Date: 4-17-217 Solar pumping system Sequence 1 Series - 61SEQ23 Test Report This report quantitatively documents the tested performance of a solar surface water pumping system consisting of a specific surface AC pump powered by solar PV panels in conjunction with a PicoCell controller. Solar PV panels are the DC input for the PicoCell controller and the singlephase surface AC pump is connected to the PicoCell s output, as shown in figure 1. Solar PV panels are connected in series in order to provide the required DC solar power to the PicoCell controller that is generating the appropriate AC output for a specific AC pump. The PicoCell controller can be used for running any AC pump from solar PV independent of phase, voltage and frequency. For a given AC pump specification, PicoCell is capable of generating a true sinewave with a variable frequency range of 3-6Hz. By varying the frequency, PicoCell controls the pump s speed in the range between 5 and 1% of rated speed, depending on the power availability from the solar panels (PV input). Figure 1: Solar AC pumping system diagram In this particular setup, a single-phase (2-wire) surface pump was tested with the PicoCell controller powered by 3-5 common PV panels (6 cells, 23-27 W) wired in series. The technical specification of the AC pump is provided in the table 1. Table 1: Technical specification of tested AC pump: Surface pump: Sequence 61SEQ23 Power: 1/3 1/8 HP Voltage: 115/23V Current: 3.3A Frequency: 6Hz Pressure: 23ft Max flow: 61 GPH Speed: 345rpm MFG# SunTech Drive, Inc. www.suntechdrive.com 5485 Conestoga Court, Suite 25, Boulder, 831, Colorado
The Sequence surface pump was tested for several different pressures versus flow, and its nominal pump curve (for 6Hz) is shown in figure 2. Figure 2: Model 61SEQ23 When the pump is controlled by the PicoCell, which is connected to the solar PV panels, the PicoCell will run the pump at different speed frequency range: 3-6 Hz, and hence the pump will generate variable flow at variable available solar PV power, for the same head (pressure setting). In order to start the pump at 3 Hz, at any head, it takes 75W from solar PV panels. To run the pump at nominal 6Hz, it takes a maximum of 35W. Figure 3: Power requirements vs. frequency for Sequence 75 solar surface water pump 2
Depending on the location where this solar pumping system is installed, it will require more or less total PV capacity to achieve these results. There are 6 solar zones that are shown in Figure 3. Zone 6 has the most solar insolation (6-7 kwh/m 2 /day), zone 5 is in the solar insolation of 5-6 kwh/m 2 /day, while zone 1 has the least amount of sun (1-2 kwh/m 2 /day). The highest solar insolation is to be expected in Sahara region of Africa, South Africa, Australia and Caribbean part of South America. On the other hand, least amount of solar insolation is found in northern parts of Europe and Russia, North America, Greenland, and most southern tip of South America figure 4. Figure 4: Solar insolation zones in the World Figure 5-1 present solar AC pump hours of operation for all six zones respectively, for various pressures. Each of the lines is based on the solar PV installed capacity, so that a customer at a given zone of interest can choose the correct amount of solar PV panels solar PV capacity. Furthermore, each figure shows accumulative, daily flow for the given zone, for various heads and chosen solar PV capacity (right graph). Hence, the customer can not only choose the solar PV capacity based on the operating time per day for the given pump, but even more convenient, based on the total daily flow required at the given location. For example, if a customer has a site at zone 4, for 4, gallons of water (figure 7), the solar pumping system will require 9W of solar PV capacity (4 standard 25W PV panels) and as a result will operate over 9 hours per day. 3
12. 1. 8. 6. 4. 2.. 5 4 Figure 5: Operating hours and daily flow of solar powered surface Sequence pump for Zone 6, for 12. 1. 8. 6. 4. 2.. 5 4 Figure 6: Operating hours and daily flow of solar powered surface Sequence pump for Zone 5, for 1. 8. 6. 4. 2.. 5 4 Figure 7: Operating hours and daily flow of solar powered surface Sequence pump for Zone 4, for 4
1. 8. 6. 4. 2.. 5 4 Figure 8: Operating hours and daily flow of solar powered surface Sequence pump for Zone 3, for 1. 8. 6. 4. 2.. 5 4 Figure 9: Operating hours and daily flow of solar powered surface Sequence pump for Zone 2, for 1. 4 8. 6. 4. 2.. Figure 1: Operating hours and daily flow of solar powered surface Sequence pump for Zone 1, for 5
Figure 11: Daily pump operation of 1HP pump for different solar PV panel capacities Figure 11 above shows how increasing solar PV capacity affects duration of operation of solar pumping system. Time 1 is the duration of operation for 9W pump when powered by 1W solar PV panels. If additional 25W panel is added, same 9W pump will be supplied with 125W of solar PV power, and therefore duration of operation - Time 2 will be significantly higher, as shown in the figure. Increasing the solar PV capacity continues increase in duration of pump operation, but not linearly. Therefore, adding more solar PV capacity will provide diminishing returns after a certain point until it does not make economical sense anymore. Moreover, it is possible to extend the duration of operating hours of the same AC pump if a battery bank is added to the system, as shown on the figure 12 below, especially if nighttime operation is critical. The battery bank can be designed and sized for different AC load to extend the operation for a desired amount of time. For a given 1/3HP Sequence 1 series AC pump, the table below shows battery bank sizes for different night time operation. Table 1: Battery bank configuration for 1/3HP Sequence 1 series AC pumps for different nighttime operation durations in addition to normal solar irradiance hours 4 hours 6 hours 8 hours 1 hours 6 x 55Ah, 12V batteries 6 x 75Ah, 12V batteries 6 x 15Ah, 12V batteries 6 x 135Ah, 12V batteries 6
Figure 12 below shows typical system installation for solar AC pump with battery back-up. Battery and solar PV got connected to the battery box, which is then connected to the PicoCell that runs the AC pump. The battery box leverages the embedded intelligence of the PicoCell and provides hardware protections for the batteries as well as the PicoCell. It can also be used to power an auxiliary cooling for the enclosure housing the batteries themselves. Figure 12: AC pump driven by PicoCell powered by solar and battery bank system 7