WO2013071768A1 - 三相交流电源相位识别装置 - Google Patents

三相交流电源相位识别装置 Download PDF

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Publication number
WO2013071768A1
WO2013071768A1 PCT/CN2012/078702 CN2012078702W WO2013071768A1 WO 2013071768 A1 WO2013071768 A1 WO 2013071768A1 CN 2012078702 W CN2012078702 W CN 2012078702W WO 2013071768 A1 WO2013071768 A1 WO 2013071768A1
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Prior art keywords
phase
isolation unit
power supply
load
output
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PCT/CN2012/078702
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English (en)
French (fr)
Inventor
李丹
戴彬传
张伟
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中兴通讯股份有限公司
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Publication of WO2013071768A1 publication Critical patent/WO2013071768A1/zh

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    • GPHYSICS
    • G01MEASURING; TESTING
    • G01RMEASURING ELECTRIC VARIABLES; MEASURING MAGNETIC VARIABLES
    • G01R29/00Arrangements for measuring or indicating electric quantities not covered by groups G01R19/00 - G01R27/00
    • G01R29/18Indicating phase sequence; Indicating synchronism

Definitions

  • the utility model relates to the field of mobile communication, in particular to a three-phase alternating current power source phase identification device. Background technique
  • the quality of the three-phase AC power supply is unaffected by the load.
  • the actual power supply has a certain output impedance
  • the output voltage will be distorted, resulting in pollution of the power grid and degradation of the power supply quality. If the phase of the load can be judged, and then the configuration of each phase load can be guided, that is, the pollution of the power grid to the power grid can be artificially reduced.
  • the utility model provides a three-phase alternating current power supply phase identification device, which solves the problem that the prior art cannot judge the phase of the load in the three-phase alternating current power supply.
  • the utility model provides a three-phase alternating current power supply phase identification device, which comprises: a state selector, an isolation unit, a power supply and a signal processing unit; wherein
  • a state selector connected to the positive pole of the load output voltage, according to a predetermined setting, the control circuit is closed and opened, and the output end is connected to the second input end of the isolation unit;
  • the isolation unit includes two input ends and two output ends, wherein the first input end is connected to the negative pole of the load output voltage, the second input end is connected to the state selector, and the first output end is connected to the pull-up resistor One end of the signal processing unit and the second output end are grounded for isolating signals that are not common; a power supply, connected to the other end of the pull-up resistor;
  • the signal processing unit is connected to the first output end of the isolation unit, and determines the phase of the load according to the high level signal or the low level signal output by the isolation unit.
  • a current limiting resistor is disposed between the state selector and the isolation unit.
  • the number of state selectors is two or more, and the number of isolation cells is two or more.
  • each state selector is connected to a second input of the respective isolation unit.
  • the state selector is a switching device.
  • the switching device is a DIP switch.
  • the isolation unit is an optocoupler.
  • the signal processing unit is a Digital Signal Processor (DSP).
  • DSP Digital Signal Processor
  • the load is a rectifier.
  • the three-phase AC power phase identification device is mounted on the backplane of the rectifier unit.
  • the beneficial effects of the utility model are as follows:
  • One phase of the three-phase AC power source outputs a DC voltage through a load, and the DC voltage is respectively selected and isolated by the state of the state selector and the isolation unit of the three-phase AC power phase recognition device, and respectively output corresponding high and low level signals. And being sent to the signal processing unit, the signal processing unit can determine the phase of the load in the three-phase power supply according to the state of the level signals, and solve the problem that the phase of the load in the three-phase AC power source cannot be judged in the prior art.
  • the three-phase AC power phase recognition device according to the embodiment of the present invention is simple in design, easy to implement, and low in cost, and can be applied to all occasions where it is necessary to identify the phase of the three-phase AC power source.
  • FIG. 1 is a schematic structural view of a phase identification device for a three-phase alternating current power supply according to an embodiment of the present invention
  • FIG. 2 is a process flow diagram of a phase identification device for a three-phase alternating current power supply according to an embodiment of the present invention
  • FIG. 3 is a schematic diagram of a phase of a three-phase AC power supply connected to a rectifier carrying a three-phase AC power phase recognition device according to an embodiment of the present invention
  • FIG. 4 is a schematic diagram of a phase of a three-phase alternating current power source B connected to a rectifier carrying a three-phase alternating current power source phase identification device according to an embodiment of the present invention
  • Fig. 5 is a schematic view showing a phase of a three-phase alternating current power source C connected to a rectifier carrying a three-phase alternating current power source phase identification device according to an embodiment of the present invention.
  • the utility model provides a three-phase AC power phase recognition device, which can realize the load in the system powered by the three-phase AC power source.
  • the detection of the phase, and the structure is simple, the cost is low, and the implementation is easy.
  • FIG. 1 is a schematic structural diagram of a three-phase AC power phase recognition device according to an embodiment of the present invention, as shown in FIG.
  • the three-phase AC power phase recognition device of the embodiment includes: a state selector 10, an isolation unit 12, a power supply 14, and a signal processing unit 16.
  • a state selector 10 an isolation unit 12
  • a power supply 14 an isolation unit 14
  • a signal processing unit 16 a signal processing unit 16.
  • the state selector 10 is connected to the positive pole of the load output voltage, and the control circuit is closed and disconnected according to a predetermined setting, and the output end thereof is connected to the second input end of the isolation unit 12; preferably, in the embodiment of the present invention
  • the state selector 10 may be any switching device capable of controlling the closing and opening of the loop, for example, a DIP switch or the like; the load may be a rectifier.
  • the isolation unit 12 includes two input ends and two output ends, wherein the first input end is connected to the negative pole of the load output voltage, and the second input end is connected to the state selector 10, and the first output end is connected One end of the pull-up resistor is connected to the signal processing unit 16, and the second output end is grounded for isolating the signal that is not common.
  • the isolation unit 12 can be an optocoupler or other device that satisfies the isolation requirement.
  • a current limiting resistor is disposed between the state selector 10 and the isolation unit 12.
  • the number of the state selectors 10 may be two or more, and the number of the isolation units 12 may be two or more.
  • Each state selector 10 is connected to a second input of a respective isolation unit 12, respectively.
  • the power supply 14 is connected to the other end of the pull-up resistor for providing a high level and a low level to the output of the isolation unit 12 through the pull-up resistor;
  • the signal processing unit 16 is connected to the first output end of the isolation unit 12 for determining the phase of the load according to the high level signal or the low level signal output by the isolation unit 12.
  • the signal processing unit 16 can be a DSP.
  • the three-phase AC power phase recognition device can be mounted on the backplane of the rectifier unit.
  • FIG. 2 is a schematic diagram of a processing flow of a three-phase AC power phase recognition device according to an embodiment of the present invention.
  • a phase of a three-phase AC power source outputs a DC voltage through a rectifier.
  • the DC voltage is selected and isolated by the state selector and the isolation unit in the phase identification device of the three-phase AC power source, respectively outputting corresponding high and low level signals, and sent to the signal processing unit, and the signal processing unit according to the level signals
  • the state of the load can be judged as the phase of the load in the three-phase power supply, and the recognition result is output.
  • the application scenario of this embodiment is the phase identification of the rectifier unit in the communication power source, and the phase identification device is installed on the backplane of the rectifier unit that supplies the phases of the three-phase AC power source to realize the judgment of the phase of the load, and the judgment result is obtained. Report to the monitoring system for easy query and display.
  • FIG. 4 is a schematic diagram of a rectifier carrying a three-phase AC power phase recognition device connected to a phase of a three-phase AC power source
  • FIG. 4 is a schematic diagram of a phase of a three-phase AC power source connected to a rectifier carrying a three-phase AC power phase identification device according to an embodiment of the present invention
  • FIG. 5 is a schematic diagram of a rectifier connected to a three-phase AC power source C phase with a three-phase AC power phase recognition device according to an embodiment of the present invention, as shown in FIG. 3, FIG. 4, and FIG.
  • the switch K1 of the phase identification device needs to be turned off according to a predetermined setting, and K2 is closed, so the output signal N1 is high level, and N2 is low power. level.
  • the switch K3 of the phase identification device needs to be closed according to a predetermined setting, and K4 is turned off, so the output signal N3 is low level, and N4 is high power. level.
  • the switch K5 of the phase identification device needs to be closed according to a predetermined setting, and K6 is closed, so the output signal N5 is low level, and N6 is low level. .
  • the N1-N6 signals detected by the rectifiers are sent to the DSP.
  • the DSP judges the phase of the rectifier according to the logic in Table 1, and uploads the judgment result to the monitoring unit, so the customer can remotely check the phase of the rectifier and allocate it reasonably. Each phase is loaded.
  • the signal processing unit can determine the phase of the load in the three-phase power supply according to the state of the level signals.
  • the utility model selects and isolates the DC voltage of one phase of the three-phase AC power source through the load, and selects and isolates the states of the plurality of state selectors and the isolation unit in the phase identification device of the three-phase AC power source, respectively outputting corresponding electric power
  • the signal is signaled to the signal processing unit, and the signal processing unit determines the phase of the load in the three-phase power source based on the state of the level signal.
  • the utility model can solve the problem that the phase of the load in the three-phase AC power source cannot be judged in the prior art; and the design is simple, easy to implement, and low in cost, and can be applied to all phases that need to identify the phase of the three-phase AC power source. occasion.

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  • Physics & Mathematics (AREA)
  • General Physics & Mathematics (AREA)
  • Testing Of Short-Circuits, Discontinuities, Leakage, Or Incorrect Line Connections (AREA)
  • Emergency Protection Circuit Devices (AREA)

Abstract

一种三相交流电源相位识别装置,包括:状态选择器(10),连接于负载输出电压的正极,根据预定设置控制电路的闭合与断开;隔离单元(12),包括两个输入端和两个输出端,其中,第一输入端连接于负载输出电压的负极,第二输入端连接于状态选择器(10),第一输出端连接上拉电阻的一端和信号处理单元(16),第二输出端接地,对不共地信号进行隔离;供电电源(14),连接于上拉电阻的另一端;信号处理单元(16),连接于隔离单元(12)的第一输出端,根据隔离单元(12)输出的高电平信号或低电平信号判定负载的相位。该装置设计简单、易于实现、成本低廉,可以应用于所有需要识别三相交流电源相位的场合。

Description

三相交流电源相位识别装置 技术领域
本实用新型涉及移动通讯领域, 特别是涉及一种三相交流电源相位识 别装置。 背景技术
在理想情况下, 三相交流电源的供电质量是不受负载影响的。 但是, 由于实际电源具有一定的输出阻抗, 若三相交流电源的三相负载不平衡, 会导致输出电压发生畸变, 造成电网的污染和供电质量的下降。 如果能够 对负载所在相位进行判断, 进而对各相负载的配置起到指导作用, 即可以 人为的减小用电设备对电网的污染。
在现有技术中, 只能够对三相电源相序进行判断或单相电源相位角进 行检测, 并不能对由三相交流电源供电的系统中负载所在相位进行识别。 发明内容
本实用新型提供一种三相交流电源相位识别装置, 以解决现有技术不 能够对三相交流电源中负载所在的相位进行判断的问题。
本实用新型提供一种三相交流电源相位识别装置, 该装置包括: 状态 选择器、 隔离单元、 供电电源和信号处理单元; 其中,
状态选择器, 连接于负载输出电压的正极, 根据预定设置控制电路的 闭合与断开, 其输出端连接于隔离单元的第二输入端;
隔离单元, 包括两个输入端和两个输出端, 其中, 第一输入端连接于 所述负载输出电压的负极, 第二输入端连接于所述状态选择器, 第一输出 端连接上拉电阻的一端和信号处理单元, 第二输出端接地, 用于对不共地 信号进行隔离; 供电电源, 连接于上拉电阻的另一端;
信号处理单元, 连接于隔离单元的第一输出端, 根据隔离单元输出的 高电平信号或低电平信号判定负载的相位。
优选地, 状态选择器和隔离单元中间设置有一限流电阻。
优选地, 状态选择器的个数为两个或多个, 隔离单元的个数为两个其 中或多个。
优选地, 每个状态选择器分别连接于相应隔离单元的第二输入端。 优选地, 状态选择器为开关器件。
优选地, 开关器件为拨码开关。
优选地, 隔离单元为光耦。
优选地, 信号处理单元为数字信号处理器 (Digital Signal Processor, DSP )。
优选地, 负载为整流器。
优选地, 三相交流电源相位识别装置安装于整流器单体的背板上。 本实用新型有益效果如下:
三相交流电源中的某一相经负载输出直流电压, 该直流电压经过三相 交流电源相位识别装置若干路状态选择器和隔离单元的状态选择和隔离 后, 分别输出相应的高低电平信号, 并送入信号处理单元, 信号处理单元 根据这些电平信号的状态即可判断出负载处于三相电源中的相位, 解决了 现有技术中不能够对三相交流电源中负载所在的相位进行判断的问题, 根 据本实用新型实施例的三相交流电源相位识别装置设计简单、 易于实现、 成本低廉, 可以应用于所有需要识别三相交流电源相位的场合。 附图说明
图 1是本实用新型实施例的三相交流电源相位识别装置的结构示意图; 图 2是本实用新型实施例的三相交流电源相位识别装置的处理流程示 意图;
图 3是本实用新型实施例的携带有三相交流电源相位识别装置的整流 器连接三相交流电源 A相的示意图;
图 4是本实用新型实施例的携带有三相交流电源相位识别装置的整流 器连接三相交流电源 B相的示意图;
图 5是本实用新型实施例的携带有三相交流电源相位识别装置的整流 器连接三相交流电源 C相的示意图。 具体实施方式
为了解决现有技术不能够对三相交流电源中负载所在的相位进行判断 的问题, 本实用新型提供了一种三相交流电源相位识别装置, 可以实现由 三相交流电源供电的系统中负载所在相位的检测, 并且结构简单、 成本低 廉、 易于实现, 以下结合附图以及实施例, 对本实用新型进行进一步详细 说明。 应当理解, 此处所描述的具体实施例仅仅用以解释本实用新型, 并 不限定本实用新型。
根据本实用新型的实施例, 提供了一种三相交流电源相位识别装置, 图 1是本实用新型实施例的三相交流电源相位识别装置的结构示意图, 如 图 1 所示, 根据本实用新型实施例的三相交流电源相位识别装置包括: 状 态选择器 10、 隔离单元 12、 供电电源 14、 信号处理单元 16, 以下对本实 用新型实施例的各个模块进行详细的说明。
具体地, 状态选择器 10, 连接于负载输出电压的正极, 根据预定设置 控制回路的闭合与断开, 其输出端连接于隔离单元 12的第二输入端; 优选 地, 在本实用新型实施例中, 其中, 状态选择器 10可以是任何能够控制回 路的闭合与断开的开关器件, 例如, 拨码开关等; 负载可以为整流器。
隔离单元 12, 包括两个输入端和两个输出端, 其中, 第一输入端连接 于负载输出电压的负极, 第二输入端连接于状态选择器 10, 第一输出端连 接上拉电阻的一端和信号处理单元 16, 第二输出端接地, 用于对不共地信 号进行隔离;其中,隔离单元 12可以采用光耦或其他满足隔离要求的器件。
优选地, 状态选择器 10和隔离单元 12中间设置有一限流电阻。
此外, 状态选择器 10的个数可以为两个或多个, 隔离单元 12的个数 也可以为两个或多个。 每个状态选择器 10分别连接于相应隔离单元 12的 第二输入端。
供电电源 14, 连接于上拉电阻的另一端, 用于通过上拉电阻为隔离单 元 12输出端提供高低电平;
信号处理单元 16, 连接于隔离单元 12的第一输出端, 用于根据隔离单 元 12输出的高电平信号或低电平信号判断负载的相位。 所述信号处理单元 16可以为 DSP。
在本实用新型实施例中, 三相交流电源相位识别装置可以安装于整流 器单体的背板上。
在本实用新型实施例中, 图 2是本实用新型实施例的三相交流电源相 位识别装置的处理流程示意图, 如图 2所示, 三相交流电源中的某一相经 整流器输出直流电压, 该直流电压经过三相交流电源相位识别装置中的状 态选择器和隔离单元的状态选择和隔离后, 分别输出相应的高低电平信号, 并送入信号处理单元, 信号处理单元根据这些电平信号的状态即可判断出 负载处于三相电源中的相位, 输出识别结果。 以下结合实例, 以整流器为 例, 对本实用新型上述实施例进行详细的说明。
本实施例的应用场景为通讯电源中整流器单体的相位识别, 通过在三 相交流电源各相供电的整流器单体背板上安装相位识别装置, 实现对负载 所在相的判断, 并将判断结果上报监控系统, 便于查询和显示。
图 3、 图 4和图 5中, 负载为整流器, 状态选择器由两个开关组成, 状态选择器与隔离单元之间连接限流电阻。 其中, 图 3是本实用新型实施 例的携带有三相交流电源相位识别装置的整流器连接三相交流电源 A相的 示意图, 图 4是本实用新型实施例的携带有三相交流电源相位识别装置的 整流器连接三相交流电源 B相的示意图, 图 5是本实用新型实施例的携带 有三相交流电源相位识别装置的整流器连接三相交流电源 C相的示意图, 如图 3、 图 4、 图 5所示:
如果使用三相交流电源中的 A相为整流器供电,在进行供电配置时, 需 要根据预定设置将相位识别装置的开关 K1断开, K2闭合, 因此输出信号 N1为高电平, N2为低电平。
如果使用三相交流电源中的 B相为整流器供电,在进行供电配置时, 需 要根据预定设置将相位识别装置的开关 K3闭合, K4断开, 因此输出信号 N3为低电平, N4为高电平。
如果使用三相交流电源中的 C相为整流器供电,在进行供电配置时, 需 要根据预定设置将相位识别装置的开关 K5闭合, K6闭合, 因此输出信号 N5为低电平, N6为低电平。
将各台整流器检测到的 N1-N6信号送给 DSP, DSP根据表 1中的逻辑 对整流器的相位进行判断, 并将判断结果上传到监控单元, 因此客户可以 远程查看整流器所在相位, 进而合理分配各相负载。
表 1
Figure imgf000007_0001
从上述处理可以看出, 三相交流电源中的某一相经整流器整流后, 输 出直流电压, 该直流电压经过三相交流电源相位识别装置若干路状态选择 器和隔离单元的状态选择和隔离后, 分别输出相应的高低电平信号, 并送 入信号处理单元, 信号处理单元根据这些电平信号的状态即可判断出负载 处于三相电源中的相位, 上述技术方案解决了现有技术中不能够对三相交 流电源中负载所在的相位进行判断的问题, 根据本实用新型实施例的三相 交流电源相位识别装置设计简单、 易于实现、 成本低廉, 可以应用于所有 需要识别三相交流电源相位的场合。
尽管为示例目的, 已经公开了本实用新型的优选实施例, 本领域的技 术人员将意识到各种改进、 增加和取代也是可能的, 因此, 本实用新型的 范围应当不限于上述实施例。 工业实用性
本实用新型将三相交流电源中的某一相经负载输出的直流电压, 经三 相交流电源相位识别装置中的若干路状态选择器和隔离单元的状态选择和 隔离后, 分别输出相应的电平信号到信号处理单元, 由信号处理单元根据 电平信号的状态判断出负载处于三相电源中的相位。
采用本实用新型, 可以解决现有技术中不能对三相交流电源中负载所 在的相位进行判断的问题; 并且, 设计简单、 易于实现、 成本低廉, 可应 用于所有需要识别三相交流电源相位的场合。

Claims

权利要求书
1、 一种三相交流电源相位识别装置, 其特征在于, 该装置包括: 状态 选择器、 隔离单元、 供电电源和信号处理单元; 其中,
状态选择器, 连接于负载输出电压的正极, 根据预定设置控制电路的 闭合与断开, 其输出端连接于隔离单元的第二输入端;
隔离单元, 包括两个输入端和两个输出端, 其中, 第一输入端连接于 所述负载输出电压的负极, 第二输入端连接于所述状态选择器, 第一输出 端连接上拉电阻的一端和信号处理单元, 第二输出端接地, 所述隔离单元 对不共地信号进行隔离;
供电电源, 连接于所述上拉电阻的另一端;
信号处理单元, 连接于所述隔离单元的所述第一输出端, 根据所述隔 离单元输出的高电平信号或低电平信号判定所述负载的相位。
2、 如权利要求 1所述的装置, 其特征在于, 所述状态选择器和所述隔 离单元中间设置有限流电阻。
3、 如权利要求 1所述的装置, 其特征在于, 所述状态选择器的个数为 两个或多个, 所述隔离单元的个数为两个或多个。
4、 如权利要求 3所述的装置, 其特征在于, 每个状态选择器分别连接 于相应隔离单元的所述第二输入端。
5、 如权利要求 1至 4中任一项所述的装置, 其特征在于, 所述状态选 择器为开关器件。
6、如权利要求 5所述的装置, 其特征在于, 所述开关器件为拨码开关。
7、 如权利要求 1至 4中任一项所述的装置, 其特征在于, 所述隔离单 元为光辆。
8、 如权利要求 1至 4中任一项所述的装置, 其特征在于, 所述信号处 理单元为数字信号处理器 DSP。
9、 如权利要求 1至 4中任一项所述的装置, 其特征在于, 所述负载为 整流器。
10、 如权利要求 9所述的装置, 其特征在于, 所述三相交流电源相位 识别装置安装于所述整流器单体的背板上。
PCT/CN2012/078702 2011-11-16 2012-07-16 三相交流电源相位识别装置 WO2013071768A1 (zh)

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CN101183144A (zh) * 2007-12-05 2008-05-21 海信集团有限公司 单相电源接线判定方法及单相电源相位检测电路
JP2008187874A (ja) * 2007-01-31 2008-08-14 Densei Lambda Kk 三相交流電源の欠相検出装置
CN201327508Y (zh) * 2009-03-31 2009-10-14 上海电科博耳电器开关有限公司 一种定相用电判断装置

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JP2008187874A (ja) * 2007-01-31 2008-08-14 Densei Lambda Kk 三相交流電源の欠相検出装置
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