RU2019927C1 - Instrument cabinet - Google Patents

Abstract

FIELD: placement of electronic modules. SUBSTANCE: cabinet has an unfolding housing, the side panels and rear panel have a cable-and-hinge joint, the rear panel and cover are hinge-jointed, and the base is attached to the side and rear channels by detachable fasteners. The internal switching module is made in the form of a frame, with switch cards installed on it. Coupling cells are secured on the side panels. Unit frameworks are secured in the instrument cabinet, and the standard replacement components - in the unit frameworks. The cabinet has two levels of vibration protection: external and internal. The external level is made up of beds and a shock- protection set consisting of shock absorbers and replaceable strainable members. The internal level uses a three-layer construction of side and rear panels, vibro-insulating combination attachment fittings are built in the side panels. The cabinet also uses replaceable cooling modules, flexible heat extractors for standard replacement components. EFFECT: improved design. 3 cl, 24 dwg

Description

 The invention relates to electronics and can be used in the development of electronic equipment (CEA) for the placement of typical replacement elements (TEZs): cells of electronic modules, subunits, blocks; for products of large systems consisting of sections of racks.

 Known instrument cabinet containing a housing and placed in it horizontal partitions with rails in which a TEZ, a switching unit are installed. The cabinet consists of three sections, the upper and lower are removable; the switching unit is made on an m-casement frame, on the leaves of which flexible-rigid multilayer commutation boards are placed. An air duct with a metering device is located in the lower section, and also in the upper section.

 The aim of the invention is to improve the volumetric and mass characteristics of REA by reducing the dimensions and mass of REA without reducing the functional capacity, increasing manufacturability (creating opportunities for fully automated production cycles of assembly and installation, tuning, control and measuring operations), reducing the complexity and cost of manufacturing REA , reducing material consumption, increasing the level of intraspecific and interspecific unification, improving operational characteristics (reliability due to increased resistance to influencing mechanical factors and improving heat dissipation from ERI, maintainability, interchangeability at various levels of the structural hierarchy of REA products).

This goal is achieved by the fact that the instrument cabinet has a bookcase housing consisting of four articulated panels, of which three vertical panels are made of three-layer (with reinforcing filler), and combined mounting units (KUK) are built into two side panels; on the central panel, the frame of the cabinet internal switching module (MVKSH) is installed; vibration isolation bushings are installed on the MVKSH frame (except for multilayer printed circuit boards of MPPK switching), in addition, pipelines of a coolant carrier (for example, water, freon, etc.) are built into the three named panels among the reinforcing filler; on the fourth, horizontal (upper) panel, there are external communication connectors that, through standardized cables, are electrically connected to MPPK MVKSH; the side panels of the cabinet are connected to the central panel by means of hinges and metal or metal-clavular passing through them, etc. cables, which are fixed in the lower elements of the cabinet mounting (made as ball bearings) at the objects of operation; the side panels are interconnected by hard jumpers fixed parallel to the cabinet base and its rear wall in the CAM with easily removable lock washers (or cotter pins);
plug-in blocks (block frames) in front along the lower plane are fixed with two captive screws to the CAM, in the upper part the side walls of the plug-in blocks are fixed with the lower guides of the square of the upstream attachment points (CUC), on the top of the back wall, the plug-in blocks are fixed using vibration damping material; replaceable plug-in modules of an autonomous or forced cooling, ventilation and air flow dosing system located in the upper and lower compartment of the cabinet, similar to plug-in units, in the dashboard; on the inner surfaces of the side panels of the cabinet in the area between the KUK there are pivotally connected connecting cells in which the connectors are fixed with flexible cables (loops) soldered to them, providing electrical connection between the MVKSh and the switching modules of the plug-in units (devices), in the plane of the lower base the cabinet is installed on the CEA protection device, placed in the cabinet, from shock, and the shock protection device contains interchangeable deformable elements.

 In the plane of the rear wall, the instrument cabinet is fixed in vibration and shock-protective lodges attached, in turn, to the object of operation.

 Figure 1 and 2 shows the proposed cabinet, General view; figure 3 - door; figure 4 and 5 - cabinet, section; figure 6 is a view along arrow a in figure 4; Fig.7 is a section bB in Fig.4; on Fig - section bb in Fig.6; in Fig.9 is a view along arrow G in Fig.8; Fig.9-13 - elements of the cabinet; on Fig - section DD in Fig; on Fig - section EE in Fig.13; in Fig.16-18 - block frame; in FIG. 19 - section FJ in Fig.17; in Fig.20 is a section ZZ in Fig.19; on Fig - panel; on Fig.24-24 is a diagram of the heat removal from the equipment.

 The instrument cabinet 1 consists of a housing 2, module 3 of the internal switching cabinet (MVKSH), block frame 6, replaceable cooling modules 7 and 8, in this case, the upper and lower ducts, with a metering device, external vibration protection devices, lodges 9 and kit 10, with a removable deformable energy-absorbing element (SDE) 11.

 The housing 2 contains a left panel 12, a right panel 13, a rear panel 14, a top panel 16, ties 15, split washers 49, a base 17, a cable 18, two decorative squares 21.

 The panels 12-14 are made of three layers and contain carrier layers 19, reinforcing filler 20, squares 22, rigidly fixed to the panel 14, bushings 23 on the rear panel, pipes 24, closing panels 12-14 around the perimeter, inserts (loops) 25 and 26, pipelines 27 and 28 for the refrigerant, combined fasteners (KUK) 29.

 CUCs contain a clip 30, a mortgage 31, guides 32, heats 33, straps 34, vibration-absorbing material 35, for example, metal rubber, polyurethane.

 MVKSh contains frame 3, multilayer printed circuit boards 36 switching (MPPC) inter-unit (inter-instrument) connections, output multilayer printed circuit boards 37 with connectors (VMPPR), printed loops 38, which can be an integral part of MPPC, when manufactured using flexible-hard MPP technology, unified ribbon cables 39, damping bushings 40, damping stops 41, left 4 and right 5 connecting cells.

 The block frame 6 contains a base 42 and 43, partitions 44, catchers 45, captive screws 46, guides 47, wall 48, split washers 49.

 The lodgements contain a metal plate 50, threaded bushings 51 (flared in the plate 50), a damping element 52, for example, a lodgement of rubber, metal rubber, polyurethane).

 The shockproof kit contains an adapter plate 53, squares 54, shock absorbers (purchased) 55, guides 56, SDE 11.

 The instrument cabinet operates as follows.

 The panels 12-14 are interconnected by means of hinges 26 and 25 and cables 18, and the panel 16 is also hinged to the panel 14. In this case, all the panels are deployed (open), according to the image in FIG. 24. Preliminarily, in panels 12 and 13, KUK 29, pipelines 27 and 28 with input and output fittings 72 and 73 are mounted. On panel 14, bushings 23 and elbows 22 are installed, and on panel 16 there are connectors 74 for connecting external communication cables 63.

 On the sleeve 23 using screws 58 install the frame MVKSH.

 Preliminarily, MPPK 36 is mounted on the MVKSH frame, interconnected by means of flexible printed cables 64, and loops 38 of connecting cells 4 and 5. MPPKs are installed on the MVKSh frame in accordance with the permissible location I.

 On panels 12 and 13, frames 66 and 67 of connecting cells 5 and 4, respectively, are mounted on easily removable hinges 65. Preliminarily, on the frames of 66 and 67, a connector is installed for communication with the output connector 68, of the instrument level switching board 69 installed in the block frame. In addition, the framework has installed transitional printed circuit boards 71.

 Solder the loops 38 from MVKSH on the boards 71 and fix them on the side panels with easily removable clamps 57.

 The side panels 12 and 13 are brought into operational position, the cables are pulled using the device 59, the squares 22 on the panel 16 are connected to the panels 12 and 13. The base 17 and the ties 15 are mounted, the door 61 is hung.

 Connect the unified ribbon cables 39 connectors 74 of the cables 63 of the external connections and the output connectors MVKSH on the MPPR 37 board.

 Check the quality of installation by connecting the KIA to the connectors of the connecting cells and the connectors of the cables of external connections.

 On guides KUK, cooling modules 7 and 8, block frames (plug-in blocks) are inserted into the instrument cabinet. The cooling modules and block frames in the instrument cabinet are fixed with captive screws 46. In addition, the cooling modules and block frames in the operational position are fixed by catchers 45 in the bushings 40, stops 41, angles 31 of the upstream HFM.

 The connecting cells 4 and 5 are brought into operational position - they are articulated with the output connectors 68 of the instrument-level switching boards 69 located in block frames.

 Typical replacement elements 60 — electronic modules, sub-blocks, blocks — are inserted into the block frame 6 along the guides 47 and secured by means of the group fastening device 62.

 At the operation site, a shock-proof kit 10, lodges 9, elements of the cooling system (forced-air and exhaust ventilation, or liquid cooling pipelines), an instrument cabinet, a cable system are mounted.

 If necessary, instrument cabinets can be connected in sections of three to four cabinets.

 The design of the instrument cabinet described above has a high level of intrinsic resonant frequency of 100 Hz, and the entire range of shock-and-shock protection devices allows providing the most favorable operating conditions for the EIS included in the equipment in the entire range of mechanical effects of mobile and stationary objects of operation.

 The above design provides the ability to effectively use all kinds of autonomous and group (centralized) object cooling systems and their various combinations and combinations.

 The absence of the need for access to the instrument cabinets from the back wall during operation, the availability of effective heat sinks to the instrument cabinet from the block frames and, accordingly, from the TEZ, the presence of pipelines and replaceable cooling modules built into the side panels, allow creating new effective schemes for heat removal from the equipment, use for this purpose almost completely the surface area of the side panels and the back wall of the instrument cabinet.

 The design of the instrument cabinet allows during operation not only to quickly replace and repair TEZ due to group mounting, to replace plug-in units, replace and repair MVKSH due to the minimum allowable number of screws and connecting cells, but also to modernize the equipment as a whole without dismantling the enclosures of the instrument cabinets, and if it is permissible without disconnecting the cables of external connections. To do this, it is enough to remove the replaceable cooling modules, disconnect the connecting cells and remove the block frames with their contents, disconnect the unified ribbon cables 39 from the 37 MVKSh boards, loosen the screws and, having released the connecting cells, remove the MVKSh frame, install the MVKSh frame and connecting cells of the new equipment, connect the cables 39 to the board 37 of the new MVKSH, install the block frames with the new equipment, connect the connecting cells, install the cooling modules and, if necessary, connect external cables and dig surface mounted decorative cover panel sections 75.

 In addition, the instrument cabinet is versatile both in terms of capabilities within and interspecific unification for the use of CEA, and in terms of numerous options that can be created on the basis of the above-mentioned solutions, depending on the purpose of the equipment, when there may be options for materials as a whole structure of the side and rear panels, and reinforcing filler; both from metals and from composites; both with the use of the external level of vibration protection, and without it; the same applies to all devices of the internal level of vibration isolation, the same applies to the use of the above methods of heat removal; in addition, there may be modifications to the instrument cabinets in terms of the number of places to accommodate both cooling modules and block frames with REA, in addition, these structural solutions and elements can be used in the console and container equipment, which is ensured by sufficient universality of the structural solution of the block frame in which the installation locations of the catchers can be changed, front and rear panels with connectors can be installed on the side walls and in this way the design of the For placement in previously known designs of instrument cabinets with cut-in REA blocks.

Claims (3)

 1. INSTRUMENT CABINET, comprising a housing made in the form of a base, a cover, and side and rear panels connected to them, housed in an internal switching module of a cabinet with connecting cells, block frames with typical replacement elements and a device-level switching plamamia, forced air cooling elements and vibration protection devices, characterized in that, in order to increase manufacturability, ease of use, reduce material consumption, the cabinet body is deployable, and the side the top and rear panels have a hinge-joint connection, the rear panel and the cover are hinged, and the base is attached to the side and back panels with detachable fasteners, and on the back and side panels there are bushes and elbows for fixing the internal switching module of the instrument cabinet, on the cover are placed connectors for connecting external communication cables, while the internal switching module of the cabinet is made in the form of a frame with patch boards installed on it, and is rigidly attached to the bushes of the rear and side panels and to the lid, and the connecting cells are fixed on the side panels, and typical replacement elements are electrically connected via connectors to the instrument-level switching circuit board located in the block frame, the output connectors of which are electrically connected to the switching cabinets of the instrument cabinet via connecting cells and their flexible printed cables respectively, with connectors of cables of external connections, moreover, the block frames are fixed in the dashboard with captive screws, and the connecting cells and typical earth elements group attached using the mounting device subrack.  2. The cabinet according to claim 1, characterized in that, in order to increase resistance to mechanical factors, the vibration protection device is made in two levels: external in the form of lodgements and shock protection set of shock absorbers and replaceable deformable elements, and the internal level, which includes three-layer design of the side and rear panels, and inside the side panels are mounted vibration-proof combined mounts, the hinged cable connection of the side and rear panels is made with the possibility of fixing the cables in It base of the cabinet body by the type of ball joints and adjustable rope tensioning force to the frame internal switching module instrument cabinet mounted vibration insulation sleeves under catcher subrack and antivibration supports.  3. The cabinet according to claim 1, characterized in that its design includes replaceable cooling modules, flexible heat sinks for conductive heat removal from the block frame to the cabinet body and pipelines built into the side and rear panels of the cabinet body that can be connected via mains to the trunk liquid cooling systems.

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