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| | *Overcharge protection and gassing functions must be temperature-compensated for high-charge-disconnect and high-charge-reconnect thresholds in two-point regulation, whereas the hysteresis must be constant (temperature range: -10°C to 55°C). The temperature compensation must be in the range of -3 to -5 mV/K/cell. | | *Overcharge protection and gassing functions must be temperature-compensated for high-charge-disconnect and high-charge-reconnect thresholds in two-point regulation, whereas the hysteresis must be constant (temperature range: -10°C to 55°C). The temperature compensation must be in the range of -3 to -5 mV/K/cell. |
| | *Own power consumption should not amount to more than 10 mA under all operating states. | | *Own power consumption should not amount to more than 10 mA under all operating states. |
| − | *The voltage drop at the terminals of the charge regulator between battery- and loadterminals (discharging) and between PV-generator terminals and battery terminals (charging) may only amount to a maximum of 0.5 V (12 V systems) or 1 V (24 V systems) at maximum load. | + | *The voltage drop at the terminals of the charge regulator between battery- and loadterminals (discharging) and between PV-generator terminals and battery terminals (charging) may only amount to a maximum of 0.5 V (12 V systems) or 1 V (24 V systems) at maximum load. |
| | *The voltage drop on the battery-lines shall be compensated by either battery sensing lines, electronic compensation or appropriate wire selection (cross-section, length). If electronic compensation is applied, the difference between battery terminal voltage and demanded thresholds of the charge regulator should not exceed 100 mV. | | *The voltage drop on the battery-lines shall be compensated by either battery sensing lines, electronic compensation or appropriate wire selection (cross-section, length). If electronic compensation is applied, the difference between battery terminal voltage and demanded thresholds of the charge regulator should not exceed 100 mV. |
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| − | <u>Mechanical Parameters, Performance and Requirements</u> | + | <u>Mechanical Parameters, Performance and Requirements</u> |
| − | *Mechanical stability of all components shall be tested by vibrations test (acc. to IEC 60068-2-6, stringency, see proposed standard) and | + | |
| − | *Shock test (acc. to IEC 60068-2-27, stringency, see proposed standard) when specimens are not packaged and not live. | + | *Mechanical stability of all components shall be tested by vibrations test (acc. to IEC 60068-2-6, stringency, see proposed standard) and |
| − | *Temperature and humidity resistance shall be defined and tested in accordance with the climatic conditions of the target region (IEC 60068-1). | + | *Shock test (acc. to IEC 60068-2-27, stringency, see proposed standard) when specimens are not packaged and not live. |
| − | *For application in tropical climates, a “cyclical damp heat test” (acc. to IEC 60068-2-30) will be performed with temperatures up to 55°C (not live) and 40°C (at nominal voltage and maximum input and output current). | + | *Temperature and humidity resistance shall be defined and tested in accordance with the climatic conditions of the target region (IEC 60068-1). |
| − | *Corrosion resistance and long-term stability will be evaluated after this damp heat test. | + | *For application in tropical climates, a “cyclical damp heat test” (acc. to IEC 60068-2-30) will be performed with temperatures up to 55°C (not live) and 40°C (at nominal voltage and maximum input and output current). |
| − | *Safety requirements shall be evaluated according to IEC 60335-1. | + | *Corrosion resistance and long-term stability will be evaluated after this damp heat test. |
| − | *Insulation resistance shall be tested according to EN 50178 or IEC 60335-1 (section 13.3) with a test voltage of 500 VDC. | + | *Safety requirements shall be evaluated according to IEC 60335-1. |
| − | *Heat development under maximum power conditions shall not exceed the limits stated in IEC 60335-1. | + | *Insulation resistance shall be tested according to EN 50178 or IEC 60335-1 (section 13.3) with a test voltage of 500 VDC. |
| − | *Resistance to heat and fire shall be tested according to IEC 60695-2-1 (glow-wire test) and EN 60742, section 26 (ball-pressure test). | + | *Heat development under maximum power conditions shall not exceed the limits stated in IEC 60335-1. |
| − | *Mechanical sturdiness of the case shall be tested according to IEC 60068-2-75 (stringency, see proposed standard) with a dead stroke hammer of 250 g from certain directions. | + | *Resistance to heat and fire shall be tested according to IEC 60695-2-1 (glow-wire test) and EN 60742, section 26 (ball-pressure test). |
| | + | *Mechanical sturdiness of the case shall be tested according to IEC 60068-2-75 (stringency, see proposed standard) with a dead stroke hammer of 250 g from certain directions. |
| | *The protection of the case against access to dangerous parts, penetration of foreign bodies and the entry of water (IP code) shall be tested according to IEC 60529. The minimum requirements are IP 20 for solid-built indoor applications and IP 54 for outdoor and other applications. | | *The protection of the case against access to dangerous parts, penetration of foreign bodies and the entry of water (IP code) shall be tested according to IEC 60529. The minimum requirements are IP 20 for solid-built indoor applications and IP 54 for outdoor and other applications. |
| − | ''Comment: This draft standard proposes a protection code of IP 20, which means "no protection against water intrusion". This does not seem to provide for adequate protection in developing countries, even in solidly built houses, as the roofs of these buildings are often not as water-tight as they are expected to be in industrialised countries. The author recommends a minimum protection code of IP 32.'' | + | |
| | + | ''Comment: This draft standard proposes a protection code of IP 20, which means "no protection against water intrusion". This does not seem to provide for adequate protection in developing countries, even in solidly built houses, as the roofs of these buildings are often not as water-tight as they are expected to be in industrialised countries. The author recommends a minimum protection code of IP 32.'' |
| | + | |
| | *The robustness of terminations and mounting devices shall be tested according to IEC 61215, test 10.14, for expansion, thrust, bending, pressure, torsion and twisting. | | *The robustness of terminations and mounting devices shall be tested according to IEC 61215, test 10.14, for expansion, thrust, bending, pressure, torsion and twisting. |
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| − | <u>Abnormal Operation Precautions</u> | + | <u>Abnormal Operation Precautions</u> |
| − | *At operation without a battery, the charge regulator will limit the output voltage at the load terminals to the maximum permissible output voltage during battery operation. If relays are included in the circuit, they must stay in a stable condition. | + | |
| − | *At operation with an extremely exhausted battery (Ubatt < 9V), a further discharge of the battery must be avoided. | + | *At operation without a battery, the charge regulator will limit the output voltage at the load terminals to the maximum permissible output voltage during battery operation. If relays are included in the circuit, they must stay in a stable condition. |
| − | *If voltage-measuring (sensor) lines are used, the stability of all thresholds must be guaranteed with open-circuited and shorted measuring lines. | + | *At operation with an extremely exhausted battery (Ubatt < 9V), a further discharge of the battery must be avoided. |
| − | *If temperature sensor lines are used, the stability of all thresholds must be guaranteed with open circuited and shorted measuring lines. | + | *If voltage-measuring (sensor) lines are used, the stability of all thresholds must be guaranteed with open-circuited and shorted measuring lines. |
| − | *The charge regulator must be protected against reverse polarity at the PV generator (up to maximum open circuit voltage) and the battery terminals (up to maximum battery voltage). | + | *If temperature sensor lines are used, the stability of all thresholds must be guaranteed with open circuited and shorted measuring lines. |
| − | *Overload protection by fuses or electronic circuits shall be tested with 125% of the maximum load current. | + | *The charge regulator must be protected against reverse polarity at the PV generator (up to maximum open circuit voltage) and the battery terminals (up to maximum battery voltage). |
| | + | *Overload protection by fuses or electronic circuits shall be tested with 125% of the maximum load current. |
| | *If the charge regulator has a separate radio outlet, its overload protection shall also be checked. | | *If the charge regulator has a separate radio outlet, its overload protection shall also be checked. |
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| − | <u>Electromagnetic Compatibility (EMC)</u> | + | <u>Electromagnetic Compatibility (EMC)</u> |
| − | *Line-conducted interference emission shall be tested at least on the output (load) line in the radio-frequency range from 150 kHz to 30 MHz (acc. to EN 50081-1, limit value class B). | + | |
| − | *Irradiated interference emission at a distance of 3 meters shall be tested in accordance with EN 55013, limit values acc. to IEC CISPR 22. | + | *Line-conducted interference emission shall be tested at least on the output (load) line in the radio-frequency range from 150 kHz to 30 MHz (acc. to EN 50081-1, limit value class B). |
| − | *Resistance to interference from fast, low-energy pulses (pulse group), coming from the load-side (e.g. energy-saving lamps), will be tested according to IEC 61000-4-4 (0.5 kV). | + | *Irradiated interference emission at a distance of 3 meters shall be tested in accordance with EN 55013, limit values acc. to IEC CISPR 22. |
| − | *Resistance to interference from single high-energy impulses, like atmospheric discharges (lightning), will be measured on the PV generator-to-regulator and on the load-to-regulator line according to IEC 61000-4-5 with 0.5 kV to 1 kV. Additionally, the pulse influence on the connecting lines between solar generator, battery and load | + | *Resistance to interference from fast, low-energy pulses (pulse group), coming from the load-side (e.g. energy-saving lamps), will be tested according to IEC 61000-4-4 (0.5 kV). |
| − | should be determined. | + | *Resistance to interference from single high-energy impulses, like atmospheric discharges (lightning), will be measured on the PV generator-to-regulator and on the load-to-regulator line according to IEC 61000-4-5 with 0.5 kV to 1 kV. Additionally, the pulse influence on the connecting lines between solar generator, battery and load should be determined. |
| − | *Optional: Resistance to interference due to electromagnetic fields shall be tested in reference to IEC 61000-4-3 (required field strength 3 V/m), only if portable or nonportable transmitters are expected to influence the operation of the charge regulator. | + | |
| | + | *Optional: Resistance to interference due to electromagnetic fields shall be tested in reference to IEC 61000-4-3 (required field strength 3 V/m), only if portable or nonportable transmitters are expected to influence the operation of the charge regulator. |
| | *Optional: Resistance to interference from electrostatic discharge measurements are only required if touching the equipment by operators or other persons is expected to influence the operation of the charge regulator (IEC 61000-4-2, stringency: 8 kV air discharge). | | *Optional: Resistance to interference from electrostatic discharge measurements are only required if touching the equipment by operators or other persons is expected to influence the operation of the charge regulator (IEC 61000-4-2, stringency: 8 kV air discharge). |
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| − | <u>Test Report</u> | + | <u>Test Report</u> All test results must be documented and summarised in a test report, which can be requested from the supplier or manufacturer by the tendering institution. |
| − | All test results must be documented and summarised in a test report, which can be requested from the supplier or manufacturer by the tendering institution. | + | |
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| − | <u>Marking, Labels:</u> | + | <u>Marking, Labels:</u> The charge regulator must be clearly labelled, displaying the following information: |
| − | The charge regulator must be clearly labelled, displaying the following information: | + | |
| − | *Original signs (trademark, name of manufacturer or name of responsible dealer) | + | *Original signs (trademark, name of manufacturer or name of responsible dealer) |
| − | *Model number or type designation of the manufacturer | + | *Model number or type designation of the manufacturer |
| − | *Serial number | + | *Serial number |
| − | *Nominal voltage (V) | + | *Nominal voltage (V) |
| − | *Maximum PV generator (input) current (A) | + | *Maximum PV generator (input) current (A) |
| − | *Maximum load (output) current (A) | + | *Maximum load (output) current (A) |
| − | *All connecting terminals must be clearly labelled with function and polarity. | + | *All connecting terminals must be clearly labelled with function and polarity. |
| − | *All displays must be clearly labelled with the meaning of the indication. | + | *All displays must be clearly labelled with the meaning of the indication. |
| | *Characteristic type and value of fuses must be written near the fuse holder. | | *Characteristic type and value of fuses must be written near the fuse holder. |
| | | | |
| − | <u>Documentation:</u> | + | <u>Documentation:</u> The documentation delivered with the charge regulator must contain the following information and data: |
| − | The documentation delivered with the charge regulator must contain the following information and data: | + | |
| − | *Installation instructions | + | *Installation instructions |
| − | *Operating instructions | + | *Operating instructions |
| − | *Technical data | + | *Technical data |
| − | *Troubleshooting instructions | + | *Troubleshooting instructions |
| − | *Safety warnings | + | *Safety warnings |
| − | *Information on spare parts | + | *Information on spare parts |
| | *Warranty | | *Warranty |
| | | | |
| − | In particular, the documentation must indicate the following data: | + | In particular, the documentation must indicate the following data: |
| | | | |
| − | <u>Environmental Conditions:</u> | + | <u>Environmental Conditions:</u> |
| − | *Range of operating temperature | + | |
| − | *Range of storage temperature | + | *Range of operating temperature |
| | + | *Range of storage temperature |
| | *Maximum relative humidity | | *Maximum relative humidity |
| | | | |
| − | <u>Physical properties of the charge regulator:</u> | + | <u>Physical properties of the charge regulator:</u> |
| − | *Case dimensions | + | |
| − | *Weight | + | *Case dimensions |
| − | *Case properties (material) | + | *Weight |
| − | *Degree of protection (IP Code) | + | *Case properties (material) |
| − | *Fasteners, fixing material | + | *Degree of protection (IP Code) |
| − | *Connecting terminals, maximum cable size | + | *Fasteners, fixing material |
| − | *Cables (inlet, strain relief, cross-sections) | + | *Connecting terminals, maximum cable size |
| | + | *Cables (inlet, strain relief, cross-sections) |
| | *Spare parts | | *Spare parts |
| | | | |
| − | <u>Electrical properties of the charge regulator:</u> | + | <u>Electrical properties of the charge regulator:</u> |
| − | *Nominal voltage (V) | + | |
| − | *Maximum PV-generator current (A) | + | *Nominal voltage (V) |
| − | *Maximum load current (A) | + | *Maximum PV-generator current (A) |
| − | *Type of regulator (series regulator, shunt regulator) | + | *Maximum load current (A) |
| − | *Working principle (PWM, two-point-regulation, state of charge algorithm) | + | *Type of regulator (series regulator, shunt regulator) |
| − | *All used thresholds (V) | + | *Working principle (PWM, two-point-regulation, state of charge algorithm) |
| − | *Temperature compensation for the thresholds (mV/°C/celI) | + | *All used thresholds (V) |
| − | *Service life | + | *Temperature compensation for the thresholds (mV/°C/celI) |
| − | *Own consumption | + | *Service life |
| − | *Losses | + | *Own consumption |
| − | *Overload protection | + | *Losses |
| − | *Reverse-polarity protection | + | *Overload protection |
| − | *Capability of switching to accommodate different nominal voltages | + | *Reverse-polarity protection |
| − | *Warning before load disconnect | + | *Capability of switching to accommodate different nominal voltages |
| − | *Delayed load disconnection | + | *Warning before load disconnect |
| − | *Displays (LED's, display, accuracy) | + | *Delayed load disconnection |
| | + | *Displays (LED's, display, accuracy) |
| | *Additional functions (MPP tracking, etc.) | | *Additional functions (MPP tracking, etc.) |
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The charge regulator (or Battery Control Unit, BCU) shall primarily serve to protect the battery against both deep discharging and overcharging.
As soon as this standard is released, the tender specification for charge regulators might be formulated as follows:
Charge regulators should have been type-tested and certified for qualification in compliance with IEC 6xxxx (number not yet available by November 1999) “Photovoltaic Systems, Charge Regulators, Part 1: Safety Test - Requirements and Procedures, Part 2: EMC - Test Requirements and Procedures and Part 3: Performance - Test Requirements and Procedures”.
The following tests must be performed and documented as described in the standardproposal Part 1, 2 and 3. After a visual inspection of the charge regulator, the documentation and labelling, the following electrical, mechanical, abnormal-operation and EMC parameters will be determined according to the described procedures.
