a fair comparison, the collectors are made as identically possible. 2. Theory Thermal analysis has covered in many solar ther- mal engineering texts (Duffie, Beckman 1974; Lunde 1980). Therefore, only equations which describe the thermal performance of the system will be described in this paper. Actual Collector And Supply Useful Energy Gain For the collector closed- loop cycle, the hourly use- ful energy gain can be calculated by: (1) The heat obtained by the water withdrawal can be calculated as: (2) Where Qcoll heat is transferred in W, m mass flow rate in kg/s, Cp water specific heat in J/kg.K, T is the measured temperature at the collector inlet or outlet (oC), and T20 and T18 are supply water temperatures at inlet and outlet from the storage tank, as shown in Fig. (1b) and Fig. (3). The useful energy enhancement is calculated as: (3) The collector instantaneous efficiency can be deter- mined according to: (4) IG is the global solar radiation on tilted collector at 33.3 from horizontal calculated from that measured on a horizontal surface. 3. Experimental Setup Two identical solar water heaters are manufactured in this experiment; one is supplied with flat plate col- lectors of accelerated absorber, the other is supplied with flat plate collectors of conventional absorber. Figure 1 shows the configuration of solar water heater tested when its storage tank is composed of two con- centric cylinders, and when it is a helical coiled tube in cylindrical shell. 3.1 Accelerated Flat Plate Solar Collector A flat plate collector with an accelerator plate con- sists of nine equally-spaced parallel converging rec- tangular cross-sectional area copper risers (Fig. 2) with an inlet hydraulic diameter of 2 cm. The inlet dimensions are 20x20 mm, and the outlet hydraulic diameter 13.3 mm, while the outlet dimensions are 10x20 mm and tube length of 1.2 m. The riser to riser distance is 0.1 m, and each tube has an equal right and left fin length of 40 mm. These tubes are connected with two headers of rectangular cross sectional area one at each end to collect or distribute water from and into the risers, and from collector's outlet and inlet. The joints between the headers and risers ends are welded by using brass alloy. A mat painted copper sheet is used as an absorbing plate of 1.20 x 0.9 m and of 1.9 mm thickness. This sheet is welded to the risers by brass alloy, the struc- ture is good insulated with a fire wool coating of 70 mm thickness. 3 Thermal Performance of Solar Hot Water System Using a Flat Plate Collector of Accelerated Risers 3.2 Conventional Flat Plate Solar Collector A conventional flat plate collector without accel- erator plate is designed identical to an accelerated flat plate collector, and it consists of nine equal spaced parallel copper rectangular cross sectional area pipes of inlet and outlet with equal hydraulic diameters of 20 mm. In addition, the inlet and outlet cross sections dimensions are 20x20 mm and 1.20 m length, and the riser to riser distance is 0.1 m. Each tube has an equal fin length to right and left of 40 mm, and these tubes are connected with two headers of rectangular cross sectional area. The risers are welded to the header using brass alloy. A copper sheet is used as an absorb- ing plate of 1.20 x 0.9 m and of 1.9 mm thickness. This sheet is welded to the risers using a brass alloy, the pipes are supported from the bottom by a galva- nized plate of 2 mm thickness. The structure is well- insulated with a glass wall coating of 70 mm thick- ness. The collector box frame is manufactured from a 2 mm thickness galvanized sheet formed as a box, and the collectors are connected to their containers by screws. The collectors are well-insulated by using glass wool insulation of 70 mm thickness from the back of the collectors and 50 mm thickness from the perimeter of the collectors. A glass panel of 4 mm thickness is used as a transparent cover for the collec- tor with area of 1.25x0.95 m². The glass cover lies on the collector frame in a small channel 25 mm wide, and is fixed by using a black silicon. A piece of rub- ber tape is fixed between the glass and channel to pre- vent air leakages. The cover-absorbing plate spacing is 70 mm. 3.3 Storage Tanks 3.3.1 Shell and Tube Storage Tank Two concentric horizontal cylinders form the stor- Figure 1. Close loop themosyphon solar water heater, the storage tank is a) Two concentric cylinders b) Helical coiled tube in cylindrical tank (b) (a) Storage tank 4 KE Amori and NS Jabouri age tank made from a galvanized plate of 2 mm thick- ness. The internal cylinder has an inner diameter of 375 mm, 1 m length and capacity of 110 L. The outer cylinder has an internal diameter of 470 mm and a length of 1.2 m, forming an annular space of 90 L. The internal cylinder is used for the closed-loop water (energy carrier) while the annular space between inter- nal and external cylinders is used for loading water (domestic use water). Each cylinder has two holes to form inlet and outlet ports. The tank is well insulated by a glass wool insulator of 70 mm thickness, and the storage tank can be oriented horizontally or vertically as required. 3.3.2 Coiled Tube In Shell Another storage tank manufactured by (Karima et al. 2011) is used in the present work. This tank (made from a galvanized sheet) is of 125 L volume, 1m height and 0.4 m diameter. A coiled tube is inserted inside in the tank which in turn is well insulated with glass wool of 10mm thickness. A 0.6 m high coiled tube is made by winding a copper tube of 9.5 mm diameter around a cylinder to form twelve turns of 0.25 m outside coil diameter. A spacer was placed between each two consecutive coil turns to ensure a uniform pitch along the coil, which measured 0.05 m. 3.4 Temperature Measurement One hundred and five (105) calibrated thermo- couples (Type T Copper and Constantan) are used to measure the temperature at various points of water tubes, water storage tanks, inlet and outlet of collec- tors, inlet and outlet of the withdrawal water, ambient and glass cover, as shown in Fig. 3. The entire num- ber of thermocouples are joined to Digital thermome- ter reader (Autonics-T4WM/ K(CA) 0-1200). The ambient temperature is measured by a using a mercu- ry in glass- thermometer. 3.5 Flow Rate Measurement The mass flow rate of the thermosyphon circula- tion flat plate collectors is so small tht only the laser flow meter can detect the flow which in not available, so a transparent tube of 250 mm length and 10mm diameter is connected between collector outlet and storage tank inlet. An ink injection is used to calculate the circulation rate by injecting ink and measuring the time required to pass the 250 mm distance using stop- watch to compute fluid velocity. The water load flow rate is measured by using a flow meter of 2-22 L/min. range. 3.6 Test Procedure The thermosyphon circulation solar water flat plate collectors were connected as a closed loop (indirect) system. The experiments were carried out from January to March 2009. Before each test, the follow- ing preparations were made, the closed collector loop Figure 2. Configuration of manufactured flat plate collector Collector risers Container frame Insulation a) Collector cross sectional view b) Accelerated riser (front view) c) Conventional riser (front view) 5 Thermal Performance of Solar Hot Water System Using a Flat Plate Collector of Accelerated Risers was filled with water, the glass cover is cleaned thor- oughly and the measurements and apparatus were checked. Then the storage tanks were filled with water and readings were taken each half hour from sunrise to sunset. The newly-designed system was tested side by side with the conventional type. The test was conducted from sunrise to sunset for five different mass flow rates of load water withdraw- al profiles. These profiles were: continuous load of 2.6 L/min, the profile (II) shown in Fig. 7 which is equiv- alent to daily consumption of single storage tank vol- Figure 3. Locations of temperature measurements Figure 4. Solar radiation on horizontal surface and ambient temperature (5/3/2009 at 33.3 N. Baghdad) 6 KE Amori and NS Jabouri ume, emptying the storage tank twice a day and final- ly emptying it once a day. This propose is to test the effect of storage tank orientation (horizontally and ver- tically) on the thermal performance and study the effect of using a coiled tube for collector closed-loop instead of cylindrical tank. In all the above cases all temperature measurements, flow rate (circulation rate and loop flow rate), wind- speed are recorded. 4. Results and Discussions Figure 4 shows the ambient temperature (measured (every 15 minutes) and solar radiation for the 24 hours of 27-1-2009 on the solar collector, which is obtained from the Ministry of Science and Technology Solar Center in Baghdad. It is clear that the peak solar radi- ation was between hours of 11 to 13. The peak ambi- ent temperature was 19 C. Figure 5 shows the hourly water temperature rise along a selected riser C-C for the accelerated conven- tional type. It is clear that the temperature rises with time as water proceed along the risers length, but less- er temperature values are indicated for the convention- al type since the accelerated riser occupies less water volume at the cross section especially at the riser on the upper part. Figure 6 (a & b) shows a comparison Figure 5. Water temperature distribution along risers Local time (hr) Acclerated riser C-C Local time (hr) Acclerated riser C-C 7 Thermal Performance of Solar Hot Water System Using a Flat Plate Collector of Accelerated Risers Figure 6. The thermosyphon circulate rate in the collector (33.3 N. Baghdad) a) Profile I, b) Profile II Figure 7. Water withdrawal profile (Case II) Load Case II Local time (a) (b) 8 KE Amori and NS Jabouri of the circulation rate between the accelerated and conventional flat plate for load profile I and load pro- file II shown in Fig. 7 respectively. A significant increase in the circulation rate is recorded from the first hour of day to the last hour, due to the new design criteria of the risers (converging cross sectional area). The maximum increase was at solar noon, and was due to exposing the same area to the same incident solar radiation. However, the water content in the converg- ing risers was less than that in the straight riser so the temperatures increased and its density was lighter, resulting in it rising faster. Figure 8 shows the per- centage enhancement in absorbed heat when using an accelerated collector compared to a conventional col- lector (horizontal tank case II). The useful energy enhancement was calculated using Eq. (3). The maxi- Figure 8. Percentage enhancement in absorbed heat when using accelerated collector compa- red with conventional collector (Hori- zontal tank case II) Figure 9. The instantaneous efficiency of the con- ventional and (accelerated collector for load Profile II) Figure 10. Effect of tank orientation and type on thermosyphon circulation rate (Profile II) Figure 11. Stratification in shell and tube horizo- ntal storage tank (accelerated collec- tor load Profile I) 9 Thermal Performance of Solar Hot Water System Using a Flat Plate Collector of Accelerated Risers mum enhancement was 60% at solar noon and the minimum was measured at the day’s run hour. Thus the new design recorded an instantaneous efficiency of 32.8% , while the conventional type indicated 17% as a maximum value, as shown in Fig. 9. Figure 10 shows that the vertical orientation of the storage tank enhances the circulation rate, and the coiled tube in cylinder has a much more effective design than the two concentric cylinders. Figure 11 shows the hori- zontal stratification in the concentric cylinders storage tank when connected to the accelerated collector. The upper right corner shows the hottest region (inlet of hot water from collector and exit of hot load water T=24.5 C), while the lower left corner is the coldest region exit of cold water to the collector and the inlet of cold load water T=16.5 C). Figure 12 shows the vertical stratification in the two concentric cylinders for no load where the maximum temperature indicated at the upper surface (inlet of collector hot water and exit of load hot water Tmax = 51 C). Figure 13 shows the vertical stratification in the coiled tube in the cylin- drical storage tank for load profile II , where the max- imum temperature indicated at the upper surface (inlet of collector hot water) and exit of load hot water Tmax = 37.1 C. 5. Conclusions This research shows that the system thermal behavior is sensitive to any component and can be enhanced further by modifying the design parameters and mate- rial selections. The following concluding remarks can be made, based upon this work. * The stratification obtained in the storage tank is significantly affected by the collector inlet tem- perature. * The stratification obtained in the storage tank relates proportionately to the type of load rate (or load withdrawal pattern). * Increasing the flow rate of the load decreases the stratification in the storage tank * The effectiveness of the storage tank (shell and coiled tube) reaches approximately 78% for (450 mL/min) load flow rate. * Using a car radiator instead of the coiled tube enhances the thermal performance of the storage tank. * Using an accelerated (converging) riser will enhance the thermal performance of the thermosy- phonic solar collector because it will increase the circulation rate. References Duffie JA, Beckman WA (1974), Solar energy ther- mal process. John Wiley & Sons Inc. New York. Karima AE, Mustafa FF, Sahar M (2011), Solar 0.1 0.2 0.3 0.4 X 0.8 0.7 0.6 0.5 0.4 Figure 12. 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