WO2013177643A1 - Modular electrical enclosure - Google Patents

Abstract

The present invention relates to a modular electrical enclosure comprising at least two modules, each module having at least one joining side without walls, and the modules being joined at the respective joining sides. In a configuration suitable for hoisting, each module is provided with hoisting points located on the outer beams of the covering structure. For at least one hoisting point located in a joining side, between the outer vertical beams, at least one removable intermediate beam is provided; the lower end of the removable intermediate beam is attached to an outer beam of the main structure, and the upper end of the removable intermediate beam is attached to an outer beam of the covering structure. In the finished assembled configuration, none of the joining sides is provided with removable intermediate beams. According to the invention, when the modules are manufactured, the removable intermediate beams are attached to the structure of the modules. These removable intermediate beams fulfill a structural function, allowing the modules to be hoisted for being moved and transported. Once the modules have been transported to the working site and assembled, forming the final assembled configuration of the modular electrical enclosure, the removable intermediate beams are removed. Thus, the common inside region of the modular electrical enclosure is completely free of inner pillars.

Description

 Report of the Invention Patent "ELETROCENTRO"

MODULAR ".

 The present invention relates to a modular electrocenter. Electrocenters are facilities responsible for housing power and control equipment for industrial plants. To ensure the proper functioning and durability of such equipment, the area inside the electrocenter is kept under temperature and pressure control. In addition, a good protection of the internal area from the external environment is necessary, keeping the equipment free of climatic actions and other external agents.

 Conventionally, the electrocenters are built in masonry directly in the workplace, being the assembly and testing of all equipment performed after its construction. However, many industrial plants are located considerably away from large urban centers, making the installation and testing phase of the equipment in the high cost or even unfeasible.

 Alternatively, electrocenters built from a container structure emerged. Thus, the vast majority of electrocenter equipment is assembled and tested at the factory itself. Afterwards, the container-shaped electrocenter is transported to the industrial plant, where a final stage of installation at the workplace is performed. Due to transport restrictions, container-shaped electrocenters must comply with certain dimensions. Thus came the concept of modular electrocenter, in which container-shaped modules are manufactured, with the required equipment, and, after transportation, are installed in the industrial plant, giving rise to the modular electrocenter.

A container-shaped electrocenter module is made up of geometrically shaped like a regular rectangular prism, its edges being comprised of beams with structural functions. The faces are made up of walls with insulation function in relation to the external environment. Additionally, intermediate vertical beams are provided, also with structural function.

 By way of example, a container-shaped electrocenter module may comprise four vertical beams, in positions relative to the vertical edges, plus six intermediate vertical beams, three intermediate vertical beams on either side of the module length. In an electrocenter configuration formed by the assembly of two modules side by side, one of the side faces of each module is devoid of walls, and the assembly of the two modules is carried out by the face-to-face union of said side faces without walls. Thus, both modules give rise to an internal area common to the modular electrocenter.

However, between the two modules, the three intermediate vertical beams of the wallless face of each module remain, each intermediate vertical beam of one module being positioned face to face with an intermediate vertical beam of the other module. Thus, in this two-module electrocenter configuration, there are three pillars internal to the common area, each internal pillar being defined as the face-to-face junction of two intermediate vertical beams. These internal pillars constitute a major drawback for the organization of the internal area common to the modular electrocenter. For example, these internal pillars represent a loss of working area, with the positioning of power and control equipment restricted to the positioning of the internal pillars. In addition, safety standards require minimum clearance for the placement of panels in relation to the structure, so that the existence of internal pillars becomes more critical to internal organization. In addition, escape route configuration and overall mobility within the electrocenter are impaired.

 In order to eliminate these drawbacks the present invention proposes a modular electrocenter comprising at least two modules, each module being comprised of a substantially horizontal and flat base structure formed by at least one outer perimeter bounding beams, and on the base structure are arranged tall external beams and above the height external beams a roof structure is formed, formed at least by external beams delimiting a perimeter substantially coincident with the perimeter of the base structure, and a floor arranged on the base structure. base, a covering arranged on the covering structure and walls arranged between the tall outer beams. Each module is further provided with at least one wall-less joining face, said modules joined together by their respective joining faces, and each module, in a configuration suitable for lifting via lifting, with lifting points, located at the outer beams of the roof structure, and for at least one lifting point located on a joint face and in an intermediate position between the tall outer beams there is at least one removable intermediate beam, said removable intermediate beam having its lower end fixed. to an outer beam of the base frame and its upper end is fixed to an outer beam of the roof structure, and each joining face, in a finished mounting configuration, devoid of removable intermediate beams.

According to the invention, after manufacture, the modules have the removable intermediate beams fixed in their structure. These beams Removable intermediates fulfill a structural function, enabling the lifting of the modules for their movement and transport. After shipping, positioning the modules in the workplace, and assembling the modules together, resulting in a finished modular electrocenter mounting configuration, the removable intermediate beams are removed. Thus, the internal area common to the modular electrocenter is completely free of internal pillars. Advantageously, from the proposed solution, the organization of the internal area common to the modular electrocenter is facilitated by increasing the positioning options of the power and control equipment. Escape route planning and overall mobility within the electrocenter are also facilitated.

 The invention will be better understood with the following detailed description, which will be best interpreted with the aid of the figures, namely:

 Figure 1 shows a perspective view of two modules 100 not assembled together in a configuration suitable for lifting via a first embodiment of the invention.

 Figure 2 is a perspective view, with a "V" center section, of two modules (100) mounted together, each module (100) in a configuration suitable for lifting via a first embodiment of the invention. .

 Figure 3 shows a perspective view, with a central "V" section, of two modules (100) mounted together in a finished modular electrocenter mounting configuration in accordance with a first embodiment of the invention.

Figure 4 presents a perspective view of a module (200), with emphasis on its joint face (255), in a configuration able to move lift, according to a second embodiment of the invention.

 Figure 5 shows a perspective view of a module (200), with an emphasis on its side face opposite to the joint face (255), in a configuration suitable for hoisting movement, according to a second embodiment of the invention.

 Figure 6 shows a perspective view of three unmounted modules 200 in a configuration suitable for lifting via a second embodiment of the invention.

 Figure 7 is a perspective view, with a central "V" section, of three modules (200) mounted together, each module (200) in a configuration suitable for hoisting movement, according to a second embodiment of the invention.

 Figure 8 is a perspective view, with a central "V" section, of three modules (200) mounted together in a finished modular electrocenter mounting configuration in accordance with a second embodiment of the invention.

 The following detailed description is performed according to two embodiments of the invention. For ease of understanding, elements of the second embed mode that are equivalent to the elements of the first embed mode have their references appended with "100". Thus, module (100). refers to the first embodiment of the invention and module (200) refers to the second embodiment of the invention. The two embodiments of the invention differ by reversing the mounting direction of the modules (100, 200) to each other, both giving rise to a modular electrocenter.

According to the first embodiment of the invention, an electrocenter The modular module comprises at least two modules (100). Each module 100 is comprised of a substantially horizontal and flat base frame 110 formed of at least one outer perimeter bounding beams. Preferably, the outer beams of the base frame 110, as shown in Figure 1, are comprised of two parallel long beams 112 and two short parallel beams 114 being the two. short beams (114) joined to long beams (112) to form a rectangular structure.

 Overlying the base frame (110) are tall external beams, responsible for giving a height elevation to the module (100). Preferably, as can be seen from Figure 1, the tall outer beams are comprised of four outer beams (130) joined over the base frame (110) in substantially upright position.

 Overlying the height outer beams is a roof structure (120) formed at least by outer beams delimiting a perimeter substantially coincident with the perimeter of the base structure (110). Preferably, as can be seen from Figure 1, the outer beams of the roof structure (120) are comprised of two long beams (122), parallel to each other, and two short beams (124), parallel to each other, the beams being short (124) joined to the long beams (122) to form a rectangular structure.

Over the base structure (110) of a module (100) is arranged a floor (140), preferably in the form of modular sheets, to isolate the lower part of the module (100) from the external environment. Over the cover structure (120) of a module (100) a cover (160) is arranged to isolate the upper part of the module (100) from the external environment. Between the outer height beams, more particularly between the outer beams (130), walls (150) are arranged to laterally insulate the module (100) from the outside, except for at least one face, said face being defined as the joining face (155) to an adjacent module (100). Preferably, the walls 150 are comprised of modular sheets.

 In a configuration suitable for hoisting movement, the module (100) is provided with at least four lifting points (190) located on the outer beams of the roof structure (120). More particularly, the lifting points (190) are located on the long beams (122) of the roof structure (120), with half of the lifting points (190) on each long beam (122). Preferably, the lifting points 190 are fixed with the aid of bolted joints. By way of example, as shown in Figure 1, a module (100) may be provided with six lifting points (190) located on the long beams (122) of the roof structure (120), three lifting points (190) ( 190) on each long beam (122).

In a configuration suitable for lifting via lifting, to at least one lifting point (190) located on a joint face (155) and in an intermediate position between the outer height beams, more particularly between the outer beams (130), there is at least one removable intermediate beam (170), said removable intermediate beam (170) having its lower end (172) attached to the outer beam of the base structure (110), more particularly to the long beam (112), and its end. top (174) fixed to the outer beam of the roof structure (120), more particularly to the long beam (122). Preferably, the fixing of the removable intermediate beams 170 is carried out with the aid of bolted joints. The removable intermediate beams (170) fulfill a function enabling the module (100) to be lifted for movement and transport.

 Preferably, there is a pair of removable intermediate beams (170) in an inclined position for each lifting point (190) located on a joint face (155) and in an intermediate position between the tall outer beams, more particularly between the beams 130, each removable intermediate beam (170) having its lower end (172) attached to the outer beam of the base frame (110), more particularly to the long beam (112), and its upper end (174) attached to the beam of the roof structure (120), more particularly to the long beam (122), the upper end extensions (174) being said competing removable intermediate beams (70). By way of example, as shown in Figure 1, for a module (100) having three lifting points (190) located on the joint face (155) and in an intermediate position between the outer beams (130) there are three removable intermediate beam pairs (170).

 In addition, a junction face 155 has a plurality of junction points 185 for enabling mounting of a module 100 to another adjacent module 100, resulting in a modular electrocenter. Preferably the joining points (185) are located on the long beam (122) of the cover frame (120) and the long beam (11) of the base frame (110).

For each other lifting point (190) located outside a joining face (155) and in an intermediate position between the tall outer beams, more particularly between the outer beams (130), there is at least one outer intermediate beam (180) said outer intermediate beam (180) having its lower end (182) attached to the outer beam of the base frame (110), more particularly to the long beam (112), and its upper end (184) attached to the outer beam of the roof structure (120), more particularly to the long beam (122). The external intermediate beams (180) fulfill a structural function, enabling the lifting of the module (100) for its movement and transport.

 Preferably, for at least one lifting point (190) located outside a joint face (155) and in an intermediate position between the tall outer beams, more particularly between the outer beams (130), there is a pair of outer intermediate beams. (180), in an inclined position, each outer intermediate beam (180) having its lower end (182) attached to the outer beam of the base frame (110), more particularly to the long beam (11), and its upper end (184). ) fixed to the outer beam of the roof structure (120), more particularly to the long beam (122), the extensions of the upper end (184) of said outer intermediate beams (180) competing with each other. Preferably, the outer intermediate beams 180 are removable. In case the external intermediate beams (180) are removable, they are fixed to the module (100) in a configuration suitable for lifting via lifting. In this case, preferably, the fixing of the outer intermediate beams (180) is carried out with the aid of bolted joints externally with respect to the walls (150). By way of example, as can be seen from Figure 1, for a module (100) having three lifting points (190) located off the joint face (155) and in an intermediate position between the outer beams (130) there are three pairs of external intermediate beams (180). Preferably, these three pairs of outer intermediate beams (180) are removable.

Preferably, the modular electrocenter comprises a roof (165) disposed on the cover (160) of the cover structure (120). According to First embodiment of the invention, a water (166) from the roof (165) is located in a module (100) and the complementary water (166) is located in an adjacent module (100).

 A module (100) may comprise secondary beams (158) positioned vertically between an outer beam of the base frame (110), more particularly a long beam (112), and an outer beam of the roof structure (120), more particularly a long beam (122). The function of the secondary beams (158) is restricted to allowing the attachment of the walls (150) to the module (100), not fulfilling other structural functions.

 After fabrication, in a configuration suitable for hoisting movement, a module (100) has its removable intermediate beams (170) fixed to its structure. If the external intermediate beams (180) are removable, they are also fixed to the module structure (100), in a configuration suitable for hoisting movement, as shown in Figure 1. Control and power equipment (not shown) ) are also installed in the module (100).

The module (100) can be lifted via lifting points (190) and transported, with the aid of a means of transport, to its workplace. In the workplace, module (100) is properly positioned via lifting in its working position. A second module (100) is positioned adjacent to the first module (100), with its respective joining faces (155) positioned face to face. The assembly of the first module (100) to the adjacent module (100) is carried out by means of the joining points (185), preferably with the aid of bolted joints. By way of example, one can see in Figure 2 a module (100) mounted to an adjacent module (100) in a configuration with roof (165) and removable intermediate beams (180). The removable intermediate beams (170) can also be viewed in Figure 2.

 Mounting a module (100) to the adjacent module (100) results in a modular electrocenter. After assembly, the removable intermediate beams (170) are removed. Thus, in a finished assembly configuration, each joint face (155) is devoid of removable intermediate beams (170). This way, the internal area common to the modular center is totally free of internal columns, as shown in Figure 3. If the external intermediate beams (180) of the module (100) are removable, after mounting a module (100 ) to the adjacent module (100), said external intermediate beams (180) may also be removed. Thus, in a finished mounting configuration, the outer intermediate beams (180) are detached from the module - (100). A finalized modular electrocenter assembly configuration can be viewed in Figure 3.

After mounting a module (100) to an adjacent module (100) the lifting points (190) may also be removed. Thus, in a finished modular electrocenter mounting configuration, modules (100) may be devoid of lifting points (190). In a roofed modular electrocenter configuration (165), after removal of the lifting points (190) located on the joining faces (155), a ridge (168) is mounted on the central ends of the waters (166), As can be seen in Figure 3. Thus, in a finished modular electrocenter assembly configuration, a ridge (168) is located over the central ends of the waters (66). In addition, at least one access point to the internal area common to the modular center is provided, for example from a door (not shown). THE By way of example, a module 100 may be 24 meters long and 5 meters wide.

 According to the second embodiment of the invention, a modular electrocenter comprises at least two modules (200). Each module 200 is comprised of a substantially horizontal and flat base frame 210 formed of at least outer perimeter bounding beams. Preferably, the outer beams of the base frame 210, as shown in Figures 4 and 5, are comprised of two parallel long beams 212 and two parallel short beams 214; the short beams (214) being joined to the long beams (212) to form a rectangular structure.

 On the base frame (210) are arranged tall external beams, responsible for giving a height elevation to the module (200). Preferably, as can be seen from Figures 4 and 5, the tall outer beams are comprised of four outer beams (230) joined over the base frame (210) in substantially upright position.

 Overlying the height outer beams is a roof structure (220) formed at least by outer beams delimiting a perimeter substantially coincident with the perimeter of the base structure (210). Preferably, as can be seen from Figures 4 and 5, the outer beams of the cover structure 220 are comprised of two long beams 222 parallel to each other and two short beams 224 parallel to one another. the short beams 224 joined to the long beams 222 to form a rectangular structure.

On the base structure (210) of a module (200) is arranged a floor (240), preferably in the form of modular sheets, to insulate the underside of module (200) from the external environment. Over the cover structure (220) of a module (200) a cover (260) is arranged to isolate the upper part of the module (200) from the external environment.

 Between the outer height beams, more particularly between the outer beams (230), walls (250) are arranged to laterally insulate the module (200) from the outside, except for at least one face, said face being defined as the joining face (255) to an adjacent module (200). Preferably, the walls 250 are comprised of modular sheets.

 In a configuration suitable for hoisting movement, the module (200) has at least four lifting points (290); located on the outer beams of the roof structure (220). More particularly, the lifting points (290) are located on the long beams (222) of the roof structure (220), with half of the lifting points (290) on each long beam (222). Preferably, the lifting points 290 are fixed with the aid of bolted joints. By way of example, as shown in Figures 4 and 5, a module (200) is provided with four lifting points (290) located on the long beams (222) of the roof structure (220), two lifting points being (290) on each long beam (222).

In a configuration suitable for lifting via lifting, to at least one lifting point (290) located on a joint face (255) and in an intermediate position between the outer height beams, more particularly between the outer beams (230), there is at least one removable intermediate beam (270), said removable intermediate beam (270) having its lower end (272) attached to the outer beam of the base frame (210), more particularly to the long beam (212), and its upper end (274) is attached to the outer beam of the roof structure (220), more particularly to the long beam (222). Preferably, the fixing of the removable intermediate beams 270 is carried out with the aid of bolted joints. The removable intermediate beams (270) fulfill a structural function, making it possible to lift the module (200) for its movement and transport.

 Preferably, there is a pair of removable intermediate beams (270) in an inclined position for each lifting point (290) located on a joint face (255) and in an intermediate position between the tall outer beams, more particularly between the beams 230, each removable intermediate beam (270) having its lower end (272) attached to the outer beam of the base frame (210), more particularly to the long beam (212), and its upper end (274) attached to the beam of the roof structure (220), more particularly to the long beam (222), the upper end extensions (274) of said removable intermediate beams (270) competing with each other. By way of example, as shown in Figure 4, for a module (200) having two lifting points (290) located on the joint face (255) and in an intermediate position between the outer beams (230) there are two removable intermediate beam pairs (270).

 In addition, a junction face 255 has a plurality of junction points 285 for enabling mounting of a module 200 to another adjacent module 200, giving rise to a modular electrocenter. Preferably the joining points (285) are located on the long beam (222) of the cover structure (220) and the long beam (212) of the base structure (210).

For each other lifting point (290) located off one side In the intermediate position between the high outer beams, more particularly between the outer beams 230, there is at least one outer intermediate beam 280, said outer intermediate beam 280 having its lower end (282). ) fixed to the outer beam of the base frame (210), more particularly to the long beam (212), and its upper end (284) fixed to the outer beam of the roof structure (220), more particularly to the long beam (222). The external intermediate beams (280) fulfill a structural function, enabling the lifting of the module (100) for its movement and transport.

Preferably, for at least one lifting point (290) located outside a joining face (255) and in an intermediate position between the tall outer beams, more particularly between the outer beams (230), there is a pair of outer intermediate beams. (280), in an inclined position, each outer intermediate beam (280) having its lower end (282) attached to the outer beam of the base frame (210), more particularly to the long beam (212), and its upper end (284) it is fixed to the outer beam of the roof structure (220), more particularly to the long beam (222), the upper end extensions (284) of said outer intermediate beams (280) competing with each other. Preferably, the outer intermediate beams (280) are removable. If the external intermediate beams (280) are removable, they are fixed to the module (200) in a configuration suitable for lifting via lifting. In this case, preferably, the fixing of the outer intermediate beams (280) is carried out with the aid of bolted joints externally with respect to the walls (250). By way of example, as can be seen in Figure 5, for a module (200) having two lifting points (290) located off the joint face (255) and in an intermediate position between the outer beams (230) there are two pairs of external intermediate beams (280). Preferably, these two outer intermediate beam pairs (280) are removable.

 Preferably, the modular electrocenter comprises a roof (265) disposed on the cover (260) of the cover structure (220). According to the second embodiment of the invention, both waters (266) of the roof (265) are located in a module (200). A ridge (268) is located over the central ends of the waters (266).

 A module (200) may comprise secondary beams (258) positioned vertically between an outer beam of the base frame (210), more particularly a long beam (212), and an outer beam of the roof structure (220), more particularly a long beam (222): The function of the secondary beams (258) is restricted to enabling the attachment of the walls (250) to the module (200), not fulfilling other structural functions.

 After fabrication, in a configuration suitable for hoisting movement, a module (200) has its removable intermediate beams (270) fixed to its structure, as shown in Figure 4. If the external intermediate beams (280) removable, they are also attached to the module frame (200), in a configuration suitable for lifting via lifting, as shown in Figure 5. Control and power equipment (not shown) are also installed in the module ( 200).

The module (200) can be lifted via lifting points (290) and transported, with the aid of a means of transport, to its workplace. In the workplace, module (200) is properly positioned via lifting in its working position. At least a second module (200) is positioned adjacent to the first module (200), with their respective joining faces (255) positioned face to face. The assembly of the first module (200) to the adjacent module (200) is carried out by means of the joining points (285), preferably with the aid of bolted joints. By way of example, one can see in Figure 6 three modules (200), in a configuration with roof (265) and removable external intermediate beams (280), before being mounted together. In this case, the intermediate module (200) has two joint faces (255), each joint face (255) suitable for mounting to an adjacent module (200). In Figure 7 one can see the three modules (200) mounted together.

 Mounting a module (200) to at least one adjacent module (200) results in a modular electrocenter. After assembly, the removable intermediate beams (270) are removed. Thus, in a finished assembly configuration, each joint face (255) is devoid of removable intermediate beams (270). Thus, the internal area common to the modular electrocenter is completely free of internal pillars, as shown in Figure 8, in a modular electrocenter configuration formed by mounting three modules (200) together. If the external intermediate beams (280) of the module (200) are removable, after mounting a module (200) to at least one adjacent module (200), said external intermediate beams (280) may also be removed. Thus, in a finished mounting configuration, the outer intermediate beams (280) are detached from the module (200). A finalized modular electrocenter mounting configuration can be viewed in Figure 8.

After mounting a module (200) to at least one adjacent module (200) the lifting points (290) can also be removed. Thus, in a finished modular electrocenter mounting configuration, the modules (200) may be devoid of lifting points (290). In a configuration of Modular electrocenter with roof (265), after removal of the lifting points (290), complementary tiles (269) are positioned at the ends of the modules (200), finishing the roof (265), as shown in Figure 8 Thus, in a finished modular electrocenter mounting configuration, complementary tiles (269) are arranged at the ends of the modules (200). In addition, at least one access point to the internal area common to the modular electrocenter is provided, for example from a door (254). By way of example, a module 200 may be 12 meters long and 5 meters wide.

 Advantageously, from the proposed solution, the internal area common to the modular electrocenter is completely free of internal pillars. Thus, the organization of the common internal area is facilitated by increasing the positioning options of the power and control equipment. Escape route planning and overall mobility within the electrocenter are also facilitated. Naturally, although the technical effect of the invention is associated with the elimination of the internal pillars within the common area of a modular electrocenter, if there is a need, for example, an organizational need, it is possible to assemble internal walls by dividing the internal area common to the modular electrocenter .

 The modular electrocenter can be mounted in your workplace directly on the ground or on supporting pillars. In addition, the modular electrocenter can be mounted on wheels, on a boat or on a floating structure, among others.

Of course, the modular electrocenter can also be mounted to accommodate different floors. Still, according to the first embodiment of the invention, other pairs of modules (100) may be mounted to a first pair of modules (100) to increase the length of the modular electrocenter.

 Preferred or alternative embodiments described herein are not capable of limiting the present invention to structural forms, and there may be constructive variations which are equivalent without, however, departing from the scope of protection of the invention.

Claims

 1. "MODULAR ELECTRIC CENTER", characterized in that it comprises at least two modules (100, 200), each module (100, 200) being comprised of a substantially horizontal and flat base structure (110, 210) formed by at least one beam. outer boundaries of a perimeter, and on the base frame (110, 210) are arranged tall outer beams and on the tall outer beams is arranged a roof structure (120, 220) formed at least by outer bounding beams of a perimeter substantially coincident with the perimeter of the base structure (110, 210), a floor (140, 240) disposed on the base structure (110, 210), a cover (160, 260) disposed on the cover structure (120, 220) and walls (150, 250) arranged between the tall outer beams, each module (00, 200) further having at least one joint face (155, 255) devoid of walls (150, 250) , said modules (100, 200) joined together through their respective joining faces (155, 255), each module (100, 200), in a configuration suitable for lifting via hoisting, provided with lifting points (190, 290), located on the outer beams of the roof structure (120, 220), for at least one lifting point (190, 290) located on a joining face (155, 255) and in an intermediate position between the height outer beams there is at least one removable intermediate beam (170, 270) , said removable intermediate beam (170, 270) having its lower end (172, 272) attached to an outer beam of the base frame (110, 210) and its upper end (174, 274) attached to an outer beam of the frame. (120, 220), and each joint face (155, 255), in a finished mounting configuration, devoid of removable intermediate beams (70, 270).

2. "MODULAR ELECTROCENTER" according to Claim 1, characterized in that there is a pair of removable intermediate beams (170, 270) in an inclined position for each lifting point (190, 290) located on a joint face (155, 255) and in an intermediate position between the tall outer beams, the upper end extensions (174, 274) being said competing removable intermediate beams (170, 270).

 "MODULAR ELECTROCENTER" according to Claim 1 or 2, characterized in that at least one external intermediate beam (180, 280) exists for each other lifting point (190, 290) located outside a joint face (155 255) and in an intermediate position between the tall outer beams, said outer intermediate beam (180, 280) having its lower end (182, 282) attached to the outer beam of the base frame (110, 210) and its upper end (184, 284) secured to the outer beam of the roof structure (120, 220).

 "MODULAR ELECTROCENTER" according to Claim 3, characterized in that there is a pair of external intermediate beams (180, 280) in an inclined position for at least one lifting point (190, 290) located off one side. joining (55, 255) and in an intermediate position between the tall outer beams, the upper end extensions (184, 284) of said outer intermediate beams (180, 280) competing with each other.

 "MODULAR ELECTRIC CENTER" according to Claim 3 or 4, characterized in that the external intermediate beams (180, 280) are removable and are fixed to the module (100, 200) in a configuration suitable for lifting via lifting; module (100, 200) in a finished assembly configuration.

"MODULAR ELECTRIC CENTER" according to Claim 1, characterized in that a joint face (155, 255) has a plurality of joint points. (185, 285).

 "MODULAR ELECTROCENTER" according to Claim 1, characterized in that it comprises secondary beams (158, 258) positioned vertically between an outer beam of the base frame (110, 210) and an outer beam of the roof structure ( 120, 220).

 "MODULAR ELECTRIC CENTER" according to claim 1, characterized in that it comprises a roof (165, 265) disposed on the roof (160, 260) of the roof structure (120, 220).

 "MODULAR ELECTROCENTER" according to claim 1, 3 or 7, characterized in that the outer beams of the base structure (110, 210) are comprised of two parallel long beams (112, 212) and two short beams (114, 214), parallel to each other, the short beams (114, 214) being joined to the long beams (112, 212) to form a rectangular structure.

 "MODULAR ELECTROCENTER" according to claim 1, 2, 3 or 4, characterized in that the tall outer beams are comprised of four outer beams (130, 230) joined to the base structure (110, 210); in a substantially upright position.

 "MODULAR ELECTROCENTER" according to Claim 1, 3 or 7, characterized in that the outer beams of the roof structure (120, 220) are comprised of two parallel long beams (122, 222) and two short beams (124, 224), parallel to each other, the short beams (124, 224) being joined to the long beams (122, 222) to form a rectangular structure.

"MODULAR ELECTROCENTER" according to Claim 1, 2, 3 or 4, characterized in that the modules (100, 200) are devoid of lifting points (190, 290) in a finished mounting configuration.

"MODULAR ELECTRIC CENTER" according to Claim 8, characterized in that a water (166) from the roof (165) is located in a module (100) and a complementary water (166) is located in an adjacent module (100). .

"MODULAR ELECTRIC CENTER" according to Claims 12 and 13, characterized in that a ridge (168) is located over the central ends of the waters (166) in a finished mounting configuration.

 "MODULAR ELECTRIC CENTER" according to Claim 8, characterized in that both waters (266) of the roof (265) are located in a module (200) and a ridge (268) is located over the central ends of the waters (26). 266).

 "MODULAR ELECTROCENTER" according to Claims 12 and 15, characterized in that complementary tiles (269) are arranged at the ends of the modules (200) in a finished mounting configuration.