Product Manual Installation Instructions for CHSM-230M Series Solar Module CHSM-230M series solar module is made of 60 pieces of 156 mm 156 mm crystalline solar cells in series with high efficiency, high transmission, and low iron toughened glasses. Other characteristics include anti-aging EVA and high flame-resistant back sheet lamination, and with anodized aluminum alloy frames. Modules are highly efficient, easy to install, and highly resistant to wind. Products are made according to national standards GB/T9535-2005(IEC61215-2005)and have passed authorized test center inspections. Our products can be used in household rooftop solar systems, PV stations, and communication stations. Other feasible locations are petrol, ocean, meteorological, traffic, and solar buildings The CHSM-230M series solar modules mainly include 210W, 215W, 220W, 225W, 230W, 235W, 240W models. Electrical Specification Mono Series Photovoltaic Module Model CHSM-230M Number of Cells 60 pcs PMP (W) 230 (± 10%) VOC (V) 36.75 (± 10%) ISC (A) 8.26 (± 10%) VMP (V) 29.4 (± 10%) IMP (A) 7.82 (± 10%) Max Series Fuse Rating (A) 15 (± 10%) Nominal Mass 20.5 kg Package Size 1652 mm 994 mm 45 mm Cell Size 156 mm 156 mm System V max DC 1000V Bypass Diode Rating 45V, 12A Configuration 6 10 Electrical characteristics are within ±10 percent of the indicated values of ISC, VOC, and WMP under test conditions (irradiance of 100 mw/cm 2, AM1.5 spectrum, and cell temperature of 25 C) 1
Under normal conditions, a photovoltaic module is likely to experience conditions that produce more currents and/or voltage than reported at standard test conditions. Accordingly, the values of ISC and VOC marked on this module should be multiplied by a factor of 1.56 when determining component voltage ratings, conductor ampacity, fuse sizes, and size of controls connected to the PV output. Please refer to section 690-8 of the National Electrical Code (NEC) for any additional multiplying factors of 156 percent, which may be applicable. Installation should be in accordance with CSA C22.1, Safety Standards for Electrical Installations, Canadian Electrical Code, Part 1. Physical Characteristics No. Item Remarks 1 Measurement Length:1652 mm (65.03 inches); Width: 994 mm (39.10 inches); Height: 45 mm (1.77 inches) 2 Weight 20.5 kg (44 pounds) 3 Cell 60 pcs (156 mm 156 mm) solar cells, 6 10 matrix arranged in series 4 Output Cable 4 mm 2 cable with UL certification, polarity mark, waterproof; length is 900 mm. 5 Junction Box With 4 pcs connector, IP65, max system voltage is 600 VDC, max current is 16 A, outer material is PPO with UL certification 6 Structure Front: High transmission and transparent toughened glass with 3.2 mm (1/8 inch) in height Back: Polyester Material: EVA 7 Frame Anode oxidation. Aluminum alloy frame 6063T5 Color: Silver 8 Insulated Performance 50 MΩ 9 Maximum System DC 1000V Voltage 2
Operating Environment Climate Conditions Install the PV module in the following conditions: Environment temperature: -20 C to 40 C. Operating temperature: -40 C to 80 C. Water resistance: Do not dip the modules into water or it will continually explode under water. Antisepsis: Keep away from salt erosions and sulfurous places. Installation Notes Modules electrical performance in a system is the same. In series connections, all modules must have the same amperage. In parallel connections, all modules must have the same voltage. The quantity of modules connected must match the voltage specifications of the devices used in the system. Modules can not be connected to create a voltage that is higher than the permitted system voltage. In order to minimize the risk of an indirect lightning strike, avoid forming loops when designing the system. Modules must not be fitted as overhead glazing. Ensure that the installed system can withstand the anticipated wind and snow loads. The maximum load on the module must not exceed 1.44 kn/m 2. To avoid exceeding the maximum load, site-specific environmental loads such as wind and snow should be accounted for. Precipitations can run off through small openings on the back side of the module, which should not be covered or blocked after installation. The installed project must face north in the southern hemisphere, or south in the northern hemisphere. The electricity will be comparatively lower when the project is facing west or east. Incorrect installation will result in power loss. RECOMMENDED TILT ANGLES FOR A FIXED SYSTEM SITE LATITUDE IN DEGREES FIXED TILT ANGLE 0 o TO 15 o 15 o 15 o TO 25 o SAME AS LATITUDE 25 o TO 30 o LATITUDE+5 o 30 o TO35 o LATITUDE+10 o 35 o TO 40 o LATITUDE+15 o 40 o + LATITUDE+20 o 3
Modules must be connected in the same angle. Otherwise, power loss will occur due to the difference in sunlight intensity. Solar modules generate power to the maximum when facing directly at the sun. When mounting modules to a permanent structure, modules should be tilted at an angle for optimum winter performance. As a rule, if the system power output is adequate during the winter, then performance will be satisfactory for the other seasons of the year. The module tilt angle is measured between the solar modules and the ground. Avoid installing modules under shadows, even module factories use bypass diodes to decrease the loss of energy. Shadows will result in the loss of power output. Grounding All module frames must be attached to solid ground. A qualified electrician must complete ground connections. The cable utilized in connecting modules to the ground must be copper wire with 14(12)AWG. 4
Stainless steel M5 bolt Stainless steel M5 cut washer φ4.2 copper wire Stainless steel M5 plain washer Stainless steel M5 nut Stainless steel M5 spring washer Stainless steel M5 Cut washer Use the holes (5.0 mm) marked with. To create the conductive connection (frame is anodized), use Stainless steel M5 nut, two Stainless steel cut washer, Stainless steel M5 plain washer, Stainless steel M5 spring washer, φ4.2 copper wire, and Stainless steel M5 bolt. 1. Copper wires with M5 cupped washer should be placed through the bolt. 2. Put the cut washer through the bolt. The bolt must be placed through the designated hole in the aluminum frame. 3. Use the nut and the cut washer to secure all the parts. The copper wire can not be attached to the aluminum. 5
Do not interrupt or manipulate the conductive connection during daily maintenances. All crunodes on the conductive connection must be firmly attached. The fastness does not depend on soldering. Suggested Maximum Number of Modules in Parallel and in Series We recommend that the maximum number of modules in a parallel system should be no more than four modules. The maximum number of modules in a series system should be no more than eight. Mounting Each module must be securely fastened at a minimum of 6 points (14 mm 9 mm). The frame is stress tested for mounting on the long sides. Its short sides should not be securing the module. We recommend to use a torque wrench for installation. The tightening torque (using Stainless steel M6 bolts, Stainless steel washer, and Stainless steel M6 nut) should be around 15-20 Nm. Modules should be secured using existing holes. There is no need to drill any additional holes, which will automatically void the product warranty. Appropriate corrosion-proof fastening materials should be used. An open space between the module frame and the mounting surface may be required to prevent the junction box from touching the surface and to circulate cool air around the back of the module. We recommend the standoff method or the rack method if the modules are installed on a rooftop or a building wall. In the standoff method, the support for modules is parallel to the roof or building wall. An open space is also required between the frame and the mounting surface to prevent wiring damages and to allow air circulation to the back of the module. The recommended height for the standoff method is 115 mm. If other mounting methods are employed, the Listing for Fire Class Ratings may be affected. 6
1 3 2 Example for mounting the PV modules to a substructure: Clamping on (additional ground space may be required) 1. Stainless steel M6 nut 2. Stainless steel washer 3. Stainless steel M6 t-head bolt Installation on the Rooftop During rooftop and building wall installations, make sure that the modules are securely fastened. This will prevent modules from falling down in extreme weather. Please comply with safety standards and regulations and use the appropriate securing equipments. The back sides of modules need to be sufficiently ventilated to prevent any hydrometeor. A minimum distance of 50 mm needs to be observed between the installed planes and the back sides of modules. Wiring The modules use TYCO 1740971-1 type junction box, located on the back side of the module. This box is weather resistant and is compatible with standard wiring or conduit connections. Wiring methods should be in accordance with the NEC. Each module is packed with a set of bypass diodes and cable clamps. Correct Wiring Method In order to minimize the risk of an indirect lightning strike, avoid forming loops when designing the system. Check to make sure the wiring is correct before starting up the generator. If the measured open circuit voltage (UOC) and short-circuit current (ISC) differ from the specifications, then there is a wiring error. Correct Contact Plug Connections The plug connector has its own polarity. Make sure that the connection is safe and secure. The plug connector should not receive external stresses. Otherwise, it can only be used in circuit connections. 7
Use of Suitable Material Use cable extensions and plugs that are intended for outdoor use. Ensure that they are in perfect electrical and mechanical conditions. Use only cables that have one conductor. Select the appropriate cable diameter to minimize voltage drop (to calculate the minimum cable diameter and the fuse, and to calculate controls, multiply the UOC and ISC by a factor of 1.25). If the module is connected to the control box, the control box with Female type Connectors TYCO 1394462-2 and Male type Connectors TYCO 1394461-4 must be used. Bypass Diodes The type, voltage rating, current rating of the diodes are SL1515, 40V, 16A, respectively. The plastic material has an UL classification of 94V-0. Partial shading of an individual module can cause reverse voltage to occur across the shaded module. The electrical current is then forced through the shaded area by other modules. When a bypass diode is wired parallel with the series string, the forced current will flow through the diode and bypass the shaded module minimizing module heating and array losses of current. Diodes used as bypass diodes: Set a Rated Average Forward Current of 12A, above maximum system current at highest module operating temperature. Set a Rated Repetitive Peak Reverse Voltage 40V, above maximum system voltage at lowest module operating temperature. There are three bypass diodes per module and 20 cells per bypass diode Battery When charging batteries for solar modules, the battery must be installed in a proper manner to protect system performance and user safety. Keep the battery away from any human and animal traffic flows. Select a site that is well ventilated and protected from sunlight, rain, snow, and debris. Do not light matches or create sparks near battery banks, as explosion causing hydrogen gas is generated during the charging process. Outdoor installations of batteries should be in an insulated and ventilated protective case intended for this purpose. Maintenance and Cleaning Do not change the PV components without consultation (diode, junction box, plug connectors, and etc). Give modules a sufficient tilt of at least 15. Cleaning the modules is not necessary as rainfall will produce a self-cleaning effect. Heavy soiling on modules will result in output reductions. Do not scrape or rub away any dry soil accumulations, which will cause micro-scratch. We recommend cleaning modules with plenty of water from a hose. Do not use any cleaning agents, the use of a 8
gentle cleaning application such as a sponge is sufficient. The system should be inspected at regular intervals. Checklists All connecting points are tight, secure, and free of corrosion. All cable connections are secure, tight, clean and free of corrosion. Cables should not be damaged in any manner. Check module frame s conductivity to the earth. Danger of Death from Electrical Shocks! Solar modules generate electricity immediately after exposure to sunlight. A single module on its own is below the extra low voltage safety level. When multiple modules are connected in series (adding up the voltage) or in parallel (adding up the current), a potential danger is present. The following points must be observed when handling the solar modules to avoid risks of fire, sparks, and fatal electric shocks. Do not insert electrical conducting parts into plugs or sockets. Do not fit solar modules and wiring with wet plugs and sockets. Exercise utmost caution when carrying out work on wiring and safety equipments. Appropriate protective gears should be used when applicable. Do not use modules if they are damaged in any manner. Do not dismantle modules. Do not mark the rear of modules using sharp objects. Exercise utmost caution when working on wiring and the inverter. Be sure to follow manufacturer s installation instructions carefully. Artificially concentrated sunlight should not be directed at modules or panels at any time. Danger of Death from Arcing! Modules generate current under direct sunlight. An arc may be produced when connections are separated. Thus, we recommend covering modules with a lightproof cloth during installation. When breaking a connected string of modules (e.g. disconnecting the DC line from the inverter under load), a lethally strong arc can occur: Never disconnect the solar generator from the inverter when the inverter is still connected to the main grid remove the fuse from the AC side on the inverter first. Ensure cable connections are in perfect condition (no splitting, soiling, or other contamination). Remark: All sizes are measured in mm, with a tolerance of ±2 mm. 9
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