This part specifies the special requirements for ballasts for high-pressure mercury lamps, low-pressure sodium lamps, high-pressure sodium lamps and metal halide lamps. This part applies to ballasts using 50Hz or 60Hz AC power below 1000V. The rated power, size and characteristics of the discharge lamps matched with it shall comply with the provisions of IEC60188, IEC60192 and IEC60662. This part applies to complete ballasts and their components, such as reactors, transformers and capacitors. GB 19510.10-2004 Lamp control gear Part 10: Special requirements for ballasts for discharge lamps (except fluorescent lamps) GB19510.10-2004 Standard download decompression password: www.bzxz.net

[CS 29.140.99
National Standard of the People's Republic of China
GB19510.10——2004/IFC61347-2-9;2003CB14045—1993
Lamp controlgearPart 10, Particular requirements for ballasts for discharge lamps (except fluorescent lamps) (IEC 61347-2-9.2003, IDT)
2004-05-10 Issued
General Administration of Quality Supervision, Inspection and Quarantine of the People's Republic of China Standardization Administration of China
2005-02-01 Implementation
Normative references
Requirements
Test instructions
Measures to prevent accidental contact with live parts
According to the wire
Nuclear ground installation
Moisture-proof and insulation·
Medium Electric strength
Preheat test of winding
Ignition limit of ballast
High voltage pulse test
Fault condition
Structure
Electrical components and electrical test
Screws, flow parts and connectors
Heat resistance, fire resistance and sliding resistance
Appendix A (Thermal Standard Appendix)
Appendix B (Control Appendix)
Appendix core (Normative Appendix)
Appendix D (Normative Appendix)||t Appendix E (normative appendix)
Appendix F (normative appendix)
Appendix (normative appendix)
Appendix H (normative requirements)
Appendix 1 (normative appendix)
Appendix J (informative excerpt)
G19510.10—2004/E61347-2-9,2003 Reagents for determining whether conductive parts are live parts that may cause electric shock Special requirements for control devices of thermally protected expansion lamps and their applications Self-connection devices for lamps with protective devices Special requirements for the heating test of thermally protected lamps in this test are as follows: The constant S of 4530 is used in the "Energy Identification Test" test using a convection wind protection box. The method for determining the impulse voltage value is as follows: The voltage value of the selected ballast group is determined by the ballast temperature. Figure 1. Test circuit for ballast for lamps with integral starting devices. 2. Ballast heating test sheet. Figure J.3 Ballast heating test layout. Table 2: Limit values ​​of winding shortness of ballasts subjected to 30-day durability test under abnormal working conditions and 10% rated output voltage. Table 3: Limit values ​​of winding shortness of ballasts subjected to 60-day durability test under abnormal working conditions and 110% rated voltage. All technical contents of this part are mandatory. Foreword G19.11 ton lamp control devices are divided into 12 parts: Part 1: General requirements and safety requirements Part 2: Special requirements for automatic devices (except light automatic devices); GE 19510. 10—2004/1KC: 61347-2-9:2003 Part 1: Special requirements for current/inter-filter electronic voltage converters for calcium line lamps! ：…Part 4: Special requirements for direct current electronic ballasts for fluorescent lamps Part 6: Special requirements for direct current electronic ballasts for public transportation lighting equipment Part 7: Special requirements for direct current electronic ballasts for aircraft lighting Part 8: Special requirements for direct current electronic ballasts for emergency lighting Part 9: Special requirements for direct current electronic ballasts for fluorescent lamps Part 11: Special requirements for inverters and frequency converters for commercial frequency cold start tubular lamps (wide angle lamps) Part 12: Special requirements for miscellaneous electronic ballasts for lamps This part is the third part of the control device of B151 lamp. This part should be used together with GB195:0.1. It is formulated after supplementing or modifying the corresponding clauses of GB19510.1.
This part is equivalent to IEC61347-2-S:2900 lamp control system - Part 29: Particular requirements for current locks for discharge lamps (other than fluorescent lamps) and the 2003 revision 1 (English rate). This part is equivalent to the reprint of IEC613-7-2-5, 2000203 revision 1. For ease of use, this standard has made the following editorial changes: a) \IEC61347-2-9\ is changed to \this part\, \IEC61347-2-9 standard\-- is changed to \GB19510.19" b) In addition to the foreword of ECS1347-2-9, the preface of IEC6:34725 is changed: "(Note>\ brackets in the form of international standards are removed, and the decimal point is replaced by \" as the decimal point; For other international standards cited in TEC61347-1, 2003, some of them are temporarily adopted as Chinese standards. These international standards are used to replace the relevant standards. The rest of the standards that have not been equivalent to them and are adopted as Chinese standards are directly used in this part (Section 2 of this part). This part replaces GB14045-193 General requirements and safety requirements for burners for discharge lamps (except tubular flame lamps). The main differences between this part and GA14045-1933 are as follows: a) The technical requirements and test methods of this part are combined into one chapter according to the test items, and the two chapters of technical requirements and test methods are no longer divided. Some requirements and tests of this part refer to the corresponding requirements of Part 1, and only some requirements are added: The vehicle part stipulates the requirements for inspection, storage and transportation before purchase! The second column title of Table 2 in GB14045-1933 is changed to the second column title of Table 1 under 115% rated voltage. GB19510.10 is one of the national standards for control devices: The following lists the expected structure of these national standards and their corresponding international standards, as well as the national standards that will be replaced: CB15510.1 Lamp control devices Part 2: Requirements and safety requirements E4Y1GH1S51, 2 Lamp control devices Part 2: Special requirements for dynamic devices (other than glow starters) August
GB195F0.10-204/IEC61347-2-9:2003 (TEL: S1347-2-1):
GB19510.3 Lamp strip control devices Part 1: Special requirements for DC/AC electronic step-down converters for zinc filament lamps 3 (IHC 5134722):
CB1510.4 Lamp control device Part 4, Particular requirements for AC electronic ballasts for northern lamps 3 (1EC5134723. Code #GH16143-1994);
G19510.5≤ Lamp empty installation
1E 61347 2-4):
Part 3: Particular requirements for DC electronic ballasts for public lighting 3 Part 6, Particular requirements for DC ballasts for lighting of public transport vehicles 3B1U510. Lamp control device
(IFC G1347-2-5)
B19510. Lamp control device
(1H 61347 # 61;
Part 7: Special requirements for DC electronic ballasts for use in outdoor lighting 3GB110.8 Type and installation of lamps
Part 9: Special requirements for DC electronic ballasts for emergency lighting 3 (IEC 1347-2-7):
GB195IC.9 Lamp control devices Part 9: Special requirements for ballasts for industrial lamps 3 (IEC.1847-2.R, replacing GF2313-1593
GB1S5SIU.0 Lamp control devices Part 1S, Maintenance requirements for ballasts for emergency lighting (except fluorescent lamps) 3 (IEC1347.29. replacing GR14943-1993]);||t GB195513.11 Lamp control devices Part 11: Special requirements for inverters and frequency converters for cold-start discharge lamps (radian lamps) (IEC6134720): GB19551.12 Lamp control devices Part 12: Special requirements for inverters for lamps using miscellaneous neutron circuits [IEC62347-2-11]. Appendix A, Appendix C, Appendix E, Appendix F, Appendix G of this part.Appendix H and Appendix I are the appendixes of the specification. The power part is submitted by China Light Industry Federation. This part is under the jurisdiction of the National Technical Committee for Standardization of Lighting Electric Energy (CSBTS/TC224). The drafting units of this part are: Fuzhou Yaming Electric Co., Ltd., Philips Yaming Exhibition Lighting Co., Ltd., Shanghai Shuangdeng Lighting Electric Co., Ltd., National Electric Light Source Quality Supervision and Inspection Center (Shanghai), Wujiang Huafeng Electric Co., Ltd., Philips Ximing Electronics (Shanghai) Co., Ltd., Jiangyang Guangcai Group Co., Ltd. Beijing Electric Light Source Research Institute, Shanghai Wenming Lighting Electric Co., Ltd. The main drafters of this part are: Zhang Hequan, Zhang Yiku, Huang Wen, Zhang Lianming, Cheng Shuiping, Qian An, Yu Shuizhuang, Kang Shukuai, Kang Shuo, Wu Guosi, Mei Suhui, Yang Xiaoping, Ye Jimei, and the previous versions of the standard that has not been replaced by this part are published for the first time in 2017. This is the first revision. Introduction
GB19510.10—2004/1t:61347-2-9.2003 This part and the various parts constituting R19510.2~R19510.12 specify the scope of application of the clauses and the sequence of changes in the provisions when any clause of GB19510.1 is cited, and also specify the necessary supplementary requirements. The various parts of GB1950.2~GT:510.12 are independent of each other and refer to each other. If this part refers to a requirement of CB15510.1 by the sentence "according to a requirement of GB1351U.1", this sentence means that all requirements of that clause are followed, except for the narrow scope of control devices of certain types of lamps described in R19510.2--GH19510.12.
GB19510.10-2004/1EC 61347-2-9.2003 Lamp control devices =
Part 10: Particular requirements for ballasts for discharge lamps (other than fluorescent lamps) This part specifies the special requirements for ballasts for commercial volt-free lamps, low-voltage galvanic lamps, sodium-iron lamps and pyrolysis lamps. This part is applicable to ballasts with an output voltage of 1 V or less using 5UHz or H20 for AC/DC current. The efficiency, dimensions and electrical connections of the matching high-efficiency induction lamps shall comply with the provisions of IEC60188, IEC60192 and IEC60662. This part is applicable to complete ballasts and components or parts thereof, such as reactors, capacitors and capacitors. The special requirements for thermally protected ballasts are given in Appendix H.
III 1: Gland type discharge lamps require a distributor, 2. For filament lamps, see GE1051C.6. Performance requirements are listed in 1E60923.
2 Normative references
The following documents are used in this part of G9510 and become the terms of this part. The referenced documents are dated, and all subsequent revisions (excluding errors, etc.) or sub-editions are not applicable to this provisional part. However, the parties to this agreement on this part will study whether the latest versions of these documents can be used. For any undated referenced documents, the latest versions apply to this part.
This part adopts the normative references given in Chapter 2 of G1951.1 to place the following normative references: GB 9510.1 Control of lamps Part 1: Requirements (GB9510.12004.IEC6.3-7-1.2063, [DT)
IEC60188
Commercial pressure mercury lamp
1EC60132 Low pressure lazy lamp
1EC 61662 Commercial pressure discharge lamps
Performance requirements for external ballasts for discharge lamps (fluorescent lamps IEC609231
EC61347-2-1.2U00, Part 2 - Static: Special requirements for dynamic control devices (except glow starters) 3 Definitions
This part adopts the definitions described in Chapter 3 of GB15510.1 and the following definitions. 3.1
The fixed temperature rise of the ballast Temperamental ureris:uf bnllnstInding The source rise determined by the manufacturer under the conditions specified in this section. For the requirements and installation conditions of the first device, see Appendix H. 3.2
High-voltage impulse
A transient voltage that is applied for a period of time. When the voltage is applied, it is quickly raised to a selected value, and then slowly reduced to zero. This pulse is generally expressed as the sum of two exponentials. The "pulse" in the technical field is distinguished from the "current demand". The latter refers to the limited change of the power grid of the electrical equipment produced by the Kobe cattle during use. 4-millisecond requirements
Extracted from Chapter 4 of GB195_0.1 and the following requirements, 1
GB19510.10—2004/1EC 61347-2-8:20034.1 Capacitors and other components
Capacitors and other components installed in ballasts shall comply with the requirements of the standard. 4.2 Thermally protected ballasts
Requirements for thermally protected ballasts Appendix B.
5 Test instructions
According to Chapter 5 of GB19510.1 and the following requirements: 5. 1
Type tests shall be carried out on individual ballasts or a batch of products submitted for type tests. Seven of the ballasts shall be subjected to heat resistance tests and one ballast shall be subjected to full tests on the others. For qualified conditions for heat resistance tests, refer to the requirements of Chapter 13. For ballasts for sodium fluoride lamps and high-pressure sodium lamps, six additional ballasts shall be subjected to total voltage pulse tests in accordance with the requirements of Chapter 15. No unqualified products shall appear during the test. 5.2
The tests shall be carried out under the conditions specified in Appendix H of GB10510.1. During the test, each type of ballast shall be subjected to a rate test. If a batch of similar ballasts is involved, the liquid Each rated power ballast in the batch shall be tested, or representative ballasts shall be selected from the batch for testing in consultation with the manufacturer. When a batch of ballasts with the same structure but different performance are submitted for inspection, if the test report of the manufacturer is accepted by the inspection department, the number of samples for heat resistance test according to the requirements of Section 13 and the use of permanent ballasts different from 45UU shown in the research record is allowed to be reduced, and these tests can even be omitted. Requirements of the classification and license (R19510: Section 6: 7 Markings Ballasts as part of lamps do not need to be marked. For ballasts installed in the outlet socket of street lamps, all the marks listed in 1 and 2 should be marked on the ballast. The marking should comply with the provisions of 7 and 2 in G1910.1. 7.1 Mandatory markings
Locked current devices (excluding built-in ballasts) shall be clearly and permanently marked with the following mandatory markings: For current devices used together with transmitters (IEC61917-1), the terminals (terminal mounting plate) for carrying pulse voltages shall be marked on the current devices.
Note: This marking may be in the form of technical drawings, and the simple charging method for high-voltage lamps and some metal-oxide lamps does not need to be used in this way.
7.2 Supplementary markings
In addition to the mandatory markings mentioned above, the following additional markings shall be placed on the inverter or in the manufacturer's product specifications or in the instructions:
Required contents of GB19510.147.1); - For high-voltage lamps used with metal halide lamps: 1) If the maximum peak value of the inductive impulse withstand by the nanoinverter exceeds 1590V, this value shall be marked; 2) For the product of the trigger used with the nanoinverter: : For inverters composed of more than one independent component, the main components of the components shall be marked on the components that control the current:
- For For ballasts with a test document (not enough to remove the large cable cable), the rated voltage and capacitance should be repeated. CB19510.10-2004/C61347-2-9.2003 For multi-small ballasts installed in lamp holders and wiring basins, the installation suggestions to help prevent the ballast and related parts from being over-stable should be marked. 7.3 Other signs The manufacturer can provide the following applicable non-mandatory signs: The rated temperature rise of the winding is estimated to be 5K. After the mark and mark, 8. Prevent accidental contact with live parts. According to the requirements of GB19510.1, Section 11. 9. Terminals According to the requirements of GB19510, Section 1.
10 Grounding device
According to the requirements of CB1U510,1, etc., Chapter 9,
11 Moisture-proof and insulation
According to the requirements of GB19510.1 Chapter 11. t2 Dielectric strength
According to the requirements of GB19510.1 Chapter 12.
In addition, for the dry current group using the trigger and the pulse voltage generated inside it, the reverse dielectric strength test should also be carried out on the insulation that withstands the double voltage. The test voltage is shown in the following table (- working voltage) pulse voltage.
and strong ground
base ground and supplementary ground
13 Heat resistance test of potential group
According to the requirements of GB1951U.1 Chapter 13.
14 Ballast thermal limit Www.bzxZ.net
21 00
Inductive impulse voltage> 1.414
Cpen/J. 4J4+2 7id V
/2x1. 4-1
The ballast and its mounting surface shall not produce temperatures that impair its safety. The ballast and its mounting surface shall be tested in accordance with the tests of 14.1 and 4.2 and the H.12 test of G1951.1.
14.1 When the ballast is tested in accordance with the requirements of 14.2, the temperature under normal and abnormal conditions shall not exceed the corresponding values ​​shown in G1.
Before the test, the following inspections and measurements shall be carried out:) The ballast shall start and operate normally. () If necessary, the voltage of the cable group shall be measured at the ambient temperature. At the end of the heating test, the ballast will reach room temperature. At this time, the ballast should meet the following requirements: 1) The marking of the ballast is still clearly visible: 3
GB19510.10-2004/EC61947-2-9.2003b) The ballast shall be subjected to the dielectric strength test in Chapter 12 without being damaged, but the test voltage shall be 75% of that shown in Table 1 of GB19510.1, but not less than 500V. 14.2 Place the ballast under normal conditions for testing. If required, place the ballast at: 10°C and rated voltage Operate at a fixed switching rate until the temperature reaches the rated value, but if there is a / mark, verify the marked value at the rated current. For tests under normal conditions, the ballast should be operated with suitable lamps. The lamps should be located so that the heat they produce will not affect the heating of the ballast. If, under the specified test conditions, the current through these lamps is within the same range as the current through the reference lamp, these lamps can be considered as abnormal lamps. For tests under abnormal conditions, the ballast is connected to the output and the lubrication terminals of the lamps are short-circuited to simulate the ballast being able to operate under abnormal conditions. Short circuit method, for the test line of the national type ballast and the lamp in the school cabinet with appropriate resistance to the test and the combustion of the lamp, it is necessary to carry out special tests and the combustion of the lamp is not fluctuating, that is: the actual value of the lamp under the rated current is 110%. For the non-reduced resistance ballast diagram, the full account is guaranteed to reach the level of the original position,
Note 2: The ballast (not required) and the appropriate lamp are connected together in the power supply to achieve the specified frequency and then the measurement is carried out. In this case, the impedance line is trapped and the current is excited. (Find the current resistance of the commercial sheet associated with the lamp), the test control and measurement can be carried out without the lamp installed. The test should be carried out under the temporary power supply. Table 1 Maximum temperature
Maximum temperature!
Indicates the ballast energy group without position
Indicates the ballast group with abnormal high standard value
and the end liquid capacitor and the external filling part: without temperature mark
Normal mark
Various materials and components:
Technical filling group with fuel pressure components
Inorganic block material acid evaporation pressure part | |tt||The department does not accept the parts
Secure parts
The parts
Thermal insulation materials
The normal operation of the ballast under the rated voltage
10G! In the case of the abnormal band of the rated voltage
1: If the manufacturing method of the materials used is different from that listed in the table, their working temperature and pressure shall not be higher than the permitted temperature of the test materials already specified. 2: When the ballast is operated at its nominal maximum ambient temperature When working, the flux values ​​shown in the table are obtained based on a 25% ambient temperature. The residual voltage of the system group under the working condition of 1X% is intended to exceed the range indicated on the certificate. It is not necessary to carry out this measurement only when there is a mark on the lead or other requirements in the product indication. This flux can only be carried out in a state of abnormality. The range limit of the energy group is not allowed to be higher than 3/3 of the b
number under the permanent pregnancy test theory. Low (invalid 2, Table 5) In addition to the insulation layer of the conductor, the plasticity of the conductor used for the connection with the conductor or the live part is also determined when the humidity is: For example, the test conditions of 18.1 in GB191C.1 are established according to the use case, 15
S
High voltage pulse test
GB19510.10-2004/IEC61347-2-9:2003 Table 2 The 30-day durability test of the conductor under abnormal working conditions and 110 rated voltage can be limited to two uses||t t||Ballasts with "[6\" standard state shall be subjected to 60-day endurance test with winding conduction limit value and temperature limit under abnormal working conditions and 110% rated voltage. The load connected to the ballast for metal halide lamps and high-pressure sodium lamps will impose high pulses on the ballast. Therefore, the ballast shall withstand the test specified in 15.1 or 15.2. There are two types of ballasts. The ballasts designed to work in the circuit with an external starting device for the lamp shall be subjected to the test specified in 15.1; the ballasts designed to work with an internal starting device for the lamp shall be subjected to the test specified in 15.2. The manufacturer shall state which test is applied to his product.
CB 19510,10—2004/KC: 61347-2-9;200315.1 Connect a 20pF negative capacitor to the six ballasts in 5.1 to make them work with the trigger and measure the pulse voltage. After that, the trigger is removed and the dielectric strength of the parts subjected to pulse voltage is tested in the following manner. Another similar trigger is used together with the ballast at a rated voltage of 1.1°C for 30 days without any capacitor or ground connection. If the trigger fails before 30 days, the damaged trigger shall be replaced in time. From 30 days after the test, the ballast with the mark indicating that only the trigger with delayed pulse off setting is used (see the explanation of item 2 in the second item of 7.2) shall be subjected to the same test, except that the test period is 2% of the on-off cycle and the off time is at least 2mn. After the test, the dielectric strength test specified in Chapter 12 shall be carried out. During the test, all terminals except the ground conductor shall be connected together. No arcing or breakdown shall occur. Then, the original trigger and 20F load capacitance shall be connected again and the pulse voltage shall be measured. The measured value shall not differ from the initial measured value by more than 10% or 15%. 2 For three of the six samples in 5.1, subject them to the tests for protection against corrosion and erosion and the test for electrical strength required in Clauses 11 and 12. Heat the remaining three samples in an oven until the material reaches the rated temperature indicated on the ballast. Immediately after these pre-conditioning tests, subject all samples to the following high-voltage impulse test. Connect the ballast under test, a variable resistor and a utility relay (e.g. H1G or VR312/412 vacuum switch) with a closing time (excluding bounce time) of %mR~15m to a direct current source. By adjusting the current and operating the resistor, a voltage pulse is generated in the ballast. Then slowly adjust the current so that the current increases to the peak voltage indicated on the ballast and measure the voltage impulse at the terminals of the ballast in accordance with the requirements of Note 1 and Figure 1. Note 1: If the electronic ballast is used for a very short time, the impulse voltage should be higher than that specified in the specification. The DC current value when the starting voltage is reached should be recorded, and then the sample should be operated at this current for 1 hour. During this period, the power should be disconnected 10 times per minute, and the disconnection time for each time is 35. After the test is completed, all six ballast samples shall be immediately subjected to the anti-sealing and cross-over performance tests and dielectric display tests specified in Chapters 11 and 12.
Note 2: The use of ballasts other than single-circuit ballasts is still under investigation. 16 Fault state
does not comply with the requirements of Chapter 14 of GB19510.1. 17 Anchor structure
According to the requirements of GB19510.1 Chapter 13. 18 Distance between lighting and electrical space
According to GB1510.1 Chapter 15 and the following requirements: In parallel core current transformers, the insulation layer of the conductor can withstand the first or second level test in Chapter 13 of IEC60317-0-1, and the paint or similar materials can be regarded as equivalent to 1mm when calculating the distance between different groups of enameled wires or between enameled wires and shells and cores according to the values ​​shown in Table 3 and Table 4 of IEC60510.1. However, this calculation can only be used when the creepage distance and electrical clearance are not less than 2mm except for the paint coating. 10 Screws, electrical components and connectors
According to the requirements of Chapter 17 of IEC60515.1
20 Heat resistance, fire resistance and electrical shock resistance
According to the requirements of GB19510,1 Chapter 18,
21 Corrosion resistance
According to the requirements of CB19510,1 Chapter 15.
Appendix 4
(Normative Appendix)
CB19510.10—2004/IEC: 61347-2-9:2003 The test for determining whether a thick electric part is a live part that may cause electric shock shall be in accordance with the requirements of Appendix A of GB9510.1.
Appendix B
(Normative Appendix)
Special requirements for the control device of thermally protected lamps shall be in accordance with the requirements of Appendix B of GB2510.1 and the following requirements: The manufacturer of the current generator shall submit samples that have been specially treated for type testing. Appendix C
(Normative Appendix)
Special requirements for electronic control devices of lamps with thermal protection shall not be in accordance with the requirements of Appendix C of GF19510.1. Appendix C
(Normative Appendix)
The heat protection device of heat protection lamps shall comply with the requirements of Appendix D of GB19510.1.
Appendix E
(Normative Appendix)
The application of the band number S less than 4500 in the t, (group penetration) test shall comply with the requirements of GB19510.1.
Appendix F
(Normative Appendix)
Anti-convection wind test
According to the requirements of GB191C.
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