WO2011026381A1 - 供电电源的缓启动电路 - Google Patents

供电电源的缓启动电路 Download PDF

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Publication number
WO2011026381A1
WO2011026381A1 PCT/CN2010/074945 CN2010074945W WO2011026381A1 WO 2011026381 A1 WO2011026381 A1 WO 2011026381A1 CN 2010074945 W CN2010074945 W CN 2010074945W WO 2011026381 A1 WO2011026381 A1 WO 2011026381A1
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Prior art keywords
unit
power supply
control
start circuit
slow start
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PCT/CN2010/074945
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English (en)
French (fr)
Inventor
石鸿斌
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中兴通讯股份有限公司
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Publication of WO2011026381A1 publication Critical patent/WO2011026381A1/zh

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    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02MAPPARATUS FOR CONVERSION BETWEEN AC AND AC, BETWEEN AC AND DC, OR BETWEEN DC AND DC, AND FOR USE WITH MAINS OR SIMILAR POWER SUPPLY SYSTEMS; CONVERSION OF DC OR AC INPUT POWER INTO SURGE OUTPUT POWER; CONTROL OR REGULATION THEREOF
    • H02M1/00Details of apparatus for conversion
    • H02M1/36Means for starting or stopping converters

Definitions

  • the present invention relates to the field of power supply control technologies, and in particular, to a slow start circuit for a power supply.
  • a power supply power supply is uniformly supplied to each board through a backboard, and each board is provided with an energy storage unit at a power input port of the board for its own working stability requirement.
  • the energy storage unit is connected to the power supply, which brings an instantaneous power-on surge current, which often causes an instantaneous drop of the power supply voltage, which affects the stability of other boards of the system.
  • the whole device is powered on, it will also cause an instantaneous drop of the power supply voltage, which affects the working stability of other devices.
  • a metal oxide semiconductor (MOS) transistor is connected in series, and the voltage between the gate and the source (GS) of the MOS transistor is controlled by a slow charging circuit, and the MOS transistor is slowly turned on, but the scheme is At the expense of a large amount of heat loss of the MOS tube, when faced with a large-capacity energy storage unit, it is not sufficient to suppress the power-on surge current.
  • a power slow-start circuit on the one hand, when the power is on, on the one hand, the input current can slowly increase, and the impact on the system power supply is reduced as much as possible. On the other hand, it is hoped that normal operation allows large current to pass normally, and the circuit is lost. As low as possible.
  • the problem to be solved by the present invention is to provide a slow start circuit for a power supply to solve the contradiction and the need for a large current caused by an excessive input current when the power is turned on, and a large current when the power is normal. High cost problem.
  • a slow start circuit for a power supply is provided.
  • the slow start circuit of the power supply is disposed between the power supply and the main unit, and an input end of the main unit is connected to an output end of the power supply, and the slow start circuit comprises: a switch a unit, a current limiting unit, an energy storage unit and a control unit; the switching unit and the current limiting unit are connected in parallel, and a front end of the parallel branch is connected to another output end of the power supply, and a rear end of the parallel branch Connecting to one end of the energy storage unit and another input end of the main unit; the other end of the energy storage unit is connected to the one output end of the power supply; the control unit, the first The end is connected to the control end of the switch unit, and the second end thereof is connected to the control end of the main unit; wherein the control unit controls the off and on of the switch unit to control the power supply pair The main unit performs power supply.
  • the current limiting unit when the power supply is initially powered, the current limiting unit is used to limit the maximum current allowed to flow, thereby avoiding the impact current of the power-on of the board; meanwhile, the switching unit is allowed to pass a large current, thereby ensuring The current required for normal operation, because the current limiting unit only works when the power supply is initially powered up, the loss caused by current limiting is negligible, and the static loss of the switching unit is small, so the loss of the entire slow start circuit is very small.
  • the capacity of the energy storage unit is not limited, so that the card can provide an energy storage unit of any capacity according to actual needs.
  • FIG. 1 is a schematic block diagram of a slow start circuit of a power supply according to an embodiment of the present invention
  • FIG. 2 is a structural diagram of a slow start circuit of a power supply according to an embodiment of the present invention.
  • DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The core idea of the present invention is: when the power supply is initially powered, the current limiting unit is used to limit the maximum current allowed to flow, thereby avoiding the impact current of the board power-on; and at the same time, the switching unit allows a large current to pass, thereby The current required for normal operation is guaranteed, since the current limiting unit is only powered When the power supply is initially powered up, the loss caused by current limiting is negligible, and the static loss of the switching unit is small, so the loss of the entire slow start circuit is very small.
  • An embodiment of the present invention provides a slow start circuit for a power supply, as shown in FIG.
  • the circuit comprises: a switching unit, a current limiting unit, an energy storage unit and a control unit; wherein, the switching unit and the current limiting unit are connected in parallel, and the front end 4 of the parallel branch is connected to the output end 1 of the power supply, and the rear end of the parallel branch 5 is connected to one end 8 of the energy storage unit and the input end 10 of the main unit; the energy storage unit, the other end 9 of which is connected to the output end 2 of the power supply; the control unit, the first end 6 of which is connected to the control end 3 of the switch unit
  • the second end 7 is connected to the control end 12 of the main unit; the control unit controls the off and on of the switch unit to control the power supply to supply power to the main unit.
  • the slow start circuit further includes an effusion unit in parallel with the energy storage unit.
  • the effusion unit can be a resistor device or a diode.
  • the control unit controls the turning off and conducting of the switch unit, including: when the power supply is powered, the control unit controls the switch unit to be turned off, the main unit is in a closed state, and the energy storage unit is charged via the current limiting unit; After the charging is completed, the control unit controls the switching unit to be turned on, and controls the main unit to be turned on.
  • the switch unit may be a relay or an optocoupler switch.
  • the current limiting unit may be another resistance device.
  • the energy storage unit may be a capacitor.
  • the control unit may be an electromechanical management unit or a delay control circuit.
  • the power supply provided by the example is The structure diagram of the slow start circuit is set between the power supply and the main module power supply in the board, the main module power supply in the board is the main unit, and the input end 11 of the main module power supply in the board is connected to the power supply
  • the output is -48VRTN.
  • the slow start circuit comprises: a switch unit is a switch S l , a current limiting unit is a resistor R1 , an energy storage unit is a capacitor C1 and a control unit; wherein, the switch S 1 and the resistor R1 are connected in parallel, and the front end 4 of the parallel branch is connected to the power supply
  • the output end of the power supply is -48V
  • the rear end 5 of the parallel branch is connected to one end 8 of the capacitor C1 and the input end 10 of the main module power supply in the board
  • the capacitor C1 has the other end 9 connected to the output end of the power supply -48VRTN
  • a control unit having a first end 6 connected to the control terminal 3 of the switch S1 and a second end 7 connected to the control terminal 12 of the main module power supply in the board; the control unit controls the switching off and on of the switch S1 to Control the power supply to supply power to the main module power supply in the board.
  • the switch S 1 when the power supply is initially powered, the switch S 1 is turned off, and the capacitor C1 is charged via the resistor R1; at this time, the resistor R1 defines the allowable input. The maximum current avoids the inrush current of the board.
  • the control unit controls the switch S1 to be turned on, and then the main module power supply in the control panel is turned on, and the main module power supply in the board is powered via the switch S1. Since the switch S 1 allows a large current to pass, the current required for normal operation is secured.
  • the resistor R1 Since the resistor R1 only works during the power-on period, the loss caused by the current limiting is negligible; the static loss of the switch S 1 is small, so the loss of the entire slow-start circuit is very small.
  • the capacity of the capacitor C1 is not limited, so that the card can provide any capacity of capacitance according to actual needs. Capacitor C 1 is used for energy storage. According to the power supply of the main module in the board and the system needs, the capacitor value can be selected, such as 220uF. In combination with the input power supply of -48V, the withstand voltage can be 100V. In combination with the above requirements, aluminum electrolytic capacitors with appropriate parameters are generally selected.
  • Resistor R1 is used for current limiting, and its resistance determines the maximum inrush current Imax when the power supply is powered.
  • the selection of resistor R1 mainly considers the heat dissipation limit.
  • the power resistor is better, which can be subjected to greater heat loss, such as ceramic resistor 680 ⁇ -10 ⁇ .
  • the corresponding maximum inrush current is about 70 mA, and the maximum heat dissipation of the resistor is about 3.5 W. . Assuming that the number of boards in the entire system is 50, the maximum power-on surge current of the entire system is only 3.5A.
  • the charging time constant of the capacitor C 1 is 150ms, taking 4 times the time constant, and only Charging can reach 98% in 600ms.
  • Switch SI optional relay such as 48VDC electromagnetic relay, its rated working current and other parameters can be selected according to the actual needs of the board.
  • the control unit can be implemented in a variety of ways, generally in combination with a system solution. If the board itself has an organic power management unit, it can be programmed by the electromechanical management unit to control the switch S 1 and the power of the main module in the board.
  • a delay circuit such as a resistor-capacitor circuit can also be designed to perform the above control.
  • the control unit can control the power of the switch S 1 and the main module in the board through the optical device.
  • a resistor of a suitable resistance can be connected in parallel with the capacitor C1 so that the capacitor C1 can quickly discharge the charge when the card is pulled out, and the magnitude of the resistance depends on the desired discharge time.
  • the current limiting unit when the power supply is initially powered, the current limiting unit is used to limit the maximum current allowed to flow, thereby avoiding the impact current of the power-on of the board; meanwhile, the switching unit is allowed to pass a large current, thereby ensuring normal operation.
  • the current required for the operation since the current limiting unit only works when the power supply is initially powered up, the loss caused by the current limiting is negligible, and the static loss of the switching unit is 4 ,, so the loss of the entire slow start circuit is very small.
  • the capacity of the energy storage unit is not limited, so that the card can provide an energy storage unit of any capacity according to actual needs.
  • the solution of the present invention is not limited to the applications listed in the specification and the embodiments. Various changes and modifications can be made by those skilled in the art to which the present invention pertains, and all such changes and modifications are within the scope of the appended claims.

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  • Engineering & Computer Science (AREA)
  • Power Engineering (AREA)
  • Direct Current Feeding And Distribution (AREA)

Description

供电电源的緩启动电路 技术领域 本发明涉及电源控制技术领域, 尤其涉及一种供电电源的緩启动电路。 背景技术 在板卡式设备中, 供电电源经由背板统一给各板卡供电, 各板卡出于自 身工作稳定性要求, 在板内电源输入口设置有储能单元。 各板卡在插板上电 时, 该储能单元接入供电电源, 带来瞬间上电冲击电流, 常会造成供电电源 电压的瞬间跌落, 影响系统其他板卡的工作稳定性。 在设备整体上电时, 同 样会造成供电电源电压的瞬间跌落, 影响其他设备的工作稳定性。 为保持系统工作的稳定性, 常于板内电源输入口提供緩启动电路, 以减 緩板卡上电对供电电源的冲击, 目前常用的方案有如下两种: 第一、 串入热敏电阻之类器件, 使输入电流緩慢增长, 但该方案抑制电 流增速效果非常小, 应用性差。 第二、 串入金属氧化物半导体 (Metal Oxid Semiconductor, 简称为 MOS) 管, 通过緩充电电路控制 MOS 管门极 -源极 (GS ) 间电压上升, 緩步打开 MOS管, 但该方案是以 MOS管的大量热耗为代价的, 面对大容量储能单元 时, 则不足以抑制上电冲击电流。 作为电源緩启动电路, 一方面希望刚上电时, 输入电流能够緩慢增长, 尽可能降氐对系统电源的冲击; 另一方面, 又希望正常工作时, 允许大电流 的正常通过, 且电路损耗尽可能低。 然而, 釆用上述两种常用的方案, 无法 解决刚上电时输入电流过大对供电电源造成的冲击和工作正常时需要大电流 的矛盾的问题, 并且耗能较大。 发明内容 本发明要解决的问题是提供一种供电电源的緩启动电路,以解决现有技 术中刚上电时输入电流过大对供电电源造成的冲击和工作正常时需要大电流 的矛盾以及能耗高的问题。 根据本发明, 提供了一种供电电源的緩启动电路。 根据本发明的供电电源的緩启动电路,设置在所述供电电源和主体单元 之间, 所述主体单元的一个输入端连接至所述供电电源的一个输出端, 所述 緩启动电路包括: 开关单元、 限流单元、 储能单元和控制单元; 所述开关单元和所述限流单元并联,其并联支路的前端连接至所述供电 电源的另一个输出端, 其并联支路的后端连接至所述储能单元的一端和所述 主体单元的另一个输入端; 所述储能单元, 其另一端连接至所述供电电源的所述一个输出端; 所述控制单元, 其第一端连接至所述开关单元的控制端, 其第二端连接 至所述主体单元的控制端; 其中, 所述控制单元控制所述开关单元的关断和导通, 以控制所述供电 电源对所述主体单元进行供电。 在本发明提供的技术方案中, 在供电电源初始供电时, 利用限流单元限 制允许流入的最大电流, 避免了板卡上电的冲击电流影响; 同时, 利用开关 单元允许大电流通过, 从而保障了正常工作所需的电流, 由于限流单元只在 供电电源初始上电时工作, 限流带来的损耗可忽略不计, 开关单元静态损耗 又很小, 故整个緩启动电路的损耗非常小。 此外, 储能单元的容量不受限制, 使得板卡可根据实际需要提供任意容量的储能单元。 附图说明 图 1是本发明实施例提供的一种供电电源的緩启动电路的原理框图; 图 2是本发明实施例提供的一种供电电源的緩启动电路的结构图。 具体实施方式 本发明的核心思想在于: 在供电电源初始供电时, 利用限流单元限制允 许流入的最大电流, 避免了板卡上电的冲击电流影响; 同时, 利用开关单元 允许大电流通过, 从而保障了正常工作所需的电流, 由于限流单元只在供电 电源初始上电时工作, 限流带来的损耗可忽略不计, 开关单元静态损耗又艮 小, 故整个緩启动电路的损耗非常小。 此外, 储能单元的容量不受限制, 使 得板卡可根据实际需要提供任意容量的储能单元。 下面结合附图及优选实施方式对本发明技术方案进行详细说明。 本发明实施例提供了一种供电电源的緩启动电路, 如图 1所示, 设置在 供电电源和主体单元之间,该主体单元的输入端 11连接至供电电源的输出端 2 , 该緩启动电路包括: 开关单元、 限流单元、 储能单元和控制单元; 其中, 开关单元和限流单元并联,其并联支路的前端 4连接至供电电源的输出 端 1 ,其并联支路的后端 5连接至储能单元的一端 8和主体单元的输入端 10; 储能单元, 其另一端 9连接至供电电源的输出端 2 ; 控制单元, 其第一端 6连接至开关单元的控制端 3 , 其第二端 7连接至 主体单元的控制端 12 ; 控制单元控制开关单元的关断和导通,以实现控制供电电源对主体单元 进行供电。 进一步地, 该緩启动电路还包括与该储能单元并联的泻流单元。 其中, 该泻流单元可以是一电阻器件或二极管。 进一步地, 控制单元控制开关单元的关断和导通, 包括: 供电电源供电时,控制单元控制开关单元关断,主体单元处于关闭状态 , 该储能单元经由限流单元充电; 在储能单元充电完成后, 控制单元控制开关 单元导通, 并控制主体单元开启。 进一步地, 该开关单元可以是继电器或光耦开关。 进一步地, 该限流单元可以是另一电阻器件。 进一步地, 该储能单元可以是电容。 进一步地, 该控制单元可以是机电管理单元或延时控制电路。 下面通过一个具体示例对上述实施例进行详细的描述,但该示例并不构 成对本发明保护范围的限制。 具体地, 如图 2所示为本示例提供的供电电源 的緩启动电路的结构图, 该緩启动电路设置在供电电源与板内主模块电源之 间, 该板内主模块电源即为主体单元, 该板内主模块电源的输入端 11连接至 供电电源的输出端 -48VRTN。 该緩启动电路包括: 开关单元为开关 S l、 限流 单元为电阻 Rl、 储能单元为电容 C1和控制单元; 其中, 开关 S 1和电阻 R1并联, 其并联支路的前端 4连接至供电电源的输出 端 -48V, 其并联支路的后端 5连接至电容 C1的一端 8和板内主模块电源的 输入端 10; 电容 C1 , 其另一端 9连接至供电电源的输出端 -48VRTN ; 控制单元, 其第一端 6连接至开关 S 1的控制端 3 , 其第二端 7连接至 板内主模块电源的控制端 12; 控制单元控制开关 S 1元的关断和导通, 以控制供电电源对板内主模块 电源进行供电。 下面对图 2所示的电路的工作原理进行详细的描述, 具体地, 在供电电 源初始供电时, 开关 S 1关断, 经由电阻 R1给电容 C1充电; 此时, 电阻 R1 限定了允许输入的最大电流, 避免了板卡上电的冲击电流。 在电容 C1 完成 充电后, 控制单元控制开关 S 1 导通, 然后控制板内主模块电源开启, 经由 开关 S 1给板内主模块电源供电。 由于开关 S 1允许大电流通过, 从而保障了 正常工作所需的电流。 由于电阻 R1 只在刚上电时段工作, 限流带来的损耗 可忽略不计; 开关 S 1 静态损耗又很小, 故整个緩启动电路的损耗非常小。 此外, 本示例中, 电容 C1 的容量大小不受限制, 使得板卡可根据实际需要 提供任意容量的电容。 其中, 电容 C 1用来储能, 可根据板内主模块电源以及系统需要选择合 适容值, 如 220uF, 结合本示例输入电源为 -48V的条件, 耐压值可选 100V。 结合上述要求, 一般选合适参数的铝电解电容。 电阻 R1 用于限流, 其阻值大小决定供电电源供电时的最大冲击电流 Imax。 电阻 R1选型主要考虑热耗限制。 在本示例中, 选择功率电阻较好,它 能 受更大的热耗, 如陶瓷电阻器 680 Ω-10λν, 此时, 对应的最大冲击电流 则约为 70mA, 电阻最大热耗约为 3.5W。假定整个系统的板卡数量为 50块, 则整个系统的最大上电冲击电流仅为 3.5A。 以电阻 Rl=680 欧姆, 电容 Cl=220uF为例, 电容 C 1充电时间常数为 150ms , 取 4倍时间常数, 也只需 600ms即可达到充电 98%。 开关 S I可选继电器, 如 48VDC电磁继电器, 其额定工作电流等参数 可根据板卡实际需要降额选择。 控制单元可以有多种实现方式, 一般结合系统方案选择。 若板卡本身有 机电管理单元, 可交由机电管理单元编程控制开关 S 1 以及板内主模块电源 的开启。 若板卡没有机电管理单元, 也可设计延时电路, 例如电阻电容电路 以完成上述控制。 为满足电源隔离要求, 控制单元可通过光藕器件实现对开 关 S 1和板内主模块电源的控制。 进一步地, 可以和电容 C 1并联一个合适阻值的电阻, 以便在拔卡时电 容 C1可快速泻放电荷, 其阻值大小取决于期望的放电时间。 在本发明实施例中, 在供电电源初始供电时, 利用限流单元限制允许流 入的最大电流, 避免了板卡上电的冲击电流影响; 同时, 利用开关单元允许 大电流通过, 从而保障了正常工作所需的电流, 由于限流单元只在供电电源 初始上电时工作, 限流带来的损耗可忽略不计, 开关单元静态损耗又 4艮小, 故整个緩启动电路的损耗非常小。 此外, 储能单元的容量不受限制, 使得板 卡可根据实际需要提供任意容量的储能单元。 本发明所述方案, 并不仅仅限于说明书和实施方式中所列运用。 对本发 明技术所属领域的普通技术人员来说, 可才艮据本发明故出各种相应的改变和 变形, 而所有这些相应的改变和变形都属于本发明权利要求的保护范围。

Claims

权 利 要 求 书
1. 一种供电电源的緩启动电路, 设置在所述供电电源和主体单元之间, 所述主体单元的一个输入端(11)连接至所述供电电源的一个输出端 (2), 其特征在于, 所述緩启动电路包括:
开关单元、 限流单元、 储能单元和控制单元;
所述开关单元和所述限流单元并联,其并联支路的前端 (4)连接至 所述供电电源的另一个输出端 ( 1 ), 其并联支路的后端 (5)连接至所述 储能单元的一端 (8)和所述主体单元的另一个输入端(10);
所述储能单元,其另一端 (9)连接至所述供电电源的所述一个输出 端 (2);
所述控制单元, 其第一端 (6)连接至所述开关单元的控制端 (3) , 其第二端 (7)连接至所述主体单元的控制端(12);
其中, 所述控制单元, 用于控制所述开关单元的关断和导通, 以 控制所述供电电源对所述主体单元进行供电。
2. 如权利要求 1 所述的緩启动电路, 其特征在于, 所述緩启动电路还包 括与所述储能单元并联的泻流单元, 用于使所述储能单元泻放电荷。
3. 如权利要求 2所述的緩启动电路, 其特征在于, 所述泻流单元为一电 阻器件或二极管。
4. 如权利要求 1至 3中任一项所述的緩启动电路, 其特征在于,
所述控制单元, 用于在所述供电电源供电时, 控制所述开关单元 关断, 控制所述主体单元处于关闭状态, 以使所述储能单元经由所述 限流单元进行充电, 在所述储能单元充电完成后, 控制所述开关单元 导通, 并控制所述主体单元开启。
5. 如权利要求 1至 3 中任一项所述的緩启动电路, 其特征在于, 所述开 关单元为继电器或光 开关。
6. 如权利要求 1至 3 中任一项所述的緩启动电路, 其特征在于, 所述限 流单元为一电阻器件。
7. 如权利要求 1至 3 中任一项所述的緩启动电路, 其特征在于, 所述储 能单元为电容。
8. 如权利要求 1至 3 中任一项所述的緩启动电路, 其特征在于, 所述控 制单元为机电管理单元或延时控制电路。
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