CN211207289U - Server and CRPS circuit thereof - Google Patents
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- CN211207289U CN211207289U CN201922419640.7U CN201922419640U CN211207289U CN 211207289 U CN211207289 U CN 211207289U CN 201922419640 U CN201922419640 U CN 201922419640U CN 211207289 U CN211207289 U CN 211207289U
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Abstract
The application discloses CRPS circuit includes: a CRPS circuit body; voltage detection means for detecting an input voltage of the CRPS circuit main body; current detection means for detecting an input current of the CRPS circuit main body; the first parameter determining module is respectively connected with the voltage detecting device and the current detecting device and used for determining instantaneous circuit parameters according to the input voltage and the input current; and the BMC is connected with the first parameter determination module and is used for receiving the output data of the first parameter determination module. By applying the scheme of the application, the detection and the acquisition of the circuit parameters at the input end of the CRPS can be conveniently carried out. The application also provides a server with corresponding technical effects.
Description
Technical Field
The utility model relates to a circuit detection technical field especially relates to a server and CRPS circuit thereof.
Background
With the continuous development of computers and information technology, data storage is growing rapidly. Under the push of the increasing data storage and the continuous innovation of application drivers, the demand of the large data industry for the server is also continuously increased.
CRPS (Common Redundant Power Supplies) plays an important role in the operation of servers as an energy conversion and supply part of server equipment. However, currently, real-time detection of output power is only performed at the output of the CRPS. However, in practical applications, due to sudden changes of the mains supply and sudden changes of the load, abnormal conditions such as voltage drop and sudden power increase are easily caused, and further, faults may be caused, so that a user needs to support circuit data of an input end.
In order to obtain the circuit parameters at the input end of the CRPS, currently, a user is usually required to adopt an additional power meter to build a test system to realize the measurement and calculation of the circuit parameters at the input end of the CRPS, and such a method is complex in operation, time-consuming and labor-consuming. In addition, real-time monitoring is not available, i.e., the power meter cannot be detected after being removed, which is not beneficial to the maintenance of the server system.
In summary, how to conveniently detect and obtain circuit parameters at the input end of the CRPS is a technical problem that needs to be solved by those skilled in the art.
SUMMERY OF THE UTILITY MODEL
The utility model aims at providing a server and CRPS circuit thereof to conveniently carry out the detection of the circuit parameter of CRPS input and acquire.
In order to solve the technical problem, the utility model provides a following technical scheme:
a CRPS circuit, comprising:
a CRPS circuit body;
voltage detection means for detecting an input voltage of the CRPS circuit main body;
current detection means for detecting an input current of the CRPS circuit main body;
a first parameter determining module, connected to the voltage detecting device and the current detecting device, respectively, for determining instantaneous circuit parameters according to the input voltage and the input current;
and the BMC is connected with the first parameter determination module and is used for receiving the output data of the first parameter determination module.
Preferably, the instantaneous circuit parameters determined by the first parameter determination module include: the CRPS circuit comprises a CRPS circuit main body, a CRPS circuit main body and a power supply, wherein the CRPS circuit main body comprises an input end, an input end and an output end, the input end of the CRPS circuit main body is connected with the input end of the CRPS circuit main body, the instantaneous apparent power of the input end of the CRPS circuit main body, the instantaneous reactive power of the input end of the CRPS circuit main body, the instantaneous power factor of the CRPS circuit main body, the instantaneous input.
Preferably, the first parameter determination module includes:
a preceding stage parameter determining unit connected to the voltage detecting device and the current detecting device, respectively, for determining, based on the input voltage and the input current: the transient apparent power of the input end of the CRPS circuit main body, the transient active power of the input end of the CRPS circuit main body, the transient reactive power of the input end of the CRPS circuit main body, the transient power factor of the CRPS circuit main body, the transient input voltage of the CRPS circuit main body and the transient input current of the CRPS circuit main body;
and the rear-stage parameter determining unit is respectively connected with the front-stage parameter determining unit and the BMC and is used for determining the electric energy efficiency of the CRPS circuit main body and outputting the output data of the front-stage parameter determining unit and the electric energy efficiency to the BMC.
Preferably, the former-stage parameter determination unit is a PFC control unit of a PFC circuit in the CRPS circuit main body, and the latter-stage parameter determination unit is a LL C resonance control unit of an LL C circuit of the CRPS circuit main body.
Preferably, the method further comprises the following steps:
and the second parameter determining module is respectively connected with the voltage detecting device, the current detecting device and the BMC, and is used for determining an average circuit parameter according to the input voltage and the input current and outputting the average circuit parameter to the BMC.
Preferably, the average circuit parameter determined by the second parameter determining module includes: the average apparent power of the CRPS circuit body input terminal over the first time period, the average active power of the CRPS circuit body input terminal over the first time period, the average reactive power of the CRPS circuit body input terminal over the first time period, the average power factor of the CRPS circuit body over the first time period, the average input voltage of the CRPS circuit body over the first time period, and the average input current of the CRPS circuit body over the first time period.
Preferably, the method further comprises the following steps:
and the display device is connected with the BMC and is used for displaying the data received by the BMC.
Preferably, the method further comprises the following steps:
and the wireless transmission device is connected with the BMC and is used for wirelessly transmitting the data received by the BMC to a remote terminal.
A server comprising the CRPS circuitry of any of the above.
In the scheme of the application, a voltage detection device and a current detection device are directly arranged in the CRPS circuit so as to detect the circuit parameters of the input end of the CRPS. Specifically, the voltage detection means may detect an input voltage of the CRPS circuit main body, and the current detection means may detect an input current of the CRPS circuit main body. The first parameter determining module is respectively connected with the voltage detecting device and the current detecting device, and can output the instantaneous circuit parameters to the BMC after determining the instantaneous circuit parameters according to the input voltage and the input current. Therefore, according to the scheme of the application, a user does not need to use an additional power meter to detect the circuit parameters of the CRPS input end, and the user can directly obtain the circuit parameters of the CRPS input end from the BMC, so that the circuit parameters of the CRPS input end can be conveniently detected and obtained. In addition, since the removal is not required as with a power meter, the problem that the maintenance of the server system is not facilitated due to the failure of detection after the removal does not occur.
Drawings
In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.
Fig. 1 is a schematic structural diagram of a CRPS circuit in the present invention;
fig. 2 is a schematic structural diagram of a CRPS circuit according to an embodiment of the present invention.
Detailed Description
The core of the utility model is to provide a CRPS circuit, can conveniently carry out the detection of the circuit parameter of CRPS input and acquire.
In order to make the technical field better understand the solution of the present invention, the following detailed description of the present invention is provided with reference to the accompanying drawings and the detailed description. It is to be understood that the embodiments described are only some embodiments of the invention, and not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.
Referring to fig. 1, fig. 1 is a schematic structural diagram of a CRPS circuit according to the present invention, where the CRPS circuit may include:
the CRPS circuit body 10.
The CRPS circuit body 10 represents an original CRPS circuit, and the specific circuit configuration thereof can be set and adjusted according to actual needs, for example, the general CRPS circuit body 10 may include the power frequency rectifying circuit 11, the PFC circuit 12, the LL C circuit 13 and the high frequency rectifying circuit 14 in fig. 2, of course, the specific circuit configurations of the power frequency rectifying circuit 11, the PFC circuit 12, the LL C circuit 13 and the high frequency rectifying circuit 14 and the types of relevant components in the circuit may also be set and selected according to actual needs, and reference may be made to the existing relevant circuit configurations, which will not be described in detail herein.
A voltage detection means 20 for detecting an input voltage of the CRPS circuit main body 10;
a current detection means 30 for detecting an input current of the CRPS circuit body 10.
In the present embodiment, the CRPS circuit is provided with the voltage detection device 20 and the current detection device 30, the voltage detection device 20 can detect the input voltage of the CRPS circuit body 10, the current detection device 30 can detect the input current of the CRPS circuit body 10, and the other CRPS circuit parameters can be calculated based on the input voltage of the CRPS circuit body 10 detected by the voltage detection device 20 and the input current of the CRPS circuit body 10 detected by the current detection device 30.
It should be noted that the voltage detection device 20 and the current detection device 30 may be normally detected in real time or may be detected at a predetermined detection cycle, but if the detection is performed at a predicted detection cycle, the detection is normally performed at a short detection cycle.
The specific circuit configuration of the voltage detection device 20 and the current detection device 30 can also be set and adjusted according to actual needs, and the CRPS circuit body 10 receives an alternating current, i.e., an AC input shown in fig. 1, which is usually the commercial power.
And a first parameter determining module 40 connected to the voltage detecting device 20 and the current detecting device 30 respectively for determining instantaneous circuit parameters according to the input voltage and the input current.
A BMC50 coupled to the first parameter determination module 40 for receiving output data of the first parameter determination module 40.
In practical applications, the instantaneous circuit parameter determined by the first parameter determining module 40 may generally include 6 items, specifically: instantaneous apparent power at the input end of the CRPS circuit body 10, instantaneous active power at the input end of the CRPS circuit body 10, instantaneous reactive power at the input end of the CRPS circuit body 10, instantaneous power factor of the CRPS circuit body 10, instantaneous input voltage of the CRPS circuit body 10, and instantaneous input current of the CRPS circuit body 10. The instantaneous input voltage of the CRPS circuit body 10 is the detection value of the voltage detection device 20, the instantaneous input current of the CRPS circuit body 10 is the detection value of the current detection device 30, and the rest four parameters are calculated values.
Of course, in other embodiments, the determined instantaneous circuit parameter may also include other things, for example, in the embodiment of fig. 2, the first parameter determining module 40 may include:
preceding stage parameter determining means 41 connected to the voltage detecting means 20 and the current detecting means 30, respectively, for determining from the input voltage and the input current: instantaneous apparent power at the input end of the CRPS circuit main body 10, instantaneous active power at the input end of the CRPS circuit main body 10, instantaneous reactive power at the input end of the CRPS circuit main body 10, instantaneous power factor of the CRPS circuit main body 10, instantaneous input voltage of the CRPS circuit main body 10, and instantaneous input current of the CRPS circuit main body 10;
the subsequent parameter determination unit 42, which is connected to the previous parameter determination unit 41 and the BMC50, determines the power efficiency of the CRPS circuit main body 10, and outputs the output data of the previous parameter determination unit 41 and the power efficiency to the BMC 50.
In this embodiment, the preceding-stage parameter determination unit 41 determines the 6 commonly used circuit parameters, the subsequent-stage parameter determination unit 42 determines the power efficiency of the CRPS circuit body 10, and the subsequent-stage parameter determination unit 42 outputs the output data of the preceding-stage parameter determination unit 41 and the power efficiency to the BMC 50. In this embodiment, the subsequent parameter determining unit 42 needs to obtain circuit data of the output end of the CRPS circuit main body 10, specifically, needs to obtain the instantaneous active power of the output end of the CRPS circuit main body 10, and then, in combination with the instantaneous active power of the input end of the CRPS circuit main body 10, the electric energy efficiency of the CRPS circuit main body 10 can be determined.
In this embodiment, the BMC50 can acquire the power efficiency, so that a user can conveniently know the CRPS circuit condition more carefully, which is also beneficial to maintaining and adjusting the system.
It is also noted that it is considered that the circuit originally has a relevant control unit for controlling the PFC circuit 12 in the CRPS circuit body 10, and originally has a relevant control unit for controlling the LL C circuit 13 in the CRPS circuit body 10.
In a specific embodiment of the present invention, the former stage parameter determining unit 41 may be a PFC control unit of the PFC circuit 12 in the CRPS circuit main body 10, and the latter stage parameter determining unit 42 may be a LL C resonance control unit of the LL C circuit 13 of the CRPS circuit main body 10.
That is to say, in this embodiment, the former stage parameter determining unit 41 and the latter stage parameter determining unit 42 of the present application are implemented by directly using the original PFC control unit of the PFC circuit 12 and the original LL C resonance control unit of the LL C circuit 13, which is beneficial to reducing the cost of the present application and facilitating implementation.
In addition, in the foregoing embodiment, in order to more precisely understand the circuit condition of the user, the subsequent parameter determination unit 42 is used to determine the power efficiency of the CRPS circuit body 10 and output the determined power efficiency to the BMC50, and in other embodiments, the BMC50 may calculate the power efficiency. For example, in the embodiment of fig. 2, the subsequent stage parameter determination unit 42 may be configured to transfer the received output data of the previous stage parameter determination unit 41 to the BMC50 only, without participating in the arithmetic processing of the data. It will be appreciated that such an approach may take up more of the computing resources of the BMC 50.
In a specific embodiment of the present invention, considering that in addition to the instantaneous circuit parameters, in practical applications, the user may also need the average circuit parameters of the input end of the CRPS circuit main body 10 to know the overall state of the circuit in a period of time, therefore, this embodiment may further include:
and a second parameter determination module respectively connected to the voltage detection device 20, the current detection device 30 and the BMC50, for determining an average circuit parameter according to the input voltage and the input current, and outputting the average circuit parameter to the BMC 50.
The specific parameter items in the average circuit parameters may also be set and adjusted according to actual needs, for example, in a specific embodiment of the present invention, the average circuit parameters determined by the second parameter determining module may include: the average apparent power at the input end of the CRPS circuit body 10 in the first time period, the average active power at the input end of the CRPS circuit body 10 in the first time period, the average reactive power at the input end of the CRPS circuit body 10 in the first time period, the average power factor of the CRPS circuit body 10 in the first time period, the average input voltage of the CRPS circuit body 10 in the first time period, and the average input current of the CRPS circuit body 10 in the first time period.
In this embodiment, the average circuit parameter determined by the second parameter determining module is relatively comprehensive, and is convenient for a user to use and observe. It should be noted that, in some cases, when the average circuit parameter needs to be obtained, the average circuit parameter may also be obtained by the first parameter determining module 40, that is, the function of the second parameter determining module may be integrated in the first parameter determining module 40, for example, the function of the preceding stage parameter determining unit and the function of the second parameter determining module may be realized by the same controller, and the implementation of the present invention is not affected.
In a specific embodiment of the present invention, the present invention can further include:
and the display device is connected with the BMC50 and is used for displaying the data received by the BMC 50. The display device can display the data received by the BMC50, so that a user can visually observe the condition of the CRPS circuit on site.
Further, in order to facilitate remote observation, the method may further include:
the wireless transmission device connected with the BMC50 is used for wirelessly transmitting the data received by the BMC50 to a remote terminal, so that a user can know the condition of the CRPS circuit at a remote end without being on site, and the work of the user is facilitated.
In the solution of the present application, the voltage detection device 20 and the current detection device 30 are directly provided in the CRPS circuit to detect the circuit parameters at the input terminal of the CRPS. Specifically, the voltage detection device 20 may detect the input voltage of the CRPS circuit body 10, and the current detection device 30 may detect the input current of the CRPS circuit body 10. The first parameter determining module 40 is connected to the voltage detecting device 20 and the current detecting device 30, respectively, and determines the instantaneous circuit parameter according to the input voltage and the input current, and then outputs the instantaneous circuit parameter to the BMC 50. Therefore, according to the scheme of the application, a user does not need to use an additional power meter to detect the circuit parameters of the CRPS input end, and the user can directly acquire the circuit parameters of the CRPS input end from the BMC50, so that the detection and acquisition of the circuit parameters of the CRPS input end can be conveniently performed. In addition, since the removal is not required as with a power meter, the problem that the maintenance of the server system is not facilitated due to the failure of detection after the removal does not occur.
Corresponding to the above embodiments of the CRPS circuit, the embodiments of the present invention further provide a server, which can include the CRPS circuit in any of the above embodiments, and can be referred to in correspondence with the above, and the description is not repeated here.
It is further noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other like elements in a process, article, or apparatus that comprises the element.
The principle and the implementation of the present invention are explained herein by applying specific examples, and the above descriptions of the embodiments are only used to help understand the technical solution and the core idea of the present invention. It should be noted that, for those skilled in the art, without departing from the principle of the present invention, the present invention can be further modified and modified, and such modifications and modifications also fall within the protection scope of the appended claims.
Claims (9)
1. A CRPS circuit, comprising:
a CRPS circuit body;
voltage detection means for detecting an input voltage of the CRPS circuit main body;
current detection means for detecting an input current of the CRPS circuit main body;
a first parameter determining module, connected to the voltage detecting device and the current detecting device, respectively, for determining instantaneous circuit parameters according to the input voltage and the input current;
and the BMC is connected with the first parameter determination module and is used for receiving the output data of the first parameter determination module.
2. The CRPS circuit of claim 1, wherein the instantaneous circuit parameters determined by the first parameter determination module comprise: the CRPS circuit comprises a CRPS circuit main body, a CRPS circuit main body and a power supply, wherein the CRPS circuit main body comprises an input end, an input end and an output end, the input end of the CRPS circuit main body is connected with the input end of the CRPS circuit main body, the instantaneous apparent power of the input end of the CRPS circuit main body, the instantaneous reactive power of the input end of the CRPS circuit main body, the instantaneous power factor of the CRPS circuit main body, the instantaneous input.
3. The CRPS circuit of claim 1, wherein the first parameter determination module comprises:
a preceding stage parameter determining unit connected to the voltage detecting device and the current detecting device, respectively, for determining, based on the input voltage and the input current: the transient apparent power of the input end of the CRPS circuit main body, the transient active power of the input end of the CRPS circuit main body, the transient reactive power of the input end of the CRPS circuit main body, the transient power factor of the CRPS circuit main body, the transient input voltage of the CRPS circuit main body and the transient input current of the CRPS circuit main body;
and the rear-stage parameter determining unit is respectively connected with the front-stage parameter determining unit and the BMC and is used for determining the electric energy efficiency of the CRPS circuit main body and outputting the output data of the front-stage parameter determining unit and the electric energy efficiency to the BMC.
4. The CRPS circuit according to claim 3, wherein the preceding stage parameter determination unit is a PFC control unit of a PFC circuit in the CRPS circuit body, and the succeeding stage parameter determination unit is a LL C resonance control unit of an LL C circuit of the CRPS circuit body.
5. The CRPS circuit of claim 1, further comprising:
and the second parameter determining module is respectively connected with the voltage detecting device, the current detecting device and the BMC, and is used for determining an average circuit parameter according to the input voltage and the input current and outputting the average circuit parameter to the BMC.
6. The CRPS circuit of claim 5, wherein the average circuit parameters determined by the second parameter determination module comprise: the average apparent power of the CRPS circuit body input terminal over the first time period, the average active power of the CRPS circuit body input terminal over the first time period, the average reactive power of the CRPS circuit body input terminal over the first time period, the average power factor of the CRPS circuit body over the first time period, the average input voltage of the CRPS circuit body over the first time period, and the average input current of the CRPS circuit body over the first time period.
7. The CRPS circuit of claim 1, further comprising:
and the display device is connected with the BMC and is used for displaying the data received by the BMC.
8. The CRPS circuit of claim 7, further comprising:
and the wireless transmission device is connected with the BMC and is used for wirelessly transmitting the data received by the BMC to a remote terminal.
9. A server comprising a CRPS circuit according to any of claims 1 to 8.
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CN201922419640.7U CN211207289U (en) | 2019-12-27 | 2019-12-27 | Server and CRPS circuit thereof |
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CN201922419640.7U CN211207289U (en) | 2019-12-27 | 2019-12-27 | Server and CRPS circuit thereof |
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