TWM552213U - Rack-mounted uninterruptible power system - Google Patents

Abstract

A rack-mounted uninterruptible power system includes a plurality of mounting brackets, each of which has a spacer and can allow a power supply module or a battery module to be selectively mounted thereon. A plurality of connector modules can be disposed respectively on the plurality of mounting brackets. Each of the connector modules has a first connector and a second connector. At the same time, a first connecting element and a second connecting element are arranged on the back of the power supply module. The first connecting element and the second connecting element are positioned corresponding to the first connector and the second connector. As the power supply module is mounted on the mounting bracket, the first connecting element and the second connecting element are electrically connected to the first connector and the second connector at the same time. A second connecting element is separately arranged on the back of the battery module. When the battery module is disposed on the mounting bracket, the second connecting element is electrically connected to the second connector. The rack-mounted uninterruptible power system enables each of the connector modules to be directly connected to the power supply module and the battery module without any modification so that each mounting bracket can be compatible with the power supply module or the battery modules. The user can configure different numbers of the power supply modules or the battery modules on the plurality of different mounting brackets according to the power consumption. In addition, each of the power supply modules and the battery modules can be replaced by hot swap so that the numbers of the power supply modules or the battery modules of the uninterruptible power system can be adjusted according to the change of the power consumption at any time. When the power supply module or the battery module in the power interruption system is out of order, it can be separately removed for maintenance without stopping the entire uninterruptible power system.

Description

Rack-mounted uninterruptible power system

This creation is about a rack-based uninterruptible power system, especially a rack-mounted UPS that can be installed in a standard information cabinet.

According to the information network of the general network and communications industry, as well as the control centers of public transportation facilities such as the MRT, high-speed rail and expressways, as well as the control centers of hospitals and various industrial productions, a large number of computers and automation equipment are used. In the operation of these information and electronic equipment, the stable and uninterrupted power input is the basic condition for maintaining its normal operation. However, the public power system at this stage is often affected by the disconnection and short-circuit accidents of the transmission and distribution lines, causing pressure on the power users. Abnormal conditions such as drop or power interruption.

In the uninterruptible power system, there are mainly two types of modules, one of which is a power supply module and the other is a battery module. The battery module is mainly used for storing electric power, and the power supply module is used for converting direct current into alternating current, and outputting the converted alternating current for use, and controlling charging of the battery module.

For users of every industrial uninterruptible power system, the demand for electricity is different. Therefore, the power supply module and battery module must be adjusted and planned according to the expected power consumption and the number of connected devices. quantity. However, most of the existing uninterruptible power systems are fixed structures, and the current input and output load capacities of the power supply modules and the capacity of the battery modules are fixed and cannot be adjusted. Therefore, if the demand for electricity in the UPS system changes, the entire UPS system must be redesigned and modified, resulting in inconvenience in its use.

In addition, some of the current uninterruptible power systems are designed as rack-mounted junctions. The existing rack-type uninterruptible power system is configured to make the power supply module and the battery module compatible with a standard information cabinet, so that the power supply module and the battery module can be installed on In the cabinet of the server. Although the rack-type uninterruptible power system can change the load capacity of the uninterruptible power system by adjusting the number of power supply modules and the number of battery modules, the power supply of the existing rack-type uninterruptible power system The position of the module and the battery module are fixed and cannot be replaced at any time. Therefore, when the number of power supply modules and battery modules is adjusted, the wiring must be rearranged, which also causes troubles in operation.

Due to the above reasons, the number of power supply modules and battery modules in the existing uninterruptible power system is extremely inconvenient, and the flexibility of use is reduced. Therefore, how to improve the flexibility of the UPS system through the improvement of structural design has become one of the important topics to be solved by this undertaking.

The main purpose of this creation is to provide a rack-type uninterruptible power system that is highly interchangeable and can easily adjust and plan the number of power supply modules and battery modules according to user needs.

One embodiment of the present invention provides a rack-type uninterruptible power system, including: a plurality of mounting frames, each of the mounting frames having a spacing portion; at least one power supply module, at least one of the power supplies The supplier module is selectively disposed in the spacer of one of the mounting frame bodies; at least one battery module, at least one of the battery modules is selectively disposed on the plurality of mounting frames One of the connector bodies is respectively provided with a connector module, and each of the connector modules has a first connector, and each of the connector modules can be selected. Optionally, a second connector is disposed; at least one of the power supply modules has a first connection component and a second connection component, and the first connection component and the second connection component are in position and each The first connector and the second connector of the mounting frame body correspond to each other, and when at least one of the power supply modules is disposed on the mounting frame body, the first connecting component can Electrically connected to the first connector The second connection component can be electrically connected to the second connector; at least one of the battery modules has a second connection component, a position of the second connection component, and each of the mounting frame bodies The second connectors correspond to each other, and when at least one of the battery modules is disposed on the mounting body, the second connecting component can be electrically connected to the second connector.

A preferred embodiment of the present invention further includes a cabinet, wherein the plurality of mounting frames are disposed inside the cabinet, and at least one of the power supply modules and at least one of the battery modules are permeable. The mounting frame body is replaceably disposed inside the cabinet.

In a preferred embodiment of the present invention, the plurality of first connectors respectively have a plurality of AC output pins and a plurality of AC input pins; and the plurality of the second connectors respectively have a plurality of DC input connections Each of the power supply modules is electrically connected to the plurality of the AC output pins of the first connector and the plurality of AC input pins through the first connection component, and is transparently connected The plurality of the DC input pins of the second connection component and the second connector are electrically connected; the plurality of the battery modules are respectively transmitted through the second connection component and the second connector The DC input pins are electrically connected.

In a preferred embodiment of the present invention, the second connector further has a plurality of communication connection pins, and the power supply module is connected to the plurality of the communication connectors through the second connection component The foot reaches an electrical connection.

In a preferred embodiment of the present invention, the plurality of connector modules respectively have a fixing base, a first circuit substrate and a second circuit substrate, and the first connector is disposed on the first circuit substrate. The second connector is disposed on the second circuit substrate, and the first connector and the second connector are respectively mounted on the first circuit substrate and the second circuit substrate. Said on the fixed seat.

In a preferred embodiment of the present invention, a first circuit board of the plurality of connector modules is disposed with a first bus bar connector on a side of the first connector, and the second circuit substrate is opposite. Providing one side of the second connector a second bus bar connector; a plurality of the first connector and the first bus bar connector are electrically connected, and a plurality of the second connector and the second bus bar connector are electrically connected; The first bus bar connectors are connected through a first bus bar, and the plurality of second bus connectors are connected through a second bus bar.

In a preferred embodiment of the present invention, the mounting body for mounting the power supply module is defined as a mounting body of a first form for mounting the mounting body of the battery module. a mounting frame body defined as a second form, wherein the connector module on the mounting body of the first form is provided with the first connector and the second connector at the same time; The connector module on the mounting frame only separately sets the second connector.

In a preferred embodiment of the present invention, each of the power supply modules has a power supply housing, and each of the battery modules has a battery module housing, and each of the power supply housings and Each of the battery module housings has the same shape and size, and each of the power supply housings and each of the battery module housings and the plurality of mounting brackets are sized to each other such that Each of the power supply modules and each of the battery modules can be selectively disposed on any one of the mounting frames.

The beneficial effect of the present invention is that each power supply module or battery module can be selectively installed on each mounting frame body, so when the number of power supply modules and battery modules is adjusted, no rewiring is required. Make it more flexible to use.

In order to further understand the features and technical contents of the present invention, please refer to the following detailed description and drawings of the present invention. However, the drawings are only for reference and description, and are not intended to limit the creation.

1‧‧‧Rack-type uninterruptible power system

10‧‧‧Installation frame

11‧‧‧Slide assembly

12‧‧‧Sliding parts

13‧‧‧ Connecting rod

14‧‧‧ Fixed seat

15‧‧‧Interval

20‧‧‧Power supply module

21‧‧‧Power supply housing

22‧‧‧Display module

23‧‧‧ vents

30‧‧‧ battery module

31‧‧‧ battery case

40‧‧‧Connector Module

41‧‧‧First connector

411‧‧‧AC input pin

412‧‧‧AC output pin

42‧‧‧Second connector

421‧‧‧DC input pin

422‧‧‧Communication connection pin

423‧‧‧Additional pins

43‧‧‧First circuit board

44‧‧‧Second circuit substrate

45‧‧‧First busbar connector

46‧‧‧Second bus connector

47‧‧‧First Confluence Copper Bars

48‧‧‧Second bus bar

51‧‧‧First connection assembly

52‧‧‧Second connection assembly

60‧‧‧ cabinet

61‧‧‧ column

62‧‧‧ side panels

63‧‧‧ accommodating space

Figure 1 is an exploded perspective view of the inventive rack-type uninterruptible power system.

Figure 2 is a front elevational view of the inventive rack-mounted uninterruptible power system.

FIG. 3 is a three-dimensional combination diagram of a power supply module, a battery module, and a mounting frame body of the inventive rack-type uninterruptible power system.

FIG. 4 and FIG. 5 are respectively a three-dimensional combination diagram of the power supply module of the present invention mounted on the mounting frame body and pulled out from the mounting frame body.

FIG. 6 and FIG. 7 are respectively a three-dimensional combination diagram of the battery module of the present invention mounted on the mounting frame and pulled out from the mounting frame body.

Figure 8 is a perspective view of the power supply module used in the creation taken from the back side.

Fig. 9 is a perspective view of the battery module used in the creation taken from the back side.

FIG. 10 is a perspective view of a connector module used in the inventive rack-type uninterruptible power system.

FIG. 11 is a perspective assembled view of the multi-group connector module taken from the back side to reveal a structure in which a plurality of different connector modules are connected through a bus bar.

FIG. 12 is a schematic diagram showing the connection manners of the first and second connectors of the connector module and the first and second connection components of the power supply module of the connector module.

FIG. 13 is a schematic diagram showing the connection manner of the respective connectors of the second connector of the connector module and the second connection component of the battery module.

FIG. 14 is a perspective assembled view of a mounting frame body and a battery module according to a second aspect of the present invention.

As shown in FIG. 1 to FIG. 7 , the present invention provides a rack-type uninterruptible power system 1 including a plurality of mounting frames 10 , a plurality of power supply modules 20 , and a plurality of battery modules 30 .

The rack-type uninterruptible power system 1 of the present invention is mainly composed of a plurality of power supply modules 20 and a plurality of battery modules 30, wherein the plurality of power supply modules 20 can be used in a single machine or multiple The power supply module 20 and the battery module 30 are connected and combined to form a modular power-saving system. Each of the power supply module 20 and the battery module 30 has a casing, and the power supply module 20 and the outer casing of the battery module 30 have a shape and a size that cooperate with the mounting frames 10, thereby Each of the power supply module 20 and the battery module 30 can be arbitrarily mounted in any one of the mounting frames 10 , and the power supply modules 20 and the battery modules 30 are mounted in a cabinet 60 through the mounting body 10 . . At the same time A connector module 40 is further disposed on the mounting body 10, and each of the power supply module 20 and the battery module 30 is electrically connected to the connector module 40 of each mounting frame 10, and then through the copper. By connecting each of the connector modules 40, the respective power supply modules 20 and the battery modules 30 are connected to each other to form a modular rack-type uninterruptible power system 1.

As shown in FIG. 3 to FIG. 9 , each of the mounting frame bodies 10 includes two sliding rail assemblies 11 , and the two sliding rail assemblies 11 are parallel to each other, and each of the sliding rail assemblies 11 is respectively provided with a sliding member 12 . A spacer 15 is formed between the two rail assemblies 11 of each of the mounting frames 10 for mounting the power supply module 20 or the battery module 30 in the spacer 15 .

As shown in FIG. 4, FIG. 5 and FIG. 8, the power supply module 20 of the present invention has a power supply housing 21, and the power supply housing 21 houses a rectifier, a converter, an AC/DC converter, and a charging circuit. A circuit module such as a detector is provided with a component such as a cooling fan, and a display module 22 and a heat dissipation port 23 are disposed on the front panel of the power supply housing 21. As shown in FIGS. 6, 7, and 9, each of the battery modules 30 of the present invention has a battery case 31, and a plurality of batteries are housed inside the battery case 31.

The power supply housing 21 and the battery housing 31 of the present invention have two sides, respectively, and the two sliders 12 of the mounting frame 10 can be mounted on both sides of the power supply housing 21 and the battery housing 31. After the two sliding members 12 are assembled on the two sides of the power supply casing 21 or the battery casing 31, the two sliding members 12 are then snapped onto the two rail assemblies 11 of the mounting body 10, so that the power supply module can be 20 or the battery module 30 is mounted on the mounting body 10.

The power supply housing 21 and the battery housing 31 of the present invention are designed to have the same shape and size, and the widths of the power supply housing 21 and the battery housing 31 are compatible with the width of the spacer 15 of each mounting frame 10. Therefore, each mounting frame 10 can be matched with the power supply module 20 or the battery module 30, and each of the power supply module 20 and the battery module 30 can be selectively disposed in each Different mounting frames 10 are mounted on the mounting frame 10 so that the user can install different numbers of the power supply modules 20 or the battery modules 30 according to actual needs.

Each of the mounting frames 10 of the present invention is connected to a connecting rod 13 between the two rail assemblies 11 , and a fixing base 14 and a connector module 40 are disposed on the connecting rod 13 , and the connector module 40 respectively A first connector 41 and a second connector 42 are disposed, and a first connection component 51 and a second connection component 52 are respectively disposed on the back surface of each power supply module 20, and the battery module 30 is A second connecting component 52 is separately disposed on the back side. When the power supply module 20 or the battery module 30 is mounted on the mounting body 10, the power supply module 20 and the battery module 30 can respectively pass through the first connecting component. The first connector 41 or the second connector 42 of the 51 and the second connecting component 52 and the connector module 40 are electrically connected.

As shown in FIG. 1 and FIG. 2 , each of the power supply module 20 and the battery module 30 of the present invention can be installed in a cabinet 60 through a plurality of mounting frames 10 . The cabinet 60 has a plurality of uprights 61, and each of the two sides has a side plate 62, and an accommodating space 63 is formed between the two side plates 62. The plurality of the power rail modules 61 and the battery modules 30 can be respectively disposed through the mounting brackets. The body 10 is detachably disposed in the accommodating space 63 of the cabinet 60.

The cabinet 60 may be an information cabinet conforming to the Electronic Industries Alliance-EIA EIA-310-D standard, and the sizes of the power supply housings 21 and the battery casing 31 and the respective mounting frames 10 are also designed. It conforms to the EIA-310-D standard specification. Through the above design, the created rack-mounted uninterruptible power system 1 can be installed in the server cabinet of the general information system, without the need to separately provide a separate UPS cabinet, thus making it more flexible and Does not occupy the room space.

As shown in FIG. 5, FIG. 7 and FIG. 10 to FIG. 13, the connector module 40 of the present invention mainly includes a first connector 41 and a second connector 42, wherein the first connector 41 is disposed on the first connector 41. On the first circuit substrate 43, the second connector 42 is disposed on a second On the circuit board 44. The first connector 41 and the second connector 42 are respectively mounted on the fixing base 14 of the mounting frame 10 through the first circuit board 43 and the second circuit board 44.

A first bus bar connector 45 is further disposed on a side of the first circuit board 43 relative to the first connector 41, and a second bus bar connector is disposed on a side of the second circuit board 44 opposite to the second connector 42. 46. The first connector 41 is electrically connected to the first bus bar connector 45 through the connection line of the first circuit substrate 43 , and the second connector 42 is also electrically connected through the second circuit substrate 44 and the second bus bar connector 46 . connection.

As shown in FIG. 11, the first bus bar connectors of the different connector modules 40 can also be connected through a first bus bar 47, and the plurality of second bus bars 46 can also pass through a The two bus bars 48 are connected to each other, so that the connector modules 40 are connected to each other, and the power modules 20 and the battery modules 30 can be transmitted through the connector modules 40 after being mounted on the mounting frames 10 and The first and second bus bars 47, 48 are connected together, so that the respective power supply modules 20 and the battery modules 30 are combined into a complete uninterruptible power system.

As shown in FIG. 8 and FIG. 9 , the back side of the power supply module 20 of the present invention is provided with a first connection component 51 and a corresponding position of the first connector 41 and the second connector 42 of the connector module 40 . The second connecting component 52 is electrically connected to the first connector 41 and the second connector 42 respectively after the power supply module 20 is mounted on the mounting body 10 . And the power supply module 20 and the connector module 40 are electrically connected. As shown in FIG. 9 , the first connection component 51 is not disposed on the back surface of the battery module 30 , and only a second connection component 52 is disposed at a position corresponding to the second connector 42 corresponding to the connector module 40 . When the battery module 30 is mounted on the mounting body 10 , the second connecting component 52 and the corresponding second connector 42 are electrically connected, and the battery module 30 and the connector module 40 are electrically connected.

As shown in FIG. 10 and FIG. 12 and FIG. 13 , the first connector of the connector module 40 is 41. The second connector 42 and the connection pin arrangement of the first connection component 51 and the second connection component 52. The first connector 41 of the present invention includes a plurality of AC input pins 411 and a plurality of AC output pins 412. The second connector 42 is mainly provided with a plurality of DC input pins 421, and a plurality of communication connections. Foot 422.

The number of pins of the AC input pin 411 and the AC output pin 412 provided on the first connector 41 can be changed according to the actual design of the uninterruptible power system, and thus is not limited. In addition, at least one additional pin 423 may be disposed on the second connector 42 in addition to the DC input pin 421 and the communication connection pin 422. In this embodiment, the additional pin 423 can be used as another AC output pin or an AC input pin. In this embodiment, a part of the DC input pin or the DC output pin can be disposed on the second connector 42 through the additional pin 423 to reduce the number of pins of the first connector 41.

As shown in FIG. 8 and FIG. 12 , the first and second connection components 51 and 52 for connecting with the first connector 41 and the second connector 42 are simultaneously disposed on the back surface of the power supply module 20 . The power supply module 20 passes through the first connection component 51 and the second connection component 52 and the respective AC input pins 411 and AC output pins on the first and second connectors 41 and 42 of the connector module 40. 412. The DC input pin 421 and the communication connection pin 422 are electrically connected.

As shown in FIG. 9 and FIG. 13 , the second connection component 52 is separately disposed on the back surface of the battery module 30 , and the battery module 30 is electrically connected to the DC input pin 421 of the second connector 42 only through the second connection component 52 . connection.

It can be seen from the above description that the connector module 40 of the present invention can be respectively connected to the power supply module 20 and the battery module 30, so that the power supply module 20 or the battery module 30 is mounted on each mounting body 10. In the future, the connector module 40 on the mounting frame 10 can be electrically connected to the connector module 40. Therefore, the user can arbitrarily mount the power supply module 20 or the battery module 30 on each of the mounting frames 10.

As shown in FIG. 14, another method of using the connector module 40 used in the inventive rack-type uninterruptible power system 1 is used. In this embodiment, among the plurality of mounting frames 10, The mounting frame body 10 of the first form for mounting the power supply module 20 and the mounting frame body 10 of the second form for mounting the battery module 30 are divided. The first connector 41 and the second connector 42 are simultaneously disposed on the connector module 40 of the mounting body 10 of the first embodiment. Therefore, when the power supply module 20 is installed in the first When the mounting frame 10 is mounted on the mounting frame 10, the first connecting component 51 and the first connecting component 51 of the power supply module 20 can simultaneously achieve electrical properties with the first connector 41 and the second connector 42 of the connector module 40. connection. Of course, the mounting body 10 of the first form can also be compatible with the battery module 30. When the battery module 30 is mounted on the mounting body 10 of the first type, the second connection of the battery module 30 The component 52 is only electrically connected to the second connector 42 on the connector module 40. Since the structure of the mounting frame body 10 of the first embodiment is the same as that of the mounting frame body 10 of the foregoing embodiments, the drawings are not separately drawn in the present specification.

As shown in FIG. 14, the mounting frame body 10 of the second aspect adopted in the present invention, in the mounting frame body 10 of the second aspect, the connector module 40 is provided with only the second connector 42 separately, thereby making the power supply device When the module 20 is mounted on the mounting body 10 of the second embodiment, the first connecting component 51 of the power supply module 20 cannot be electrically connected to the connector module 40, so that the mounting body 10 of the second form is only The battery module 30 can be mounted, and the power supply module 20 cannot be installed.

The connector module 40 used in the present invention has the first connector 41 and the second connector 42 mounted on the first circuit substrate 43 and the second circuit substrate 44, respectively, thereby causing the first connector 41 of the connector module 40. And the second connector 42 can be quickly mounted on the fixing base 14 of the mounting frame 10, or can be quickly disassembled, so that each mounting frame 10 can be easily changed to the mounting body 10 of the first form or Change to the mounting body 10 of the second aspect.

The above-described design of the rack-type uninterruptible power system 1 enables each connector module 40 to be directly connected to the power supply module 20 and the battery module 30 without modification, thereby making each mounting frame The body 10 can be compatible with the power supply module 20 or the battery module 30, so the user can rely on the plant or the information room. A different number of power supply modules 20 and battery modules 30 are disposed on a plurality of different mounting frames 10 for the purpose of power usage. Even the power supply module 20 and the battery module 30 can be replaced by hot swapping, thereby enabling the uninterruptible power system to flexibly adjust the power supply module 20 according to the change in power consumption. The number of battery modules 30, and if any one of the power supply modules 20 or the battery modules 30 in the uninterruptible power system fails, can also be separately disassembled and repaired without the need to shut down the entire uninterruptible power system.

The above description is only a preferred and feasible embodiment of the present invention, and thus does not limit the scope of the patent of the present invention. Therefore, any equivalent technical changes made by using the present specification and the contents of the schema are included in the scope of protection of the present creation. .

10‧‧‧Installation frame

11‧‧‧Slide assembly

12‧‧‧Sliding parts

13‧‧‧ Connecting rod

14‧‧‧ Fixed seat

15‧‧‧Interval

20‧‧‧Power supply module

21‧‧‧Power supply housing

22‧‧‧Display module

23‧‧‧ vents

30‧‧‧ battery module

40‧‧‧Connector Module

41‧‧‧First connector

42‧‧‧Second connector

Claims (10)

A rack-type uninterruptible power system includes: a plurality of mounting frames, each of the mounting frames having a spacing portion; at least one power supply module, at least one of the power supply modules being selectable The at least one of the battery modules is selectively disposed in one of the plurality of the mounting brackets; Each of the mounting frames is respectively provided with a connector module, each of the connector modules respectively has a first connector, and each of the connector modules can selectively set a second connection. At least one of the power supply modules has a first connection component and a second connection component, a position pair of the first connection component and the second connection component, and each of the mounting frame bodies The first connector and the second connector correspond to each other, and when at least one of the power supply modules is disposed on the mounting body, the first connecting component and the first connector Electrically connected, the second connecting component can The second connector is electrically connected; at least one of the battery modules has a second connection component, and a position of the second connection component and the second connector of each of the mounting frame bodies correspond to each other, The second connection component can be electrically connected to the second connector when at least one of the battery modules is disposed on the mounting body. The rack-type uninterruptible power system of claim 1, further comprising a cabinet, wherein the plurality of mounting frames are disposed inside the cabinet, and at least one of the power supply modules and at least one The battery module is detachably disposed inside the cabinet through a plurality of the mounting frames. The rack-type uninterruptible power system of claim 2, wherein the plurality of the first connectors respectively have a plurality of AC output pins and a plurality of AC input pins; and the plurality of the second connectors respectively Having a plurality of DC input pins; each of said power supplies The module is electrically connected to the plurality of the AC output pins of the first connector and the plurality of AC input pins through the first connection component, and through the second connection component and the The plurality of the DC input pins of the second connector are electrically connected; the plurality of the battery modules are respectively achieved by the plurality of the DC input pins of the second connection component and the second connector Electrical connection. The rack-type uninterruptible power system of claim 3, wherein the second connector further has a plurality of communication connection pins, and the power supply module passes through the second connection component and The communication connection pins are electrically connected. The rack-type uninterruptible power system of claim 4, wherein each of the plurality of connector modules has a fixed base, and a first circuit substrate and a second circuit substrate, wherein the first connector is disposed on The first connector is disposed on the second circuit substrate, and the first connector and the second connector respectively pass through the first circuit substrate and the first The two circuit substrates are mounted on the fixing base. The rack-type uninterruptible power system of claim 5, wherein the first circuit board of the plurality of connector modules is provided with a first bus bar connector on a side of the first connector, a second busbar connector is disposed on a side of the second circuit board opposite to the second connector; the plurality of the first connector and the first busbar connector are electrically connected, and the plurality of The second connector and the second bus connector are electrically connected; the plurality of first bus connectors are connected through a first bus bar, and the plurality of second bus connectors are connected through a first The two busbars are connected to each other. The rack-type uninterruptible power system of claim 6, wherein the mounting frame body for mounting the power supply module is defined as a mounting body of a first form for mounting the battery module The mounting frame body is defined as a mounting body of a second form, and the connector module on the mounting frame body of the first form is simultaneously provided with the first connector and the second connector; The connector module on the mounting body of the second aspect only separately provides the second connector. The rack-type uninterruptible power system of any one of claims 2 to 7, wherein each of the power supply modules has a power supply housing, and each of the battery modules has a battery module a set of outer casings, each of the power supply housings and each of the battery module housings having the same shape and size, and each of the power supply housings and each of the battery module housings and The mounting brackets are sized to cooperate such that each of the power supply modules and each of the battery modules can be selectively disposed on any one of the mounting brackets. The rack-type uninterruptible power system of claim 8, wherein each of the mounting frames has two slide rail assemblies and two sliding members, and the two rail assemblies are parallel to each other, and the two sliding members are Slidably disposed on the two rail assemblies; the power supply housing and the battery module housing respectively have two sides, and the two sliding members of each of the mounting frames can be respectively disposed on the power supply The supplier housing or both sides of the battery module housing. The rack-type uninterruptible power system of claim 9, wherein the cabinet has two side plates, and an accommodating space is formed between the two side plates, and the plurality of the mounting frame bodies are disposed at the cabinet at equal intervals. Internally, the two slide rail assemblies of the plurality of mounting brackets are respectively disposed on inner sides of the two side panels; and the plurality of power supply modules and the plurality of battery modules respectively pass through the plurality of The mounting frame is mounted in the accommodating space of the cabinet.