Improvements introduced in rack door

Abstract

A rack door of a rack usable to store telecommunication equipment is provided. The rack door of the rack includes either a front door or a rear door of the rack and is equipped with at least two shutters of transparent injected polycarbonate with a front lens and an opening of 88% for air inlet or outlet. The rack includes an internal temperature indicator having an RGB LED ribbon configured to indicate, by changing colors, the temperature. Each shutter is attachable to at least one other shutter by a lower fitting and a top fitting, each shutter comprising a protective grid on a rear flat portion thereof, and side baffles to receive projection of light from the RGB LED ribbon.

Claims

1. A rack door of a rack (R) usable to store telecommunication equipment, the rack (R) comprising: either a front door (1) or a rear door (1); an electronic circuit that detects an internal temperature inside of the rack (R); the door (1) comprising: a plurality of extruded aluminum profiles, the profiles including a compartment for a RGB LED ribbon (L); at least two shutters (2) comprising at least a first shutter and a second shutter, the first shutter mounted above the second shutter; each shutter (2) made of a transparent injected polycarbonate, and each shutter (2) comprising: a front lens (5); side baffles (A); a protective grid (4) opposite the front lens (5); and an opening (3) for air inlet or outlet; wherein each shutter (2) has a lower fitting (2a) and an upper fitting (2b), wherein a first shutter lower fitting complementarily engages a second shutter upper fitting, the second shutter upper fitting complementarily engages the first shutter lower fitting; wherein the side baffles (A) receive light projected from the RGB LED ribbon (L), the light changing colors to indicate the rack internal temperature.

Description

BRIEF DESCRIPTION OF THE FIGURES

(1) FIGS. 1A and 1B show the rack door (1) according to the present invention patent, where in FIG. 1B is possible to check detail (A) of its assembly.

(2) FIG. 1C shows the rack (R) in side view with a front door with the shutters (2) face down to direct cold air circulation (3).

(3) FIG. 1D shows the rack (R) in side view, each one with rear door with the shutters (2) in reverse positions, i.e. facing up to direct the hot air circulation (3).

(4) FIG. 2 shows the lower view of the shutter (2) used for forming the rack door (1).

(5) FIG. 3 shows a rear view of the shutter (2), where details (B), (C) and (0) can be verified.

(6) FIG. 4 shows a top view of the shutter (2), where the detail (A) is verified.

(7) FIG. 5 shows a front perspective view of the shutter (2).

DETAILED DESCRIPTION

(8) The present invention patent relates to improvements introduced in rack (R) door (1), particularly for telecommunication, where servers, patch panel and switches are installed requiring large airflow for equipment cooling and status signaling of temperature of the servers installed in the racks.

(9) The improvements according to the present invention patent include shutter (2), which can be made of transparent injected polycarbonate, where the air inlet is directed downwards and has an opening of 88%. This model increases the efficiency and, proportionally, the saving of electric energy and, in turn, the collaboration of the environment preservation.

(10) In particular embodiment, the polycarbonate door is also used as a light diffuser which shall indicate the internal temperature of the rack, i.e. together with the polycarbonate door an RGB LED (L) is associated, which indicates the internal temperature of the rack, modulating from blue to red according to the preset temperature range.

(11) The transparent injected polycarbonate shutters (2), in addition to providing a differentiated aesthetic, also provide a faster assembly of the door (1). This is because the parts are interlocked, allowing the standardization of the parts too.

(12) Accordingly, improvements in rack (R) door (1) according to the present invention patent comprise shutters (2) comprising air inlet or outlet (3), as observed in FIGS. 1C and 1D. The air inlet and outlet are directed by the position of the shutters (2).

(13) The shutter (2) also comprises grid (4) for solid object protection, as can be seen in FIG. 3. This grid (4) is on the inner side of the shutter (2) and guarantees the integrity of the equipment installed inside the rack (2), not allowing tools to fall on the inside of the rack, especially when the targeting of the shutters are facing up (FIG. 1D) as hot air outlet. On the opposite side of the grid (4), the front lens (5) of the shutter is located, as can be seen in FIGS. 2, 3, 4 and 5.

(14) The shutters (2) have lower (2a) and upper (2b) fitting for its assembly one on top of the other, as shown in details (B) and (C) of FIG. 3. The size and number of shutters (2) employed in the construction of each rack can vary according to the need of the equipment.

(15) The shutters (2) also have a baffle (A) for LED (L) type light input shown in RGB ribbon to be attached to the profile (P1) of the door (1), as can be seen in FIG. 1B. The color emitted by the RGB LED (L) ribbon from the internal temperature of the rack (R) is irradiated in the baffle (A) by causing the lens (5) of the surface of the shutter (2) to adopt the aforementioned color, and can be used for signaling.

(16) The polycarbonate shutters (2) provide a better use of the air inflated by the floor, as they are directed towards the air outlet. Moreover, with the opening of 88%, the internal air flow is increased and, as light propagates on the inner surface, through a RGB LED ribbon (L), a light diffuser and internal temperature range indicator of the rack is configured.

(17) Current Data Centers are built to separate hot and cold aisles. The cold aisle is in front of the racks and air is coming from the floor at most of the time. In the hot aisle, the air is exhausted from the top. Thus, when using a shutter system such as the present invention it is possible to direct the direction of the air inlet and outlet in the rack, i.e. if in front of the rack the shutter is installed downwards, it will capture the air that is coming from the floor. On the other hand, if the shutters are installed behind the rack upwards will throw hot air straight into the exhaust ducts, causing this flow of hot air does not invade the corridors of cold air. Studies show that this form of installation provides savings of up to 40% of electric energy.

(18) Thus, the use of shutter (2) directs the airflow to the proper direction in a Data Center environment. Another advantage is that the polycarbonate can be used as light diffuser.

(19) In the invention, the sides shall be fixed in an extruded aluminum profile (P1), with compartment for a RGB LED ribbon (L). With this ribbon (L) is possible to modulate colors and an electronic circuit shall detected the temperature inside the rack, causing the modulation is between blue going through shades of yellow and orange and migrating to red, so that when reaches a critical state it shall blink in red color. The advantage of this system is the easy identification of the rack with temperature problem, as in a Data Center we can have the concentration of up to 2000 racks.

(20) It is to be understood that the above embodiments are merely illustrative and that any modification thereof may occur to a person skilled in the art. Accordingly, the present patent should not be considered limited to the embodiments described in the present.

(21) The man skilled in the art will readily appreciate, through the teachings contained in the text and in the drawings presented, advantages of the invention and propose variations and alternatives equivalent of embodiment without, however, departing from the scope of protection as defined in the attached claim scope.