CN111565532A - Stackable through interconnection combined box and modular through combined structure platform - Google Patents

Abstract

The invention discloses a stackable through interconnection combination box and a modular through combination structure platform. The stackable and interpenetrable combination box comprises a main body, wherein the main body is provided with a splicing wall, and the splicing wall is provided with an interface for installing an electrical interconnector. According to the technical scheme, the through interconnection interfaces are arranged on the splicing walls of the stackable through interconnection combination boxes, when the stackable through interconnection combination boxes are spliced and combined, the electrical interconnection devices are installed at the through interconnection interfaces, so that the electrical interconnection of the electrical equipment in the stackable through interconnection combination boxes can be realized, a modular through combination structure platform can be built under the condition that any number and any stacking mode of stackable through interconnection combination boxes are spliced and combined, the rapid and efficient electrical interconnection of the equipment in the stackable through interconnection combination boxes can be guaranteed, and the equipment interconnection cables in the stackable through interconnection combination boxes are not required to be disassembled.

Description

Stackable through interconnection combined box and modular through combined structure platform

Technical Field

The invention relates to the technical field of electrical equipment and electrical interconnection, in particular to a stackable through interconnection combined box and a modular through combined structure platform.

Background

In most applications, Automatic Test Equipment (ATE) or Automatic Test Systems (ATS) employ a standard equipment rack structure platform to carry the test resources and the installation of related equipment, and the electrical interconnection between the test resources or test equipment is implemented by means of interconnection cables disposed within the rack.

With modern electronic measurement and detection technologies, particularly in the field of measurement and control, under the promotion of the application of high-performance computer microprocessor technology, the application industries, application occasions and application environments of automatic detection equipment and a guarantee system are rapidly expanded to the fields with application requirements meeting diversification, generalization, modularization, motorization, combinatization and reconfigurability, such as measurement and control equipment, emission and control equipment, maintenance and guarantee equipment and the like in emergency field monitoring equipment, rescue communication guarantee equipment, field temporary measurement and control equipment and military electronic equipment, and undertake the task mission of rapid development, motorized use and accompanying guarantee.

In the prior art, only the structure platform for bearing and installing the equipment is changed from a cabinet structure to a structure of combining a plurality of portable cases, and the interconnection cable fixedly arranged in the original cabinet needs to be moved outside the combined unit to complete the direct interconnection between the equipment. Therefore, a large number of criss-cross external cables are interconnected among the combined unit chassis, and the interconnected cables are disassembled and assembled once when the combined unit chassis is moved and transferred each time, so that inconvenience is brought to the disassembly and assembly of the system. Particularly, in the transfer process of the equipment, a special cable packing box is required to be configured for external interconnection cables to carry out cable storage and protection management on cable connectors, and the external interconnection cables cannot be lost or damaged, otherwise, a test system cannot work; when the system is re-deployed, a specially trained technician is required to ensure that the system is familiar with the interconnection relationship and is responsible for interconnection identification and prevention of interface misplug accidents; the structural platform mode brings inconvenience to the use of the test system, and the efficiency of the motorized accompanying test is greatly reduced.

Disclosure of Invention

The invention mainly aims to provide a stackable through interconnection combined box and a modular through combined structure platform, and aims to solve the problem that interconnection cables need to be disassembled and assembled when an existing combined unit structure is disassembled and assembled.

In order to achieve the above object, the present invention provides a stackable and penetrative interconnection combiner box, including a main body formed with a receiving cavity for receiving and mounting electrical equipment; the main body is provided with a splicing wall, and when a plurality of stackable through-connected combination boxes are stacked and spliced, any two adjacent stackable through-connected combination boxes are spliced through the splicing wall; the splicing wall is provided with a through interconnection interface for mounting an electrical interconnection device, and when a plurality of stackable through interconnection combination boxes are stacked, spliced and combined, electrical equipment in any two adjacent stackable through interconnection combination boxes can be electrically interconnected through the electrical interconnection device at the through interconnection interface.

Optionally, the main part is along the tubular structure of fore-and-aft direction extension, last lateral wall, lower lateral wall, left side wall and the right side wall of main part are the concatenation wall, just go up the lateral wall, the lateral wall down, the left side wall with link up on the right side wall interconnect interface follows the fore-and-aft axis of main part is the bilateral symmetry and arranges from top to bottom to make adjacent two can pile up the concatenation from top to bottom and link up the concatenation with controlling and link up the concatenation with linking up the combination box.

Optionally, the upper side wall, the left side wall, the lower side wall and the right side wall are sequentially connected to form four connecting positions, and the four connecting positions are all arranged in a chamfer manner; and/or the presence of a gas in the gas,

the upper side wall, the lower side wall, the left side wall and the right side wall are both locally formed in an inward concave mode to form a shell reinforcing rib.

Optionally, the main body comprises a shell assembly, a front frame opening, a rear frame opening, a front end cover assembly and a rear end cover assembly, wherein the shell assembly is of a cylindrical structure extending in the front-rear direction and is in an open state towards the front and the rear; the front frame opening is arranged at the front opening of the shell assembly, and the front end cover assembly is detachably arranged at the front frame opening and is used for covering the front opening of the shell assembly; the rear frame opening is arranged at the rear opening of the shell assembly, and the rear end cover assembly is detachably arranged at the rear frame opening and is used for covering the rear opening of the shell assembly; wherein, link up the interconnection interface and set up in the casing subassembly.

Optionally, one of the upper end surface and the lower end surface of the front frame opening is provided with a front end positioning protrusion, and the other is correspondingly provided with a front end positioning groove for positioning the front end between two stackable through interconnected combination boxes which are stacked and spliced up and down; one of the upper end surface and the lower end surface of the rear frame opening is provided with a rear end positioning bulge, and the other one of the upper end surface and the lower end surface of the rear frame opening is correspondingly provided with a rear end positioning groove for positioning the rear end between the two stackable through interconnected combined boxes which are stacked and spliced up and down.

Optionally, a front-end annular boss is formed on the front frame opening, the front-end annular boss laterally protrudes out of the shell assembly and the front end cover assembly, the front-end annular boss includes four front-end side convex portions which are sequentially connected, a front-end chamfer is arranged between any two front-end side convex portions which are connected, forward front-end positioning holes are arranged at positions close to the front-end chamfer, so that eight front-end positioning holes are formed in the front-end annular boss, and the eight front-end positioning holes are vertically and bilaterally symmetrically arranged along the front-rear axis of the main body; be formed with rear end annular boss on the back frame mouth, rear end annular boss side direction protrusion in casing subassembly with the rear end cover subassembly, rear end annular boss is including four rear end side convex parts that link to each other in proper order, and arbitrary two that link to each other be equipped with the rear end chamfer between the rear end side convex part, and is being close to the position of rear end chamfer all is provided with the rear end locating hole towards the back, in order form eight on the rear end annular boss the rear end locating hole, and eight the rear end locating hole is followed the fore-and-aft axis of main part is bilateral symmetry and arranges from top to bottom.

Optionally, a protective cover is detachably mounted at the through interconnection interface, and the protective cover is used for sealing and covering the through interconnection interface.

The invention also provides a modular through composite structure platform, comprising:

the stackable through-interconnected combination boxes are stacked, spliced and combined, and any two adjacent stackable through-interconnected combination boxes are spliced with each other through splicing walls of the stackable through-interconnected combination boxes;

the combination mechanism is arranged among the plurality of stackable through-connection combination boxes which are randomly and adjacently stacked and spliced and is used for fastening and connecting the plurality of stackable through-connection combination boxes which are randomly and adjacently stacked and spliced in pairs;

the electrical interconnection device comprises a sending end and a receiving end, wherein a through interconnection interface of one of splicing positions of any two adjacent stackable through interconnection combination boxes is arranged at the sending end, and the receiving end connected with the sending end is arranged at the through interconnection interface of the other through interconnection interface so as to realize the electrical interconnection of electrical equipment in any two adjacent stackable through interconnection combination boxes; and the number of the first and second groups,

the supporting mechanism is provided with a preset number of the stackable through interconnection combination boxes and is used for moving and leveling the stackable through interconnection combination boxes and supporting the stackable through interconnection combination boxes.

Optionally, the front end positioning protrusion is located on the lower end surface of the front frame opening, the front end positioning groove is located on the upper end surface of the front frame opening, the rear end positioning protrusion is located on the lower end surface of the rear frame opening, and the rear end positioning groove is located on the upper end surface of the rear frame opening; the front end positioning bulge and the rear end positioning bulge of one of the two stackable communicated interconnected combination boxes which are randomly stacked and spliced up and down are respectively in positioning fit with the front end positioning groove and the rear end positioning groove of one of the stackable communicated combination boxes.

Optionally, gaps extending in the front-back direction are formed between a plurality of stackable through-connection combined boxes spliced in any adjacent stacking manner in a surrounding manner; the combined mechanism comprises a structure interconnection rod, a front end structure interconnection plate and a rear end structure interconnection plate, the structure interconnection rod extends in the front-back direction and is arranged at the gap, the front end and the rear end of the structure interconnection rod both extend out of the gap, the front end structure interconnection plate and the rear end structure interconnection plate are respectively arranged at the front end and the rear end of the structure interconnection rod, and at least one of the front end structure interconnection plate and the rear end structure interconnection plate is detachably arranged with the structure interconnection rod; wherein, the front annular boss and the rear annular boss of the stackable through-interconnection combination boxes which are randomly and adjacently stacked and spliced are respectively abutted against the front structural interconnection plate and the rear structural interconnection plate for splicing and positioning the stackable through-interconnection combination boxes which are randomly and adjacently stacked and spliced in the front-rear direction, the front positioning hole on the front structural interconnection plate, which corresponds to the stackable through-interconnection combination boxes which are randomly and adjacently stacked and spliced, is provided with a front positioning column for splicing and positioning the front ends of the stackable through-interconnection combination boxes which are randomly and adjacently stacked and spliced in the left-right direction and the up-down direction through the positioning matching of the front positioning hole and the front positioning column, and the rear positioning hole on the stackable through-interconnection combination boxes which corresponds to the stackable through-interconnection combination boxes which are randomly and adjacently stacked and spliced on the rear structural interconnection plate is provided with a rear positioning column, the rear end positioning holes are matched with the rear end positioning columns in a positioning mode, and the rear ends of the stackable through interconnected combined boxes which are stacked and spliced randomly and adjacently are spliced and positioned in the left-right direction and the up-down direction.

In the technical scheme provided by the invention, the through interconnection interfaces are arranged on the splicing walls of the stackable through interconnection combination boxes, and when a plurality of stackable through interconnection combination boxes are stacked, spliced and combined, the electrical interconnection device is arranged at the through interconnection interfaces, so that the electrical interconnection of electrical equipment in the stackable through interconnection combination boxes can be realized, the rapid and efficient electrical interconnection can be still ensured under the condition that any number of stackable through interconnection combination boxes are stacked, spliced and combined, and the equipment interconnection cables in the stackable through interconnection combination boxes are not required to be disassembled.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.

FIG. 1 is a schematic structural view of an embodiment of a stackable pass-through interconnection combiner box of the present invention;

FIG. 2 is a schematic structural view of a portion of FIG. 1;

FIG. 3 is an assembly view of the stackable and interconnectable combiner box of FIG. 1 with a sender end;

FIG. 4 is a schematic structural diagram of FIG. 3 from another perspective;

FIG. 5 is an assembly view of the stackable and interconnectable combiner box of FIG. 1 with a receiving end;

FIG. 6 is a schematic view of the structure of FIG. 5 from another perspective;

FIG. 7 is a schematic structural diagram of an embodiment of a modular pass-through composite structural platform provided in the present invention;

FIG. 8 is a schematic structural view of a portion of FIG. 7;

FIG. 9 is a schematic view of a combination mechanism of FIG. 7;

fig. 10 is a schematic structural view of another combination mechanism in fig. 7.

The reference numbers illustrate: the modular through composite structure platform 100, the stackable through interconnection box 1, the main body 11, the receiving cavity 12, the through interconnection interface 13, the housing assembly 14, the front frame opening 15, the front positioning protrusion 151, the front positioning groove 152, the front annular boss 153, the front side protrusion 154, the front positioning hole 155, the rear frame opening 16, the rear positioning protrusion 161, the rear positioning groove 162, the rear annular boss 163, the rear side protrusion 164, the rear positioning hole 165, the front end cover assembly 17, the rear end cover assembly 18, the protective cover 19, the composite mechanism 2, the structural interconnection rod 21, the front structure interconnection plate 22, the rear structure interconnection plate 23, the front positioning post 24, the rear positioning post 25, the electrical interconnection device 3, the transmitting end 31, the receiving end 32, and the supporting mechanism 4.

The implementation, functional features and advantages of the objects of the present invention will be further explained with reference to the accompanying drawings.

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.

It should be noted that, if directional indications (such as up, down, left, right, front, and back … …) are involved in the embodiment of the present invention, the directional indications are only used to explain the relative positional relationship between the components, the movement situation, and the like in a specific posture (as shown in the drawing), and if the specific posture is changed, the directional indications are changed accordingly.

In addition, if there is a description of "first", "second", etc. in an embodiment of the present invention, the description of "first", "second", etc. is for descriptive purposes only and is not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, the meaning of "and/or" appearing throughout includes three juxtapositions, exemplified by "A and/or B" including either A or B or both A and B. In addition, technical solutions between various embodiments may be combined with each other, but must be realized by a person skilled in the art, and when the technical solutions are contradictory or cannot be realized, such a combination should not be considered to exist, and is not within the protection scope of the present invention.

In most applications, Automatic Test Equipment (ATE) or Automatic Test Systems (ATS) employ a standard equipment rack structure platform to carry the test resources and the installation of related equipment, and the electrical interconnection between the test resources or test equipment is implemented by means of interconnection cables disposed within the rack.

With modern electronic measurement and detection technologies, particularly in the field of measurement and control, under the promotion of the application of high-performance computer microprocessor technology, the application industries, application occasions and application environments of automatic detection equipment and a guarantee system are rapidly expanded to the fields with application requirements meeting diversification, generalization, modularization, motorization, combinatization and reconfigurability, such as measurement and control equipment, emission and control equipment, maintenance and guarantee equipment and the like in emergency field monitoring equipment, rescue communication guarantee equipment, field temporary measurement and control equipment and military electronic equipment, and undertake the task mission of rapid development, motorized use and accompanying guarantee.

In the prior art, only the structure platform for bearing and installing the equipment is changed from a cabinet structure to a structure of combining a plurality of portable cases, and the interconnection cable fixedly arranged in the original cabinet needs to be moved outside the combined unit to complete the direct interconnection between the equipment. Therefore, a large number of criss-cross external cables are interconnected among the combined unit chassis, and the interconnected cables are disassembled and assembled once when the combined unit chassis is moved and transferred each time, so that inconvenience is brought to the disassembly and assembly of the system. Particularly, in the transfer process of the equipment, a special cable packing box is required to be configured for external interconnection cables to carry out cable storage and protection management on cable connectors, and the external interconnection cables cannot be lost or damaged, otherwise, a test system cannot work; when the system is re-deployed, a specially trained technician is required to ensure that the system is familiar with the interconnection relationship and is responsible for interconnection identification and prevention of interface misplug accidents; the structural platform mode brings inconvenience to the use of the test system, and the efficiency of the motorized accompanying test is greatly reduced.

In view of the above, the present invention provides a stackable through interconnection box assembly, and fig. 1 to 6 show an embodiment of the stackable through interconnection box assembly provided by the present invention. The stackable pass-through interconnecting combiner box can be applied to a modular pass-through combiner platform, and fig. 7 to 10 illustrate an embodiment of the modular pass-through combiner platform according to the present invention.

Referring to fig. 7, the platform 100 of the modular through-combination structure includes a predetermined number of stackable through-combination boxes 1, and the stackable through-combination boxes 1 of the predetermined number are stacked, spliced and combined with each other, specifically, referring to fig. 1 to 3, in this embodiment, the stackable through-combination boxes 1 include a main body 11, and the main body 11 is formed with a receiving cavity 12 for receiving and mounting electrical equipment; the main body 11 is provided with a splicing wall, so that when a plurality of stackable through-interconnection combination boxes 1 are spliced and combined, any two adjacent stackable through-interconnection combination boxes 1 are spliced through the splicing wall; the splicing wall is provided with a through interconnection interface 13 for mounting an electrical interconnection device 3, so that when a plurality of stackable through interconnection combining boxes 1 are spliced and combined, electrical equipment in any two adjacent stackable through interconnection combining boxes 1 are electrically interconnected through the electrical interconnection device 3 at the through interconnection interface 13 (see fig. 8).

In the technical scheme provided by the invention, the through interconnection interface 13 is arranged on the splicing wall of the stackable through interconnection combination box 1, when a plurality of stackable through interconnection combination boxes 1 are spliced and combined, the electrical interconnection device 3 is arranged at the through interconnection interface 13, so that the electrical interconnection of electrical equipment in the stackable through interconnection combination boxes 1 can be realized, the rapid and efficient electrical interconnection can be still ensured under the condition that any number of stackable through interconnection combination boxes 1 are spliced and combined, and the equipment interconnection cables in the stackable through interconnection combination boxes 1 do not need to be disassembled.

The stackable through-interconnection combining box 1 can be assembled and combined together in a manner related to the shape of the main body 11, and specifically, referring to fig. 1 and 7, the main body 11 is a tubular structure extending in the front-rear direction, the upper side wall, the lower side wall, the left side wall and the right side wall of the main body 11 are all the assembly walls, and the through-interconnection connectors 13 on the upper side wall, the lower side wall, the left side wall and the right side wall are arranged in a vertically and horizontally symmetrical manner along the front-rear axis of the main body 11, so that the two stackable through-interconnection combining boxes 1 can be assembled and connected vertically and horizontally. The stackable and through interconnection combination box 1 can be used for vertically stacking and splicing and horizontally through splicing, so that the stacking mode of hardware architectures with various different system functions can be conveniently formed, and the stress decomposition of equipment installation loads can be well achieved.

Further, referring to fig. 1 to 3, in the present embodiment, the upper sidewall, the left sidewall, the lower sidewall and the right sidewall are sequentially connected to form four connecting portions, and the four connecting portions are all disposed in a chamfer. For example, the cross-sectional shape of the body 11 resembles a square.

Referring to fig. 1 to 3, in the present embodiment, the upper sidewall, the lower sidewall, the left sidewall and the right sidewall are partially recessed to form a housing stiffener (not shown). The strength of the main body 11 can be increased by the arrangement of the shell reinforcing ribs, so that when the stackable and through-connected combined boxes 1 are stacked and spliced, the stackable and through-connected combined boxes 1 are not easy to deform, and therefore it is ensured that the electrical equipment in the two adjacent stackable and through-connected combined boxes 1 can be electrically interconnected through the electrical interconnection device 3 at the through-connected interface 13.

The stackable through interconnection box 1 may be provided with a plurality of through interconnection ports 13, but when the stackable through interconnection box 1 is assembled, the electrical interconnector 3 may not be mounted on each through interconnection port 13 of the stackable through interconnection box 1, please refer to fig. 1, in this embodiment, a protective cover 19 is detachably mounted on the through interconnection port 13, and the protective cover 19 is used to seal and cover the through interconnection port 13. In an initial state, the protective cover 19 is installed at each through interconnection interface 13 on the stackable through interconnection combination box 1, and in a splicing and assembling process, the electrical interconnection device 3 can be installed after the protective cover 19 at the through interconnection interface 13 of the electrical interconnection device 3 is detached at the through interconnection interface 13 where the electrical interconnection device 3 needs to be installed according to actual requirements, so that the sealing performance of the stackable through interconnection combination box 1 is ensured.

Referring to fig. 1 and 2, in the present embodiment, the main body 11 includes a housing assembly 14, a front frame opening 15, a rear frame opening 16, a front cover assembly 17 and a rear cover assembly 18, the housing assembly 14 is a cylindrical structure extending in the front-rear direction, and is open both forward and rearward; the front frame opening 15 is arranged at the front opening of the shell component 14, and the front end cover component 17 is detachably mounted on the front frame opening 15 and used for covering the front opening of the shell component 14; the rear frame opening 16 is disposed at the rear opening of the housing assembly 14, and the rear end cover assembly 18 is detachably mounted on the rear frame opening 16 and is used for covering the rear opening of the housing assembly 14; wherein the through interconnection interface 13 is disposed on the housing assembly 14.

Referring to fig. 7 and 8, in the present embodiment, the modular through composite structure platform 100 includes a predetermined number of stackable through interconnected combination boxes 1, in addition to the stackable through interconnected combination boxes 1, the modular through composite structure platform 100 further includes a combination mechanism 2, an electrical interconnection device 3 and a support mechanism 4, the predetermined number of stackable through interconnected combination boxes 1 are stacked and spliced with each other, and any two adjacent stackable through interconnected combination boxes 1 are spliced with each other through splicing walls of the two stackable through interconnected combination boxes 1; the combination mechanism 2 is arranged between the plurality of stackable through-connection combination boxes 1 which are randomly and adjacently stacked and spliced and is used for fastening and connecting the plurality of stackable through-connection combination boxes 1 which are randomly and adjacently stacked and spliced in pairs; the electrical interconnection device 3 includes a transmitting end 31 and a receiving end 32 (please refer to fig. 3 to fig. 6), where one through interconnection interface 13 of any two adjacent stackable through interconnection combining boxes 1 is disposed at the transmitting end 31, and the other through interconnection interface 13 is disposed at the receiving end 32 connected to the transmitting end 31, so as to electrically interconnect electrical devices in any two adjacent stackable through interconnection combining boxes 1; the stackable through-interconnection combination boxes 1 in a preset number are arranged on the supporting mechanism 4 and used for moving and leveling and supporting the stackable through-interconnection combination boxes 1 in the preset number. The same stackable through interconnection combination box 1 can realize the composition of hardware architecture stacking modes with different system functions, and can achieve good decomposition of equipment installation load stress.

Referring to fig. 2, 4 and 7, in the present embodiment, one of the upper end surface and the lower end surface of the front frame opening 15 is provided with a front end positioning protrusion 151, and the other is correspondingly provided with a front end positioning groove 152 for positioning the front end between two stackable through interconnected combiner boxes 1 stacked and spliced up and down; one of the upper end surface and the lower end surface of the rear frame opening 16 is provided with a rear end positioning protrusion 161, and the other is correspondingly provided with a rear end positioning groove 162, so as to position the rear end between the two stackable and through interconnected combination boxes 1 stacked and spliced up and down.

Specifically, referring to fig. 2, fig. 4 and fig. 7, in the present embodiment, the front positioning protrusion 151 is located on the lower end surface of the front bezel 15, the front positioning groove 152 is located on the upper end surface of the front bezel 15, the rear positioning protrusion 161 is located on the lower end surface of the rear bezel 16, and the rear positioning groove 162 is located on the upper end surface of the rear bezel 16; the front end positioning protrusion 151 and the rear end positioning protrusion 161 of one of the two stackable and through interconnected combination boxes 1 stacked and spliced up and down are respectively in positioning fit with the front end positioning groove 152 and the rear end positioning groove 162 of one of the stackable and through interconnected combination boxes 1. Through the positioning action of the front end positioning protrusion 151 and the front end positioning groove 152 and the positioning action of the rear end positioning protrusion 161 and the rear end positioning groove 162, the initial positioning between two stackable through interconnection combination boxes 1 which are stacked and spliced up and down can be realized, and the alignment of the electrical interconnection devices 3 on the stackable through interconnection combination boxes 1 which are stacked and spliced up and down is facilitated, so that the connection of the electrical interconnection devices 3 on the two stackable through interconnection combination boxes 1 is facilitated.

Specifically, referring to fig. 2 and 4, in the present embodiment, a front end annular boss 153 is formed on the front bezel 15, the front end annular boss 153 protrudes laterally from the housing component 14 and the front end cover component 17, the front end annular boss 153 includes four front end side protrusions 154 connected in sequence, a front end chamfer is arranged between any two front end side protrusions 154 connected in sequence, and a front end positioning hole 155 facing forward is arranged at a position close to the front end chamfer, so as to form eight front end positioning holes 155 on the front end annular boss 153, and the eight front end positioning holes 155 are arranged in a vertically and horizontally symmetrical manner along a front-rear axis of the main body 11; be formed with rear end annular boss 163 on the back bezel aperture 16, rear end annular boss 163 lateral protrusion in casing subassembly 14 with rear end cover subassembly 18, rear end annular boss 163 is including four rear end side convex parts 164 that link to each other in proper order, and arbitrary two that link to each other be equipped with the rear end chamfer between the rear end side convex part 164, and is being close to the position of rear end chamfer all is provided with towards rear end locating hole 165, in order form eight on the rear end annular boss 163 rear end locating hole 165, and eight rear end locating hole 165 follows the front and back axis of main part 11 is upper and lower bilateral symmetry arranges.

With continuing reference to fig. 7, 9 and 10, in the present embodiment, the stackable through-interconnection box 1 is the stackable through-interconnection box 1 as claimed in claim 6, wherein a plurality of stackable through-interconnection boxes 1 spliced in any adjacent stack are surrounded by a gap extending in the front-back direction (not shown in the drawings, the gap is formed between two or four stackable through-interconnection boxes 1 spliced in any adjacent stack by the arrangement of the front end chamfer on the front frame opening 15 and the rear end chamfer on the rear frame opening 16); the combined mechanism 2 comprises a structure interconnection rod 21, a front end structure interconnection plate 22 and a rear end structure interconnection plate 23, the structure interconnection rod 21 extends in the front-rear direction and is arranged at the gap, the front end and the rear end of the structure interconnection rod 21 both extend out of the gap, the front end structure interconnection plate 22 and the rear end structure interconnection plate 23 are respectively arranged at the front end and the rear end of the structure interconnection rod 21, and at least one of the front end structure interconnection plate and the rear end structure interconnection plate is detachably arranged with the structure interconnection rod 21; wherein, the front annular boss 153 and the rear annular boss 163 of any adjacent stackable and interconnectable box 1 abut against the front structural interconnection plate 22 and the rear structural interconnection plate 23 respectively, so as to splice and position the stackable and interconnectable boxes 1 in the front-rear direction, the front positioning hole 155 of the stackable and interconnectable box 1 corresponding to any adjacent stackable and interconnectable plate 22 is provided with a front positioning post 24, so as to splice and position the front ends of the stackable and interconnectable boxes 1 corresponding to any adjacent stackable and interconnectable box 1 in the left-right direction and the up-down direction through the positioning fit of the front positioning hole 155 and the front positioning post 24, and the rear positioning hole 165 of the rear structural interconnection plate 23 corresponding to any adjacent stackable and interconnectable box 1 is provided with a rear positioning post 25, the rear end positioning holes 165 are matched with the rear end positioning columns 25 in a positioning manner, so that the rear ends of a plurality of stackable through interconnected combination boxes 1 which are adjacently stacked and spliced are spliced and positioned in the left-right direction and the up-down direction. Through the positioning function of the front-end structure interconnection plate 22 and the rear-end structure interconnection plate 23, the positioning function of the front-end positioning hole 155 and the front-end positioning column 24, and the positioning function of the rear-end positioning hole 165 and the rear-end positioning column 25, a plurality of stackable through interconnection combination boxes 1 which are adjacently stacked and spliced can be accurately spliced and positioned in the vertical, front, rear, left and right directions, so that the plurality of electrical interconnections 3 on the stackable through interconnection combination boxes 1 are aligned with each other, and the plurality of electrical interconnections 3 on the stackable through interconnection combination boxes 1 are connected conveniently.

It should be noted that, the specific number of the stackable through-interconnection combination boxes 1 that are adjacently stacked and spliced is different, which causes the shape of the combination mechanism 2 disposed between the stackable through-interconnection combination boxes 1 to be different, for example, please refer to fig. 7 and 10, the combination mechanism 2 that is located at the leftmost, rightmost, uppermost or lowermost is disposed between two stackable through-interconnection combination boxes 1 that are adjacently stacked and spliced, the front-end interconnection plate 22 of the combination mechanism 2 is T-shaped, four front-end positioning pillars 24 are disposed on the front-end interconnection plate 22 of the T-shape, the rear-end interconnection plate 23 of the combination mechanism 2 is also T-shaped, and four rear-end positioning pillars 25 are disposed on the rear-end interconnection plate 23 of the T-shape; for another example, referring to fig. 7 and 10, the middle combination mechanism 2 is disposed between four stackable through interconnection combination boxes 1 stacked and spliced adjacently, and the front end interconnection plate 22 of the combination mechanism 2 is cross-shaped, eight front end positioning pillars 24 are disposed on the cross-shaped front end interconnection plate 22, the rear end interconnection plate 23 of the combination mechanism 2 is also cross-shaped, and eight rear end positioning pillars 25 are disposed on the cross-shaped rear end interconnection plate 23.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the scope of the present invention, and all modifications and equivalents of the present invention, which are made by the contents of the present specification and the accompanying drawings, or directly/indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (10)

1. A stackable through interconnection combination box is characterized by comprising a main body, wherein the main body is provided with a containing cavity for containing and installing electrical equipment; the main body is provided with a splicing wall, and when a plurality of stackable through-connected combination boxes are spliced and combined, any two adjacent stackable through-connected combination boxes are spliced through the splicing wall; the splicing wall is provided with a through interconnection interface for mounting an electrical interconnection device, and when a plurality of stackable through interconnection combination boxes are spliced and combined, electrical equipment in any two adjacent stackable through interconnection combination boxes can realize electrical through interconnection through the electrical interconnection device at the through interconnection interface.

2. The stackable inter-connect combiner box of claim 1, wherein the body has a tubular structure extending in a front-to-rear direction, the upper, lower, left, and right sidewalls of the body are all the splicing walls, and the through-connect interfaces on the upper, lower, left, and right sidewalls are arranged in a vertically and laterally symmetrical manner along a front-to-rear axis of the body, so that two adjacent stackable inter-connect combiner boxes can be stacked and spliced vertically and spliced laterally.

3. The stackable pass-through interconnecting combiner box of claim 2, wherein the upper sidewall, the left sidewall, the lower sidewall, and the right sidewall are connected in sequence to form four junctions, each of the four junctions being chamfered; and/or the presence of a gas in the gas,

the upper side wall, the lower side wall, the left side wall and the right side wall are both locally formed in an inward concave mode to form a shell reinforcing rib.

4. The stackable pass-through interconnecting combiner box of claim 2, wherein the body comprises a shell assembly, a front frame opening, a rear frame opening, a front end cap assembly, and a rear end cap assembly, the shell assembly having a tubular configuration extending in a front-to-rear direction and being open both forward and rearward; the front frame opening is arranged at the front opening of the shell assembly, and the front end cover assembly is detachably arranged at the front frame opening and is used for covering the front opening of the shell assembly; the rear frame opening is arranged at the rear opening of the shell assembly, and the rear end cover assembly is detachably arranged at the rear frame opening and is used for covering the rear opening of the shell assembly; wherein, link up the interconnection interface and set up in the casing subassembly.

5. The stackable pass-through interconnection box of claim 4, wherein one of the upper and lower end surfaces of the front bezel has a front positioning protrusion, and the other has a front positioning groove for positioning the front end of two stackable pass-through interconnection boxes stacked and spliced up and down; one of the upper end surface and the lower end surface of the rear frame opening is provided with a rear end positioning bulge, and the other one of the upper end surface and the lower end surface of the rear frame opening is correspondingly provided with a rear end positioning groove for positioning the rear end between the two stackable through interconnected combined boxes which are stacked and spliced up and down.

6. The stackable pass-through interconnecting combiner box of claim 4, wherein the front bezel has a front annular boss formed thereon, the front annular boss protruding laterally from the housing assembly and the front cover assembly, the front annular boss including four front side projections connected in series, a front chamfer being provided between any two front side projections connected in series, and a front positioning hole facing forward being provided at a position close to the front chamfer, so as to form eight front positioning holes on the front annular boss, and the eight front positioning holes being arranged vertically and laterally symmetrically along the front-rear axis of the main body; be formed with rear end annular boss on the back frame mouth, rear end annular boss side direction protrusion in casing subassembly with the rear end cover subassembly, rear end annular boss is including four rear end side convex parts that link to each other in proper order, and arbitrary two that link to each other be equipped with the rear end chamfer between the rear end side convex part, and is being close to the position of rear end chamfer all is provided with the rear end locating hole towards the back, in order form eight on the rear end annular boss the rear end locating hole, and eight the rear end locating hole is followed the fore-and-aft axis of main part is bilateral symmetry and arranges from top to bottom.

7. The stackable pass-through interconnection organizer of claim 1, wherein said pass-through interconnection interface is removably mountable with a protective cover for sealingly covering said pass-through interconnection interface.

8. A modular pass-through composite structural platform, comprising:

the stackable through-interconnection combination box comprises a preset number of stackable through-interconnection combination boxes, the stackable through-interconnection combination boxes are as claimed in any one of claims 1 to 7, the stackable through-interconnection combination boxes in the preset number are mutually stacked and spliced, and any two adjacent stackable through-interconnection combination boxes are mutually spliced through splicing walls of the two stackable through-interconnection combination boxes;

the combination mechanism is arranged among the plurality of stackable through-connection combination boxes which are randomly and adjacently stacked and spliced and is used for fastening and connecting the plurality of stackable through-connection combination boxes which are randomly and adjacently stacked and spliced in pairs;

the electrical interconnection device comprises a sending end and a receiving end, wherein a through interconnection interface of one of splicing positions of any two adjacent stackable through interconnection combination boxes is arranged at the sending end, and the receiving end connected with the sending end is arranged at the through interconnection interface of the other through interconnection interface so as to realize the electrical interconnection of electrical equipment in any two adjacent stackable through interconnection combination boxes; and the number of the first and second groups,

the supporting mechanism is provided with a preset number of the stackable through interconnection combination boxes and is used for moving and leveling the stackable through interconnection combination boxes and supporting the stackable through interconnection combination boxes.

9. The modular feedthrough assembly platform of claim 8, wherein the stackable feedthrough assembly box is the stackable feedthrough assembly box of claim 5, the front positioning protrusion is located on a lower end surface of the front bezel, the front positioning slot is located on an upper end surface of the front bezel, the rear positioning protrusion is located on a lower end surface of the rear bezel, and the rear positioning slot is located on an upper end surface of the rear bezel; the front end positioning bulge and the rear end positioning bulge of one of the two stackable communicated interconnected combination boxes which are randomly stacked and spliced up and down are respectively in positioning fit with the front end positioning groove and the rear end positioning groove of one of the stackable communicated combination boxes.

10. The modular feedthrough assembly platform of claim 8, wherein the stackable feedthrough assembly box is the stackable feedthrough assembly box of claim 6, wherein a plurality of stackable feedthrough assembly boxes of any adjacent stacked assembly form a gap extending in a fore-aft direction; the combined mechanism comprises a structure interconnection rod, a front end structure interconnection plate and a rear end structure interconnection plate, the structure interconnection rod extends in the front-back direction and is arranged at the gap, the front end and the rear end of the structure interconnection rod both extend out of the gap, the front end structure interconnection plate and the rear end structure interconnection plate are respectively arranged at the front end and the rear end of the structure interconnection rod, and at least one of the front end structure interconnection plate and the rear end structure interconnection plate is detachably arranged with the structure interconnection rod; wherein, the front annular boss and the rear annular boss of the stackable through-interconnection combination boxes which are randomly and adjacently stacked and spliced are respectively abutted against the front structural interconnection plate and the rear structural interconnection plate for splicing and positioning the stackable through-interconnection combination boxes which are randomly and adjacently stacked and spliced in the front-rear direction, the front positioning hole on the front structural interconnection plate, which corresponds to the stackable through-interconnection combination boxes which are randomly and adjacently stacked and spliced, is provided with a front positioning column for splicing and positioning the front ends of the stackable through-interconnection combination boxes which are randomly and adjacently stacked and spliced in the left-right direction and the up-down direction through the positioning matching of the front positioning hole and the front positioning column, and the rear positioning hole on the stackable through-interconnection combination boxes which corresponds to the stackable through-interconnection combination boxes which are randomly and adjacently stacked and spliced on the rear structural interconnection plate is provided with a rear positioning column, the rear end positioning holes are matched with the rear end positioning columns in a positioning mode, and the rear ends of the stackable through interconnected combined boxes which are randomly and adjacently stacked and spliced are stacked, spliced and positioned in the left-right direction and the up-down direction.

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