CN113255034A - Automatic layout system and generation method for equipment of convergence machine room - Google Patents

Abstract

The invention discloses a layout system and a generation method of automatic convergence machine room equipment, which comprises an equipment management module, a cabinet management module, a field management module, a convergence planning module and a user management module, wherein the equipment management module is used for managing equipment; the equipment management module comprises an equipment definition submodule and an equipment addition submodule; the cabinet management module comprises a cabinet definition sub-module and a cabinet addition sub-module; the field management module comprises a field definition submodule and an abnormal area definition submodule; the convergence planning module comprises a cabinet convergence submodule, an equipment convergence submodule, a cabinet adjusting submodule and an equipment adjusting submodule; the user management module comprises a user name uName, a user identifier uID, a user department uDept and a user password uPW. The invention can assemble and generate the layout of the cabinet and the automatic layout of the equipment in the cabinet in the machine room according to the basic information of the equipment, the monitoring of the thermal power and other elements, and supports the human-computer interaction adjustment of the layout.

Description

Automatic layout system and generation method for equipment of convergence machine room

Technical Field

The invention relates to the technical field of machine room layout, in particular to a layout system and a generation method of automatic convergence machine room equipment.

Background

Whether the layout of the machine room is reasonable or not and whether the equipment installation position is proper or not have profound influence on the management and the use of the machine room and even the fire safety of the machine room. The layout of the machine room needs to consider various factors such as space, equipment, fire protection, power supply, ventilation and the like. The layout planning of the current machine room is relatively simple, local planning is carried out according to construction projects in the machine room under most conditions, machine room project groups carry out occupied deployment of the cabinet according to the use purpose of each project, the planning uniformity is lacked, and although the requirement of the operation of the current project is met, the adjustment is difficult to carry out at the later stage.

Along with the high-speed development of the internet industry in China, the machine room construction scale is larger and larger, the application content is wider and flexible, and the machine room and the equipment layout method which are freely matched have great restriction on good performance of machine room efficiency, the energy efficiency ratio of the machine room is reduced seriously, and the requirements of the development of the information industry in China are not met.

At present, some students in the industry have conducted discussion research on machine room layout, for example, in research and application of core transmission machine room process layout optimization of the research institute of watson consulting design and research institute, ltd, based on the number of devices, power supply capacity and transmission device port information are taken as core consideration bases, and a layout idea of the machine room is provided; in the method and the device for 3D visualization of the machine room based on the Unity3 engine, which is available from Beijing Shenzhou Taiyue software corporation, a 3D visualization method and a device for the machine room are disclosed in the patent application No. 201810011912.7, so that the pipeline link information of the machine room can be monitored, and the 3D visualization management of the machine room pipeline is realized; method for generating machine room power distribution simulation page and related equipment of Shenzhen science and technology (Shenzhen) Limited company, patent application number: 201910202555.7, it provides accuracy of page simulation, and largely reduces the time of connecting paths between each distribution device and the space for storing the connecting paths, and finally improves the wiring efficiency between the primitives.

As can be seen from the above related papers and patent applications, the discussion of machine room layout and equipment layout methods has been started in the industry, but the discussion still stays in the shallow layer, and researches are performed on the conventional machine room wiring management, pipeline monitoring modeling, or equipment layout limiting conditions, but the study still cannot meet the increasing importance of machine room layout work, but lacks the professional, automatic, and intelligent planning capabilities. In view of the related technical problems, no effective solution has been proposed at present.

Disclosure of Invention

The invention provides an automatic layout system and a generation method for equipment of a convergence machine room, aiming at solving the technical problems in the prior art, aiming at generating the layout of a machine cabinet and the automatic layout of the equipment in the machine cabinet in a convergence way according to the basic information of the equipment, the monitoring of thermal power and other factors and supporting the man-machine interaction adjustment of the layout.

In order to achieve the purpose, the invention provides the following technical scheme: an automatic equipment layout system of a convergence machine room comprises an equipment management module, a cabinet management module, a field management module, a convergence planning module and a user management module;

the device management module comprises a device definition submodule and a device adding submodule and is mainly used for defining and initializing devices needing to be converged, the device definition submodule comprises a type sType, a height sHigh, a power consumption sPower, a network consumption sNet and a device name sTitle of the devices, and the device adding submodule can be used for adding the devices with the same name sTitle in batches, automatically adding sID, a device interval sUnit and setting a service tag sSign for each device;

the cabinet management module comprises a cabinet definition submodule and a cabinet adding submodule and is mainly used for defining and initializing cabinets needing to be converged, wherein the cabinet definition submodule comprises a type cType, a width cWidth, a depth cDeep and a height cUnit of the cabinets, and the cabinet adding submodule can be used for adding the cabinets with the same name cTitle in batches, automatically adding a cID for each cabinet and setting a position tag cSign;

the field management module comprises a field definition submodule and an abnormal area definition submodule, and is mainly used for finishing the definition of a machine room area and the definition of an abnormal area where a cabinet can not be placed and determining the available space of the machine room;

the convergence planning module comprises a cabinet convergence submodule, an equipment convergence submodule, a cabinet adjusting submodule and an equipment adjusting submodule, wherein the cabinet convergence submodule completes the automation specification of the cabinet,

the user management module comprises a user name uName, a user identifier uID, a user department uDept and a user password uPW.

Preferably, the system further comprises a temperature monitoring module and an operation monitoring module.

Preferably, the temperature monitoring module is used for reading and recording the value of the sensor.

Preferably, the operation monitoring module is configured to be installed in an already deployed device, and is configured to read an operation state and a network usage of the device.

Preferably, the site definition submodule is divided into rectangular areas, the irregular site area can be defined as a plurality of rectangular areas, and the abnormal area definition submodule is used for dividing the abnormal area which cannot be used for placing the cabinet.

An automatic generation method of a convergence machine room equipment layout system comprises the following steps:

step 1: the convergence planning module is used for completing automatic convergence of the equipment cabinet and the equipment, wherein the automatic convergence of the equipment cabinet must be completed firstly;

step 2: the cabinet convergence submodule reads the field information in the field management module, determines a convergence rule, reads the abnormal region value, reads the cabinet information of the cabinet management module and completes the automatic convergence of the cabinet;

and step 3: the user can manually adjust the automatically converged cabinet planning scheme through the cabinet adjusting submodule, and finally, the automatic convergence of the cabinet is completed, and the cabinet planning scheme is output;

and 4, step 4: the equipment convergence submodule reads the equipment information of the equipment management module and the cabinet planning scheme output by the cabinet adjusting submodule to complete the automatic convergence of the equipment,

and 5: and finishing the equipment planning scheme through the equipment adjusting submodule, and correcting the equipment planning scheme according to the temperature monitoring data and the operation monitoring data at the later stage.

Compared with the prior art, the invention has the beneficial effects that:

the invention relates to an automatic layout system and a generation method for converging machine room equipment, which can converge and generate cabinet layout and automatic layout of the equipment in a cabinet in a machine room according to basic information of the equipment, monitoring of thermal power and other elements, and support human-computer interaction adjustment of the layout.

Drawings

FIG. 1 is a schematic structural diagram of a device management module and its submodules according to the present invention, illustrating the main data generated by the module and provided for device aggregation;

FIG. 2 is a schematic structural diagram of a cabinet management module and its sub-modules, illustrating the main data generated by the module and provided for cabinet aggregation and equipment aggregation;

FIG. 3 is a schematic diagram of the site management module and its sub-modules, illustrating the main data generated by the module and provided for cabinet aggregation and equipment aggregation;

FIG. 4 is a schematic structural diagram of a convergence planning module and its sub-modules;

fig. 5 is a main module structure diagram of the present invention, and a visual cabinet planning scheme and a visual equipment planning scheme are finally generated;

fig. 6 is a schematic diagram of a visual field generated in the field management module, which illustrates a coordinate generation manner of the visual field of a basic L-shaped machine room;

FIG. 7 is a schematic diagram of an abnormal area in the site management module, illustrating a method for selecting a coordinate point when a square exclusion area appears in the machine room;

FIG. 8 is a schematic diagram of an abnormal area in the site management module, illustrating a method for selecting a coordinate point when a circular exclusion area is present in the machine room;

fig. 9 is a plan view of a cabinet with abnormal areas generated according to an embodiment of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Examples

Referring to fig. 1 to 9, the present invention provides a technical solution of a layout system and a generation method of an automated convergence machine room device: fig. 5 is a schematic diagram of a module structure provided according to an embodiment of the present invention, and a cabinet planning scheme and an equipment planning scheme can be generated by automated convergence according to the present invention, where main modules of the system include an equipment management module shown in fig. 1, a cabinet management module shown in fig. 2, a site management module shown in fig. 3, a convergence scale module shown in fig. 4, a temperature monitoring module, an operation monitoring module, and a user management module.

The user management module is used for managing users who can use the system formed by the embodiment of the invention and are registered and authorized by the user management module, and other modules in the embodiment of the invention can be used for completing automatic planning and design.

The device management module, as shown in fig. 1, includes a device definition sub-module and a device addition sub-module, and mainly completes the definition and initialization of devices to be aggregated, where the device definition sub-module includes a type sType of the device, a height sHigh, a power consumption sPower, a network consumption sNet, and a device name sTitle, and the device addition sub-module may increase devices with the same name sTitle in batches, and automatically add sID, a device interval sUnit, and set a service tag sSign for each device.

The type sType of the device is a system preset value, the internal transmission data is 0, 1 and 2, and the user interface is displayed as label data, wherein 0 is equal to the server device, 1 is equal to the storage device, and 2 is equal to the network device.

Specifically, the height sHigh, which defines the physical height of the device, i.e. the actual space occupied by the device in the cabinet, can be entered by the user with an arabic number of 1-10, and the height is given by U of the standard cabinet, where 1U is 4.445 cm.

In particular, the power consumption sPower is the nominal power at which the device is powered.

Specifically, the network consumption sNet is the network bandwidth required by the device to work, and a natural number greater than 0 needs to be input, and the unit is an international standard unit for network transmission.

Specifically, the device name sstitle is a general name of the device, and this embodiment takes defining the sttitle as a computing server, and through definition, information of the computing server may be defined as follows: type server device, sdhigh-2U, sPower-1500W, sNet-10 Mb.

Specifically, the device adding submodule may only add or batch-add devices defined by the device defining submodule, and when the batch addition is performed, add a specified number of similar devices in a device library of the system, where the generated devices use an sID as a unique identifier, the sID is a digital string automatically generated by the system and recorded in the database, and the digital string has uniqueness in the database, and in a system internal transmission process, the aggregation of the devices all uses the sID as unique index information.

Specifically, in order to distinguish different devices, a label sign may be set for the devices after batch addition, so as to display an intuitive device name to a user, for example, the sign is an office application server, and is used to represent main information of the devices, and is used for daily management of the devices.

The cabinet management module, as shown in fig. 2, includes a cabinet definition sub-module and a cabinet addition sub-module, and mainly completes definition and initialization of the cabinets to be aggregated, where the cabinet definition sub-module includes a type cType, a width cgidth, a depth cdep, and a height cnit of the cabinet, and the cabinet addition sub-module may add the cabinets with the same name cTitle in batch, automatically add a cID to each cabinet, and set a location tag cSign.

Specifically, cabinet type cType is the system default, and inside transmission data is 0, 1, and user interface shows for the label data, wherein 0 equals server cabinet, 1 equals the network cabinet.

Specifically, the width cWidth is the maximum value of the external width of the cabinet, and the numerical constraint is greater than 0 in meters.

Specifically, the depth cdep is the maximum value of the external depth of the cabinet, and the numerical constraint is greater than 0 in meters.

Specifically, the height crit is a space provided inside the cabinet, and the number of months is a natural number greater than 0, and the unit is U of a standard cabinet, such as 42U.

Specifically, the cabinet name cTitle is a general name of the cabinet, such as a full-height server cabinet, and the cTitle allows a user to define the name cTitle.

Specifically, the cabinet adding submodule can only add or batch-add cabinets defined by the cabinet defining submodule, when batch addition is performed, a specified number of similar cabinets are added in an equipment library of the system, the generated equipment takes the cID as a unique identifier, the cID is a digital string which is automatically generated by the system and recorded in the database, the digital string has uniqueness in the database, and in the internal transmission process of the system, the aggregation of the equipment takes the cID as unique index information.

Specifically, in order to visually display the location of the cabinet, the user may edit the location label cSign of the cabinet, for example, if the cSign is set to L3-5, which represents that the planned placement location of the cabinet is the fifth of the third row.

The site management module, as shown in fig. 3, includes a site definition sub-module and an abnormal area definition sub-module, and mainly completes definition of an equipment room area and an abnormal area definition where a cabinet placement position cannot be performed, and determines an available space of the equipment room.

Specifically, the site definition sub-modules are divided into rectangles, irregular site areas can be defined as a plurality of rectangular areas, such as L-shaped areas, U-shaped areas, mouth-shaped areas and the like, and the area names rName, the area lengths rLong, the area widths rWidth, the arrangement modes rRule, the arrangement distances rSpace1 and rSpace2 need to be defined; the abnormal area definition submodule is used for dividing abnormal areas which cannot be placed in the cabinet, such as a bearing column, a fire-fighting cabinet, a power cabinet and the like, and needs to define an abnormal area x, an abnormal area y, an abnormal area aID and an abnormal area name aName.

Specifically, the area name rNmae is a name given to a single rectangular area after the machine room is cut into different rectangles, the area width rWidth is the horizontal width of the rectangle and is a value of x in the graphic coordinate system, the area length rLong is the vertical length of the rectangle and is a value of y in the graphic coordinate system.

Specifically, the arrangement mode rRule is a basic mode of automatic convergence, each rectangular area intelligently has an arrangement mode, system data of the arrangement mode rRule is 0 or 1, 0 represents that the arrangement mode of the cabinets is horizontal arrangement, and 1 represents that the arrangement mode of the cabinets is vertical arrangement; the range interval rSpace1 is the row and column interval of the cabinet, the unit is meter, the default value of the system is 1.5, the user can modify by definition, the range interval rSpace2 is the minimum interval between the cabinet and the wall of the machine room, the unit is meter, the default value of the system is 0.5 meter, and the user can modify by definition.

Specifically, each rectangular area has an rName for identification, and the rnames can be customized but cannot be repeated.

As shown in fig. 6, the system defines an L-shaped field space, which is formed by two rectangular areas, rName 1 and rName 2. The system confirms the structure of the machine room space and performs visual display by confirming a rectangular area through two-point coordinates, wherein rName is 1 rectangular area, the starting coordinate (0, 0) and the end coordinate (x, y), wherein x is the horizontal distance of the rectangular area relative to the origin and is x meters (marked by xm in the figure), and y is the vertical distance of the rectangular area relative to the origin and is y meters (marked by ym in the figure). A rectangular area with a home value of (x, -y1), wherein x is the horizontal distance of the origin 1 of the rectangular area from the origin and is x meters (indicated by xm in the figure), y1 is the vertical distance of the origin 1 of the rectangular area from the origin and is-y meters (indicated by-y 1m in the figure), and the end coordinates are (x + x1, y), wherein xx is the horizontal distance of the origin 1 of the rectangular area from the origin and is x meters (indicated by xm in the figure), x1 is a rectangular area with a home value of (rName) 2 and is x1 meters (indicated by x1m in the figure), and y is the vertical distance of the rectangular area from the origin and is y meters (indicated by ym in the figure).

As shown in fig. 7, the abnormal area aaname is 1, which defines an abnormal area with a square bearing column in the middle, the abnormal area represents that the location cannot be placed, the coordinate system of the bearing column is represented as a starting point (x1, y1), an end point (x2, y2), x1 represents that the location is horizontally spaced from an origin point x1 meters, y1 represents that the location is vertically spaced from an origin point y1 meters, x2 represents that the location is horizontally spaced from an origin point x2 meters, and y2 represents that the location is vertically spaced from an origin point y2 meters, when the horizontal width of the bearing column is x2-x1 meters, and the vertical width of the bearing column is y2-y1 meters.

As shown in fig. 8, the anomaly area acame is 2, which defines an anomaly area with a circular bearing column in the middle, where the anomaly area represents that the location cannot be used for equipment placement, in the embodiment of the present invention, the anomaly area occupancy is still performed in a rectangular manner, the coordinate system of the bearing column is represented as a starting point (x1, y1), an ending point (x2, y2), x1 represents that the location is horizontally spaced from the origin x1 meters, y1 represents that the location is vertically spaced from the origin y1 meters, x2 represents that the location is horizontally spaced from the origin x2 meters, y2 represents that the location is vertically spaced from the origin y2 meters, where the horizontal width of the bearing column is x2-x1 meters, and the vertical width of the bearing column is y2-y1 meters.

In this embodiment, a user needs to complete maintenance of basic information of a device in a device management module, and confirm the type of the device and the number of devices that need to be aggregated and planned; completing basic information maintenance of the cabinets in a cabinet management module, and confirming the types of the cabinets and the number of the cabinets needing to be aggregated and planned; after coordinate input and exclusion of abnormal regions are completed in the field management, automatic generation of a planning plan can be performed.

Specifically, it should be noted that the planning scheme for the cabinet must be completed first, otherwise the planning scheme for the equipment cannot be completed.

Specifically, after the user completes the information setting, the cabinet convergence submodule is started, and the cabinet convergence submodule reads the area information of the machine room and the size information and the quantity information of the cabinet from the database, and completes the convergence work according to the following steps:

s001, confirming the arrangement mode of the cabinets according to the rRule information of the site, and placing a first cabinet C1 according to rSpace 2;

s002, performing operation allowance evidence obtaining according to x or y data and rWidth data of the field, and determining the number of cabinets arranged in a line;

s003, confirming the occupied area of the cabinet C1 according to the information of rWidth, rLong, rSpace1 and rSpace2, and if the occupied area is overlapped with the abnormal area, relocating the cabinet C1 by taking x2 or y2 of the abnormal area as a starting point;

s004, when the replacement occurs, calculating the number of the placed parts to be-1 according to S002;

s005, repeating S003 and S004 until the current line is placed;

s006, confirming the position of the second row for placing the first cabinet according to the position of C1 and the information of rSpace1 and rSpace 2;

s007, repeating the steps until a new cabinet cannot be placed in the current machine room area, and generating a cabinet planning suggestion scheme;

s008, in the visual proposal, a user can drag the position of the cabinet through a mouse to adjust the scheme and generate a cabinet planning scheme.

As shown in fig. 9, through the above steps, the effect of placing the cabinet in the current rectangular area.

And after the user finishes the planning of the cabinet, equipment convergence planning can be carried out on the cabinet planning scheme.

Specifically, after the user starts the equipment convergence submodule, the equipment convergence submodule reads the placing positions of all the cabinets in the cabinet planning scheme and the types of the equipment which can be accommodated by the cabinets, and finishes the equipment convergence work according to the following steps:

s101, performing primary matching according to the cType information of the cabinet and the sType information of the equipment;

s102, uniformly distributing the equipment allowed to be placed in the cabinet types to the cabinets of the same type;

s103, binding the sID of the equipment with the cID of the cabinet;

s104, placing the equipment in the same cabinet from 1U, sequentially placing every two pieces of equipment at the interval of 1U, and storing the position information into an equipment planning proposal;

s105, the user adjusts the equipment in the equipment planning proposal through the equipment adjusting submodule, or after the parameters are reset, the equipment is converged again;

s106, generating a formal equipment planning scheme;

through the steps, equipment planning of a batch starting process of the new machine room can be completed.

Meanwhile, in the embodiment of the invention, after the machine room is started, the equipment planning scheme can be updated in newly added equipment or batch newly added equipment:

s201, reading current equipment planning scheme information, and acquiring equipment types placed in each cabinet and cabinet residual space information;

s202, performing preliminary matching according to the cType information of the cabinet and the sType information of the equipment;

s203, reading the temperature information of each cabinet from the temperature sensor through the temperature detection module, and preferentially putting newly-added equipment into the cabinet with lower temperature;

s204, sequentially placing the newly added equipment in the same cabinet at a distance of 1U from the last equipment, and storing the position information into an equipment planning proposal;

s205, the user adjusts the equipment in the equipment planning proposal through the equipment adjusting submodule;

s206, generating a formal equipment planning scheme;

in the embodiment of the present invention, in the formal operation process of the machine room, the equipment convergence scheme can be adjusted according to the specific equipment operation status, and particularly, the monitoring and adjustment are performed according to the operation of the server equipment, so as to improve the operation efficiency and the safety of the machine room, and the specific method is implemented by the following steps:

s301, monitoring the temperature environment of each cabinet in real time through a temperature monitoring module, and reading the numerical value in the temperature sensor into the system;

s302, when the temperature in the cabinet exceeds an early warning threshold value, sending an active popup window early warning to a system user;

s303, the popup window information visually displays the position of the cabinet and the information of equipment placed in the cabinet;

s304, a system user can read the running state information of the equipment from the copy information of the current cabinet through the Euro running monitoring module, wherein the running state information comprises the temperature, the memory use condition, the network use condition and other related information of the equipment, so that the heat source can be visually judged;

s305, a system administrator can migrate the equipment causing the early warning and migrate the equipment to other cabinets with the same type and lower temperature;

and S306, regenerating the equipment planning scheme.

It should be obvious to those skilled in the art that the above modules or steps of the present invention may be implemented by using a computer, and names of the modules may be customized without affecting implementation manners of the embodiments of the present invention, and optionally, the present invention may be described as different steps by using different program tools or control manners.

An automatic generation method of a convergence machine room equipment layout system comprises the following steps:

step 1: the convergence planning module is used for completing automatic convergence of the equipment cabinet and the equipment, wherein the automatic convergence of the equipment cabinet must be completed firstly;

step 2: the cabinet convergence submodule reads the field information in the field management module, determines a convergence rule, reads the abnormal region value, reads the cabinet information of the cabinet management module and completes the automatic convergence of the cabinet;

and step 3: the user can manually adjust the automatically converged cabinet planning scheme through the cabinet adjusting submodule, and finally, the automatic convergence of the cabinet is completed, and the cabinet planning scheme is output;

and 4, step 4: the equipment convergence submodule reads the equipment information of the equipment management module and the cabinet planning scheme output by the cabinet adjusting submodule to complete the automatic convergence of the equipment,

and 5: and finishing the equipment planning scheme through the equipment adjusting submodule, and correcting the equipment planning scheme according to the temperature monitoring data and the operation monitoring data at the later stage.

The invention can assemble and generate the layout of the cabinet and the automatic layout of the equipment in the cabinet in the machine room according to the basic information of the equipment, the monitoring of the thermal power and other elements, and supports the human-computer interaction adjustment of the layout.

In the description of the present invention, it is to be understood that the terms "coaxial", "bottom", "one end", "top", "middle", "other end", "upper", "one side", "top", "inner", "front", "center", "both ends", and the like, indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and thus, are not to be construed as limiting the present invention.

In the present invention, unless otherwise expressly specified or limited, the terms "mounted," "disposed," "connected," "secured," "screwed" and the like are to be construed broadly, e.g., as meaning fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; the terms may be directly connected or indirectly connected through an intermediate, and may be communication between two elements or interaction relationship between two elements, unless otherwise specifically limited, and the specific meaning of the terms in the present invention will be understood by those skilled in the art according to specific situations.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. An automatic layout system of equipment in a convergence machine room is characterized by comprising an equipment management module, a cabinet management module, a field management module, a convergence planning module and a user management module;

the device management module comprises a device definition submodule and a device adding submodule and is mainly used for defining and initializing devices needing to be converged, the device definition submodule comprises a type sType, a height sHigh, a power consumption sPower, a network consumption sNet and a device name sTitle of the devices, and the device adding submodule can be used for adding the devices with the same name sTitle in batches, automatically adding sID, a device interval sUnit and setting a service tag sSign for each device;

the cabinet management module comprises a cabinet definition submodule and a cabinet adding submodule and is mainly used for defining and initializing cabinets needing to be converged, wherein the cabinet definition submodule comprises a type cType, a width cWidth, a depth cDeep and a height cUnit of the cabinets, and the cabinet adding submodule can be used for adding the cabinets with the same name cTitle in batches, automatically adding a cID for each cabinet and setting a position tag cSign;

the field management module comprises a field definition submodule and an abnormal area definition submodule, and is mainly used for finishing the definition of a machine room area and the definition of an abnormal area where a cabinet can not be placed and determining the available space of the machine room;

the convergence planning module comprises a cabinet convergence submodule, an equipment convergence submodule, a cabinet adjusting submodule and an equipment adjusting submodule, wherein the cabinet convergence submodule completes the automation specification of the cabinet,

the user management module comprises a user name uName, a user identifier uID, a user department uDept and a user password uPW.

2. The layout system of the automated convergence machine room equipment of claim 1, wherein: the device also comprises a temperature monitoring module and an operation monitoring module.

3. The layout system of the automated convergence machine room equipment of claim 2, wherein: the temperature monitoring module is used for reading and recording the numerical value of the sensor.

4. The layout system of the automated convergence machine room equipment of claim 2, wherein: the operation monitoring module is used for being installed in deployed equipment and used for reading the operation state and the network use condition of the equipment.

5. The layout system of the automated convergence machine room equipment of claim 1, wherein: the field definition submodule is divided into a plurality of rectangular areas in a rectangular mode, irregular field areas can be defined as the plurality of rectangular areas, and the abnormal area definition submodule is used for dividing abnormal areas where cabinet placement positions cannot be carried out.

6. The method for generating the layout system of the automated converged machine room equipment according to claims 1 to 5, wherein the method comprises the following steps:

step 1: the convergence planning module is used for completing automatic convergence of the equipment cabinet and the equipment, wherein the automatic convergence of the equipment cabinet must be completed firstly;

step 2: the cabinet convergence submodule reads the field information in the field management module, determines a convergence rule, reads the abnormal region value, reads the cabinet information of the cabinet management module and completes the automatic convergence of the cabinet;

and step 3: the user can manually adjust the automatically converged cabinet planning scheme through the cabinet adjusting submodule, and finally, the automatic convergence of the cabinet is completed, and the cabinet planning scheme is output;

and 4, step 4: the equipment convergence submodule reads the equipment information of the equipment management module and the cabinet planning scheme output by the cabinet adjusting submodule to complete the automatic convergence of the equipment,

and 5: and finishing the equipment planning scheme through the equipment adjusting submodule, and correcting the equipment planning scheme according to the temperature monitoring data and the operation monitoring data at the later stage.

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