PL73267Y1 - Switchboard with a pressure equalization system providing greater protection against burglary - Google Patents

Abstract

The subject of the solution is a cabinet with a pressure equalization system enabling equalization of the pressure between the surroundings and the space inside the cabinet, increasing the security of the cabinet against burglary attempts using tools, especially distribution cabinets made of plastic, in particular external cabinets intended for installing optical fibers for broadband transmission data, as well as for TV and telephone calls. The cabinet has a pressure equalization system in the form of two gaps (1) created in the wall (3), at the junction of the connection of the roof (2) with the rear wall (3), through the structures of the roof edge elements (2) and the wall (3) of the cabinet, with the roof (2), around the entire circumference, has a profiled trapezoidal groove on the surface of contact with the walls (3, 4), and on the upper surface of the front and rear walls (3) and side walls (4), it has a profiled trapezoidal threshold, thanks to which after assembling the roof (2) and walls (3, 4), a tight, form-fit connection is created at the point of contact, without a gap between the connected elements, and the gaps (1) are located horizontally, along the edge of the upper rear wall (3), in two sections and are created at the junction of the connection of the roof (2) with the walls (3, 4), by a recess in the rear wall (3), creating a rectangular recess (8), the plane of which is located at an acute angle to the surface of the wall (3), and the corresponding two rectangular recesses located on the edge of the roof (2), which, at the connection of the roof (2) with the walls (3 and 4), after their assembly, create walls (3) between the roof (2) and the recess (8), two slots (1), where the recesses of the roof edge (2) are composed of a number of symmetrical, cuboid recesses dividing the recesses into a number of rectangular slots.

Description

Description of the design: The subject of the utility model is a cabinet with a pressure equalization system that allows for pressure equalization between the exterior and interior of the cabinet, thus increasing the cabinet's security against attempted break-ins using tools, particularly for distribution cabinets made of plastic, particularly outdoor cabinets intended for installing fiber optic cables for broadband data transmission, as well as for television and telephone connections. Plastic distribution cabinets are well-known in the market and valued for their low manufacturing costs, high reliability, and the use of predominantly recyclable materials. They are used in the energy, telecommunications, and many other industries. In addition to safety requirements and protection against unauthorized access to cabinet interiors, one of the main requirements for cabinets, especially outdoor cabinets, is environmental requirements (including IP protection ratings), the fulfillment of which guarantees the uninterrupted operation of cabinet components. The telecommunications market, in particular, places high demands in this regard. This is associated with high repair costs for increasingly expensive equipment, lost profits, and the reputation of network operators in the event of system downtime. Cabling technology also impacts environmental requirements – currently used fiber optic and copper cables, despite the implemented protection measures, are not completely resistant to dust and moisture, especially if the outer layers of the cable are damaged. Many plastic cabinet designs made of various materials are available on the market. Polyester cabinets are primarily used for power applications. Due to the sensitivity of data and other factors described above, glass fiber-reinforced polycarbonate is used in the telecommunications industry, which exhibits better mechanical properties. Distribution cabinets are primarily located outdoors, in open spaces, where they are exposed to changing weather conditions such as humidity, precipitation, and temperature fluctuations. Fluctuations in ambient temperature can cause pressure to increase in a tightly closed cabinet relative to atmospheric pressure, which can result in condensation and water vapor condensation. This is undesirable because it can disrupt the operation of the equipment inside the cabinet. To protect the equipment inside the cabinet from water (condensed water vapor), it is necessary to implement an appropriate system to equalize the pressure inside the cabinet to atmospheric pressure. Currently, the market mainly uses solutions in the form of a circumferential gap between the base and the cabinet body, or a gap between the walls and the roof of the cabinet, along a selected section. These solutions, while fulfilling a pressure equalization function, do not provide a high degree of security against manual or tool-based burglary attempts. The essence of the solution proposed in this design is the cabinet's construction as a cuboid and its structural elements, which together form a pressure equalization system between the exterior and the interior of the cabinet. This system protects the cabinet interior from moisture in the form of condensed water vapor, and protects the cabinet interior from acts of vandalism, particularly burglary attempts involving the use of tools to pry open cabinet components. The cabinet pressure equalization system, according to the formula, has the form of two gaps 1, created in wall 3, at the junction of roof 2 with rear wall 3, through the construction of the edge elements of roof 2 and cabinet wall 3. Roof 2, along its entire circumference, has a profiled trapezoidal groove 5 on the contact surface with walls 3, 4, while on the upper surface of front and rear walls 3, and side walls 4, it has a profiled trapezoidal threshold 6, thanks to which, after assembling roof 2 and walls 3, 4, a tight, form-fit connection is created at the contact point, without a gap between the connected elements. The slots 1 are situated horizontally, along the upper edge of the rear wall 3, in two sections and are formed at the junction of the roof 2 with the walls 3, 4, by means of a recess in the rear wall 3, forming a rectangular recess 8, the plane of which is situated at an acute angle to the surface of the wall 3, and the corresponding two rectangular recesses 7, situated on the edge of the roof 2, which, at the junction of the roof 2 with the walls 3 and 4, after their assembly, form two slots 1 between the roof 2 and the recess 8 of the wall 3. The recesses 7, on the edge of the roof 2, are composed of a series of symmetrical, cuboidal recesses 9, dividing the recesses 7 into a series of rectangular slots. The division of the recesses 7 into a series of rectangular slots is intended to reduce the surface area of the slots, to eliminate the continuity of the slots and thus protect against inserting tools into the slots during a burglary attempt. After placing the roof 2 on the edges of the cabinet walls 3 and 4, a tight connection of the elements forming the cabinet structure is achieved, with the exception of the slots 1 in the rear wall 3, which are composed of a series of smaller rectangular recesses 9. Both the width of the slots 1 and the spacing and size of the recesses 9 are selected based on the size of the tools verifying the resistance of the cabinets to burglary attempts using tools. During cabinet assembly, roof 2 is placed on walls 3 and 4 of the cabinet. Between roof 2 and walls 3 and 4, there is a tight, form-fitting connection of structural elements, such as the trapezoidal groove 5 in roof 2 and the trapezoidal threshold 6 in walls 3 and 4. As a result of the structure of roof 2 with recesses 7 and the structure of wall 3 with recess 8, gaps 1 are created between the connected elements, ensuring free air flow, resulting in pressure equalization between the interior of the cabinet and the exterior. The shape of recesses 7 and 8 ensures a reduced area and continuity of the gap, and a labyrinthine seal of the cabinet, preventing water from entering the interior of the cabinet, including water from precipitation. The width of slots 1 and the spacing of recesses 9 prevent access to the cabinet interior during tool-based break-in attempts, increasing security and protecting the cabinet's contents. The arrangement and shape of recesses 7 and 8 means that slots 1 are visible only from the bottom of the cabinet, making them less visible to potential burglars, thereby limiting the number and effectiveness of tool-based break-in attempts. The solution is presented in more detail in the attached drawings, in which: Fig. 1–3 shows roof 2 in a perspective view, Fig. 4–6 shows wall 3 in a perspective view, Fig. 7–10 shows the connection of roof 2 and walls 3, 4 – exploded view, Fig. 11–13 shows the connection of roof 2 and walls 3, 4 – cross-section at the location of the shape connection, Fig. 14–16 shows the connection of roof 2 and walls 3, 4, cross-section at the location of the gap 1, Fig. 17–18 shows the gap between roof 2 and back wall 3 or side wall 4 in a perspective view. PL PL PL PL PL PL PL PL PL PL PL PL PL PL PL PL PL PL PL PL PL