CN203086214U - Battery backup system and battery backup module thereof - Google Patents

Abstract

The utility model discloses a battery backup system and a battery backup module thereof. The system comprises a seat body and the battery backup module, wherein the seat body is provided with a plurality of containing parts; the battery backup module comprises a modularized frame structure, a microprocessor, an energy storage element and a direct current-direct current conversion circuit, wherein the microprocessor, the energy storage element and the direct current-direct current conversion circuit are arranged in the modularized frame structure; the energy storage element and the microcontroller are connected to charge or discharge; the direct current-direct current conversion circuit is connected with the microcontroller to convert direct-current voltage; the modularized frame structure is contained in one of the containing parts of the seat body in a pluggable mode; when the modularized frame structure is contained in one of the containing parts, the microcontroller framework controls the energy storage element to charge or discharge; and direct-current voltage which is input or output by the energy storage element is controlled to be converted by the direct current-direct current conversion circuit so as to achieve the efficacy on easily maintaining, replacing and assembling and achieve high extensibility.

Description

Battery standby system and battery back up module thereof

Technical field

The utility model is about a kind of battery standby system, and is easy to power spare system and the battery back up module thereof safeguarding and change especially in regard to a kind of plugged design by the modularization frame structure.

Background technology

Along with the fast development of computer technology and world-wide web, the service that provides by world-wide web also increases day by day, and emerging technologies such as especially high in the clouds computing, high in the clouds storage are inseparable with people's life especially.Therefore, also grow with each passing day by the data center (Data center) that multiple computers, server (Server) or work station (Work station) are formed, data center for provide more, faster the service and function, be bound to such an extent that increase the quantity of computer, server or work station, and problems such as the supply of electric power of data center and battery electric power redundant also with come.

For problems such as the supply of electric power that solves data center and distribution; industry adopts power distribution unit to distribute the required electric power of every computer, server or work station more; and collocation battery standby system (Battery Backup System) carries out the battery electric power redundant; with unusual in commercial power supply or carry out the redundant supply of electric power when having a power failure, and then avoid data center to decommission or situation such as device damage.

Generally speaking, traditional battery standby system is the power demands that meets the different pieces of information center, must select battery backup unit (the Battery Backup Unit of specific standard, BBU) and assemble, to reach specific voltage or electric current supply, so because of the different specification of battery stand-by unit often is of different sizes outward appearance,, can assembles and battery backup unit is installed on the battery standby system so when assembling, often need special design or arrange.In addition, when traditional battery standby system need be safeguarded or change in battery backup unit, usually need close the battery standby system, to open the housing of the battery standby system of having assembled, and carry out the maintenance or the replacing of battery backup unit, at last again in safeguard or change finish after, re-assembly and the closing battery standby system, the beginning can be carried out the redundant supply of electric power again.

Moreover, with regard to the operator of data center, battery standby system according to the particular demands assembling not only can't carry out the redundant supply of electric power incessantly when safeguarding or change, more can't adjust the power supply specification of battery standby system with the expansion of data center, not only there are not convenient property such as maintenance, replacing, assembling and expansion, operation costs are improved relatively.

The utility model content

Main purpose of the present utility model is to provide a kind of battery standby system and battery back up module thereof, to solve existing battery standby system is the demand that cooperates the different pieces of information center, must select the battery back up module of specific standard and do not have extendibility and an assembling and be difficult for, and when the power backup unit need be safeguarded or change, must close of maintenance or the replacing of battery standby system, even re-assembly and cause relatively shortcoming such as raising of operation costs to carry out the power backup unit.

Another purpose of the present utility model is to provide a kind of battery standby system and battery back up module thereof, by modular battery back up module with and the plugged design of modularization frame structure, can be directly by of maintenance and the replacing of plug battery back up module to carry out the battery back up module, and then reach be easy to safeguard and change, assembling easily and effects such as the high extendibility of tool.

Another purpose of the present utility model is to provide a kind of battery standby system and battery back up module thereof; hot plug design by the battery back up module; can under not shutdown situation, directly carry out the maintenance and the replacing of battery back up module, to reach the effect of cutting operating costs by plug battery back up module.

For reaching above-mentioned purpose, of the present utility model one preferable enforcement aspect comprises at least for a kind of battery standby system is provided: a pedestal has a plurality of holding parts; And a plurality of battery back up modules, each this battery back up module comprises at least: one first modularization frame structure; One microcontroller is arranged in this first modularization frame structure; One energy-storage travelling wave tube is arranged in this first modularization frame structure, and is connected with this microcontroller, in order to store electrical energy or release electric energy; And one direct current-DC converting circuit, be arranged in this first modularization frame structure, and be connected, in order to conversion dc voltage with this microcontroller; Wherein, this first modularization frame structure can be located in one of these a plurality of holding parts of this pedestal with plugging, and when this microcontroller framework is located in one of these a plurality of holding parts in this first modularization frame structure, control this energy-storage travelling wave tube store electrical energy or discharge electric energy, and control this DC-to-DC change-over circuit conversion and input to the direct voltage of this energy-storage travelling wave tube or the direct voltage of this energy-storage travelling wave tube output.

For reaching above-mentioned purpose, another preferable enforcement aspect of the present utility model is for providing a kind of battery back up module, be applicable to a battery standby system that comprises a pedestal, this pedestal has a plurality of holding parts, and this battery back up module comprises at least: one first modularization frame structure; One microcontroller is arranged in this first modularization frame structure; One energy-storage travelling wave tube is arranged in this first modularization frame structure, and is connected with this microcontroller, in order to store electrical energy or release electric energy; And one direct current-DC converting circuit, be arranged in this first modularization frame structure, and be connected, in order to conversion dc voltage with this microcontroller; Wherein, this first modularization frame structure can be located in one of these a plurality of holding parts of this pedestal with plugging, and when this microcontroller system structure is located in one of these a plurality of holding parts in this first modularization frame structure, control this energy-storage travelling wave tube store electrical energy or discharge electric energy, and control this DC-to-DC change-over circuit conversion and input to the direct voltage of this energy-storage travelling wave tube or the direct voltage of this energy-storage travelling wave tube output.

Description of drawings

Fig. 1 is the structural representation of the battery standby system of the utility model preferred embodiment.

Fig. 2 is the framework calcspar of the battery back up module of the utility model preferred embodiment.

Fig. 3 is the front view of battery back up module installation shown in Figure 1.

Fig. 4 A is the schematic diagram that battery standby system of the present utility model is applied to a plurality of loads.

Fig. 4 B is the schematic diagram that battery standby system of the present utility model and control module thereof are applied to a plurality of loads.

Fig. 5 A is the structural representation of the battery back up module of the utility model preferred embodiment.

Fig. 5 B is the structural representation of the control module of the utility model preferred embodiment.

Fig. 6 is the structural representation of the battery standby system of another preferred embodiment of the utility model.

Wherein, description of reference numerals is as follows:

1: the battery standby system

2: pedestal

21: holding part

3: the battery back up module

31: the first modularization frame structures

311,411: pull handle

312: heat-sink unit

32: microcontroller

33: energy-storage travelling wave tube

34: the DC-to-DC change-over circuit

4: control module

41: the second modularization frame structures

5: bus

A1, A2, A3 ..., An: the battery back up module

L: load

L1, L2, L3 ..., Ln: load

S: power supply

S311, S411: first surface

Embodiment

Some exemplary embodiments that embody the utility model feature and advantage will be described in detail in the explanation of back segment.Be understood that the utility model can have various variations on different aspects, its neither disengaging scope of the present utility model, and explanation wherein and be shown in the usefulness that ought explain in essence, but not in order to restriction the utility model.

See also Fig. 1 and Fig. 2, it is respectively the framework calcspar of the battery back up module of the structural representation of battery standby system of the utility model preferred embodiment and the utility model preferred embodiment.As shown in Figures 1 and 2, battery standby system 1 of the present utility model comprises pedestal 2 and a plurality of battery back up module 3 at least.Pedestal 2 has a plurality of holding parts 21, and each battery back up module 3 comprises the first modularization frame structure 31, microcontroller 32, energy-storage travelling wave tube 33 and DC-to-DC change-over circuit 34 at least.Wherein, microcontroller 32 is arranged in the first modularization frame structure 31, energy-storage travelling wave tube 33 is arranged in the first modularization frame structure 31, and be connected with microcontroller 32, in order to store electrical energy or release electric energy, promptly in order to charge or discharge, and DC-to-DC change-over circuit 34 is arranged in the first modularization frame structure 31, and be connected with microcontroller 32, in order to conversion dc voltage.In this embodiment, the first modularization frame structure 31 can be located in one of a plurality of holding parts 21 of pedestal 2 with plugging, and when microcontroller 32 frameworks are located in one of a plurality of holding parts 21 in the first modularization frame structure 31, control energy-storage travelling wave tube 33 store electrical energy or release electric energy, and 34 conversions of control DC-to-DC change-over circuit input to the direct voltage of energy-storage travelling wave tube 33 or the direct voltage of energy-storage travelling wave tube 33 outputs, for example input to the direct voltage of energy-storage travelling wave tube 33 from power supply S, or energy-storage travelling wave tube 33 exports the direct voltage of load L to, but not as limit.So, the utility model by modular battery back up module 3 with and the plugged design of the first modularization frame structure 31, can be directly by plug battery back up module 3 safeguarding and to change, and then reach be easy to safeguard and change, assembling easily and effects such as the high extendibility of tool.

See also Fig. 3, it is the front view of battery back up module installation shown in Figure 1.As shown in Figure 3, the pedestal 2 of battery standby system 1 of the present utility model has a plurality of holding parts 21, and each holding part 21 is in order to hold the first modularization frame structure 31 of receiving a battery back up module 3, and the total quantity of these a plurality of holding parts 21 can be according to the load or the Demand Design of the main circuit (not shown) that is connected with battery standby system 1, among the embodiment for example shown in Figure 3, pedestal 2 promptly has seven holding parts 21.In some embodiment, the utility model is by adjusting and design the total quantity of holding part 21, hold to receive a plurality of battery back up modules 3 that are enough to provide main circuit loading demand voltage, the voltage of 12 volts of main circuit loads or 48 volts for example is provided, but not as limit.

In other embodiment,, DC power supply can be provided and be applied to n load L by the setting of n battery back up module 3.See also Fig. 4 A and Fig. 4 B, it is respectively battery standby system of the present utility model and is applied to the schematic diagram that the schematic diagram of a plurality of loads and battery standby system of the present utility model and control module thereof are applied to a plurality of loads.Shown in Fig. 4 A and Fig. 4 B, battery standby system 1 of the present utility model comprises n battery back up modules A 1～An, so that a plurality of load L1～Ln to be provided required DC power supply, wherein n is a positive integer, the total quantity n that also is the battery back up module is identical with the total quantity n of load, and battery back up modules A 1～An is complementary with load L1～Ln respectively.In this embodiment, battery back up modules A 1～An can directly be connected with load L1～Ln, also can be connected with load L1～Ln by bus 5, and under the situation of circuit turn-on, battery back up modules A 1～An and load L1～Ln be connected and battery back up modules A 1～An is all electric connection with being connected of bus 5.In addition, according to design of the present utility model, battery back up modules A 1～An also can be connected (not shown) with n power supply, charging, but not as limit.

In some embodiment, battery standby system 1 of the present utility model further comprises control module 4, to be used to monitor the running situation of integral battery door standby system 1 and the details parameter of individual cell spare module 3, for example monitoring battery standby system 1 is ready, power supply state or off-position, or the current value of monitoring individual cell spare module 3, magnitude of voltage, resistance value, capacitance, the charging cycle number of times, battery health percentage, generating efficiency, charging estimated time and discharge estimated time etc., even monitoring battery life-span and self-discharge rate etc. are right neither as limit.

See also Fig. 5 A and Fig. 5 B, it is respectively the structural representation of the control module of the structural representation of battery back up module of the utility model preferred embodiment and the utility model preferred embodiment.Shown in Fig. 5 A and Fig. 5 B, the first modularization frame structure 31 of battery back up module 3 of the present utility model further comprises first pull handle 311 and heat-sink unit 312, control module 4 comprises the second modularization frame structure 41 that has equal length, width and height with the first modularization frame structure 31, and the second modularization frame structure 41 further comprises second pull handle 411.Wherein, first pull handle 311 and second pull handle 411 are to be arranged at the first surface S311 of the first modularization frame structure 31 and the first surface S411 of the second modularization frame structure 41 respectively, and extend by the first surface S311 of the first modularization frame structure 31 and the first surface S411 of the second modularization frame structure 41 respectively, the point of application so that the Plug Action of user in safeguarding or changing to be provided, but not as limit.As for heat-sink unit 312, dispel the heat in order to the inner member of the auxiliary first modularization framework 31, and this heat-sink unit 312 can be but is not limited to a radiator fan or a fin.

In some embodiment, the first modularization frame structure 31 of battery back up module 3 has identical outward appearance and size with the second modularization frame structure 41 of control module 4, and make by single mold, with battery back up module 3 and the control module 4 that reaches the identical molds blocking, be installed on battery standby system 1 of the present utility model and can effectively integrate, significantly reduce manufacturing costs such as die sinking and design simultaneously.

See also Fig. 6, it is the structural representation of the battery standby system of another preferred embodiment of the utility model.As shown in Figure 6, because battery back up module 3 of the present utility model and control module 4 have close modularization frame structure, the i.e. first modularization frame structure 31 and the second modularization frame structure 41, so the holding part 21 of each pedestal 2 except that can holding the first modularization frame structure 31 of receiving battery back up module 3, also can hold the second modularization frame structure 41 of receiving control module 4 certainly.In other words, the second modularization frame structure 41 of first modularization frame structure 31 of battery back up module 3 and control module 4 all can be located in one of a plurality of holding parts 21 of pedestal 2 with plugging.

According to design of the present utility model, only need get final product the running situation and the details parameter of effective monitoring integral battery door standby system 1, so the quantity of the utility model control module 4 is preferable with one by the setting of single control module 4.In this embodiment, because the pedestal 2 of battery standby system 1 has seven holding parts 21, so receive the second modularization frame structure 41 of control module 4 with any appearance in seven holding parts 21, and it is preferable that other six holding parts 21 hold the first modularization frame structure 31 of receiving battery back up module 3, but not as limit.

Because the utility model can be located in one of a plurality of holding parts 21 of pedestal 2 by the first modularization frame structure 31 or the second modularization frame structure 41 with plugging; so when battery back up module 3 or control module 4 need be safeguarded or change; user or engineering staff need not to take apart pedestal 2 in advance; and can directly extract battery back up module 3 or control module 4 to safeguard or to change; the battery back up module 3 and the control module 4 that also are battery standby system of the present utility model can directly be carried out hot plug under the situation of not cutting off the power supply; and need not to make the battery standby system to shut down, can effectively reach the effect of cutting operating costs

In sum, the utility model provides a kind of battery standby system and battery back up module thereof, by modular battery back up module with and the plugged design of modularization frame structure, can be directly by of maintenance and the replacing of plug battery back up module to carry out the battery back up module, and then reach be easy to safeguard and change, assembling easily and effects such as the high extendibility of tool.In addition, the utility model more by the hot plug design of battery back up module, can directly carry out the maintenance and the replacing of battery back up module by plug battery back up module, to reach the effect of cutting operating costs under not shutdown situation.

Can think and be to modify right neither taking off as all by the personage Ren Shi craftsman who is familiar with this skill even if the utility model has been described in detail by the above embodiments as Protector that attached claim is desired.

Claims (10)

1. battery standby system comprises at least:

One pedestal has a plurality of holding parts; And

A plurality of battery back up modules, each this battery back up module comprises at least:

One first modularization frame structure;

One microcontroller is arranged in this first modularization frame structure;

One energy-storage travelling wave tube is arranged in this first modularization frame structure, and is connected with this microcontroller, in order to store electrical energy or release electric energy; And

One direct current-DC converting circuit is arranged in this first modularization frame structure, and is connected with this microcontroller, in order to conversion dc voltage;

Wherein, this first modularization frame structure can be located in one of these a plurality of holding parts of this pedestal with plugging, and when this microcontroller framework is located in one of these a plurality of holding parts in this first modularization frame structure, control this energy-storage travelling wave tube store electrical energy or discharge electric energy, and control this DC-to-DC change-over circuit conversion and input to the direct voltage of this energy-storage travelling wave tube or the direct voltage of this energy-storage travelling wave tube output.

2. battery standby system as claimed in claim 1 also comprises a control module, and this control module comprises one second modularization frame structure, and this second modularization frame structure can be located in one of these a plurality of holding parts of this pedestal with plugging.

3. battery standby system as claimed in claim 2, wherein this first modularization frame structure and this second modularization frame structure are located in one of these a plurality of holding parts of this pedestal respectively hot-swappablely.

4. battery standby system as claimed in claim 2, wherein this second modularization frame structure has identical length, width and height with this first modularization frame structure.

5. battery standby system as claimed in claim 2, wherein this second modularization frame structure has identical external structure with this first modularization frame structure.

6. battery standby system as claimed in claim 2, wherein this second modularization frame structure comprises one second pull handle, this second pull handle is arranged at a first surface of this second modularization frame structure, and is that this first surface by this second modularization frame structure extends.

7. battery standby system as claimed in claim 1, wherein this first modularization frame structure comprises one first pull handle, this first pull handle is arranged at a first surface of this first modularization frame structure, and is extended by this first surface of this first modularization frame structure.

8. battery standby system as claimed in claim 1, wherein these a plurality of battery back up modules are connected with a plurality of loads, and providing these a plurality of loads required DC power supply, and these a plurality of battery back up modules are identical with the quantity of these a plurality of loads.

9. battery standby system as claimed in claim 8, wherein these a plurality of battery back up modules are connected by a plurality of loads of a bus and this.

10. a battery back up module is applicable to a battery standby system that comprises a pedestal, and this pedestal has a plurality of holding parts, and this battery back up module comprises at least:

One modularization frame structure;

One microcontroller is arranged in this modularization frame structure;

One energy-storage travelling wave tube is arranged in this modularization frame structure, and is connected with this microcontroller, in order to store electrical energy or release electric energy; And

One direct current-DC converting circuit is arranged in this modularization frame structure, and is connected with this microcontroller, in order to conversion dc voltage;

Wherein, this modularization frame structure can be located in one of these a plurality of holding parts of this pedestal with plugging, and when this microcontroller framework is located in one of these a plurality of holding parts in this modularization frame structure, control this energy-storage travelling wave tube store electrical energy or discharge electric energy, and control this DC-to-DC change-over circuit conversion and input to the direct voltage of this energy-storage travelling wave tube or the direct voltage of this energy-storage travelling wave tube output.

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