RU2574608C2 - Noise-reduction housing for electronic equipment - Google Patents

Abstract

FIELD: physics, acoustics.

SUBSTANCE: invention relates to a noise-reduction housing for electronic equipment and a method of making same. The structure interacts with equipment located within for defining the inlet plenum and the output plenum. External air passes through the inlet opening of the housing in the inlet plenum, through equipment in the outlet plenum and comes out of the structure through the outlet opening of the housing. The inlet and/or outlet opening have partition walls. The partition walls consist of an elastic material which forms openings which are linked by a fluid medium with the internal chamber and the space outside the housing. The partition walls are arranged such that they prevent direct visibility from the inside of the structure to the outside or reduce visibility, while keeping ventilation channels between the partition walls open.

EFFECT: reduction of noise while improving heat exchange of the equipment is achieved due to that the noise reduction housing formed inside has a structure which defines an internal chamber, having ventilation openings for inlet and outlet of cooling air.

15 cl, 18 dwg

Description

Cross references to related applications

This application claims priority for provisional application for US patent No. 61/318,440 dated March 29, 2010, entitled "Noise canceling enclosure for electronic equipment and method of its manufacture", the contents of which are fully incorporated into this description by reference.

Technical field

The present invention relates to housings for electronic equipment. In particular, the present invention relates to housings for electronic equipment, configured to ventilate electronic equipment contained in the housing, and reduce noise coming from the housing.

State of the art

The number of electronic equipment available in the office and at home has increased significantly in recent years. For example, using server computers in an office environment is commonplace. In the same way, high-speed Internet access is becoming more accessible, increasing the number of electronic equipment used in the office environment, for example, T1 or T3 communication equipment, ADSL modems or modems for communication over cable networks, Ethernet routers and Wi-Fi access points .

With the increase in speed and power of modern computers and electronic equipment, the amount of “noise” and heat produced by such equipment has increased. This is partly due to the fact that the physical dimensions of various devices are becoming smaller and smaller, which further complicates the cooling of the computer and electronic equipment. This is due to the smaller surface area available for heat transfer. This means that for cooling, the air flow through the body of this equipment must be increased. The amount of noise also increases, since the cooling equipment is more powerful to provide greater performance, and such cooling equipment produces more noise.

Attempts have been made to reduce noise by placing equipment in insulated enclosures. However, this attempt to isolate noise also kept the heat generated by the equipment in an insulated enclosure. The inability to remove the retained heat caused equipment breakdown. To combat this, ventilate modern buildings, trying to ensure that the equipment has sufficient air flow. Enclosure ventilation allows most of the noise generated by computers and electronic equipment to leave the enclosure.

The found solution to the noise problem was to provide a special room for electronic equipment, for example, a special server room. Very often, these rooms are sealed, equipped with a separate air conditioning system to remove the heat generated by the equipment and maintain the temperature for the safe operation of the equipment. Depending on the amount of equipment and the size of the room, premises may also include measures to reduce noise. However, this solution has several disadvantages. Providing a special room for electronic equipment is expensive and often requires the loss of part of the useful office space. In addition, although the noise level can be reduced outside the special equipment room, it can be quite high in the equipment special room itself. This can create an unpleasant and sometimes harmful environment for those who have to work on this electronic equipment or with it.

In addition, for relatively small work sites that do not have a lot of computer equipment, a dedicated server room can be prohibitively expensive. For example, for organizations with minimal needs for server hardware, the use of all-in-one server systems (English “all-in-opera”), such as blade systems (English “blade system”), makes it possible to install a server with such performance that is required at a particular point in time, with the possibility of increasing or decreasing as necessary. Blade systems typically comprise a blade enclosure and one or more blade servers installed therein.

Unlike a regular server, the blade server may not contain typical server components, such as a hard disk, power supply, network connections and / or user interface equipment. Instead, these components reside in a server enclosure and can be shared by any of the blade servers installed in that enclosure. Thus, the capacity and power consumption of the entire system is reduced. This allows multiple servers to be installed in a relatively small enclosure volume (for example, ~ 300 mm high × ~ 500 mm wide × ~ 1000 mm deep), which in turn allows the blade system to be placed in an open office environment.

However, as mentioned above, concentrating multiple server computers in this relatively small enclosure requires sufficient cooling of the blade system hardware. Inside the blade enclosure, fan modules are mounted that blow air through the components of the blade server and typically provide such cooling. Thus, blade systems can produce a significant amount of noise, which can lead to many of the problems outlined above.

Similar noise problems were found in the home environment. With the increase in the number of audio and video equipment in the house, the noise level increased due to the need to cool such equipment. For example, a typical home theater system often contains one or more of the following elements: cable signal converter, satellite video tuner, video cassette recorder (VCR), digital video recorder (DVR), digital video disc player (DVD), audio tuner / amplifier system and / or PC media . Many people find this vast collection of electronic equipment unsightly.

To partially solve this problem, many home theater owners have sought to hide electronic equipment inside cases or furniture. But such owners are faced with similar problems associated with heat and noise, as in offices. Some home theater equipment is cooled by natural convection, rather than by blowing air through the equipment case with cooling fans. When the equipment is placed in a case, heat is retained, which can lead to equipment breakdown or a decrease in its service life.

There is a need for a system and method for providing better heat dissipation and noise reduction for electronic equipment. The present invention overcomes the known problems by providing a new system and method as described in the remainder of this description with reference to the accompanying drawings.

Disclosure of invention

The present invention relates to a noise canceling case for electronic equipment and a method for its manufacture. An embodiment of the present invention comprises a housing for suppressing noise generated within the housing. The housing comprises a housing structure forming an inner chamber, which has ventilation openings for the inlet and outlet of cooling air. The case structure interacts with the electronic equipment located inside to form the inlet plenum and the outlet plenum in the inner chamber. Air from outside the housing structure passes through the inlet in the housing structure into the inlet plenum, through electronic equipment into the exhaust plenum, and exits the housing structure through the outlet. At least one of the inlet and outlet openings comprises a partition structure consisting of a plurality of partitions. The baffles contain an elastic material forming a plurality of openings connected by a fluid to the inner chamber and the space outside the housing structure. The partitions are located so that they prevent direct visibility from the inside of the housing structure to the outside, while keeping the ventilation ducts between the partitions open.

Another aspect of the invention is that each of the partitions comprises an elongated portion of an elastic noise-canceling material having a substantially flat profile at rest and a curved profile while holding it in a deformed state.

Another aspect of the invention is a housing structure comprising a spacer in the inner chamber cooperating with electronic equipment for defining an inlet plenum and an outlet plenum.

Another aspect of the invention is a housing structure comprising an upper wall, a first side wall, a second side wall and a lower wall. At least one of these walls contains a noise reduction material located on it.

An aspect of the invention is a sound-absorbing case, also comprising a cable outlet port, comprising a port structure and a removable cover. The port design is configured to receive a port hole in the housing. The port design includes an open back and top and a removable cover. The removable cover is adapted to be mounted on the port structure to accommodate a variety of cables of various sizes. The noise canceling material is located inside the port structure and on the inner surface of the removable lid so that when the lid is fixed to the port structure, the noise canceling material located on the inner surface of the removable lid is mated with the noise canceling material inside the port structure in order to substantially isolate at least one cable passing through the port structure to the hull structure, so as to prevent the noise produced in the hull structure from escaping through the structure uw port.

Another aspect of the invention is a sound-absorbing housing comprising an intake air chamber defined by a plurality of walls, wherein at least one of said walls comprises a noise canceling material located thereon. The intake air chamber has an intake air inlet and an intake air outlet, the intake air inlet being fluidly connected to a space outside the housing structure, and the intake air outlet is fluidly connected to the air inlet.

Another aspect of the present invention is a sound-absorbing housing comprising an exhaust air chamber defined by a plurality of walls, wherein at least one of said walls comprises a noise canceling material disposed thereon. The exhaust air chamber has an exhaust air inlet and an exhaust air outlet, the exhaust air inlet being fluidly connected to the air outlet, and the exhaust air outlet is fluidly connected to a space outside the housing structure.

A brief description of the graphic materials

The present invention will be described in more detail below with reference to the attached drawings.

These and other aspects of the present invention will be described in further detail in the description, claims and the attached drawings.

FIG. 1 is an exploded perspective view of a housing characterized by features in accordance with an embodiment of the present invention.

FIG. 2 is a front view of a housing characterized by features in accordance with an embodiment of the present invention.

FIG. 3 is a perspective view of a block of exhaust baffles in accordance with an embodiment of the present invention.

4A-C depict a series of perspective views of an intake manifold block with an optional filter device in accordance with an embodiment of the present invention.

FIG. 5 is a cross-sectional perspective view of a main body part in accordance with an embodiment of the present invention.

Fig. 6A is a cross-sectional side view of an intake manifold block in accordance with an embodiment of the present invention.

6B is a cross-sectional side view of a partition in accordance with an embodiment of the present invention.

7 is a cross-sectional side view of a housing in accordance with an embodiment of the present invention.

FIG. 8A is a cross-sectional side view of FIG. 7 with electronic equipment mounted in a housing in accordance with an embodiment of the present invention.

FIG. 8B is a cross-sectional side view of FIG. 7 with electronic equipment mounted in a housing in accordance with an embodiment of the present invention.

FIG. 9 depicts a cable port in an assembly for attachment to a main body portion in accordance with an embodiment of the present invention.

10 depicts a cable port connected to a main body portion, illustrating cable installation in accordance with an embodiment of the present invention.

FIG. 11 depicts the cable port shown in FIG. 10 with a lid installed in accordance with an embodiment of the invention.

12A-B are a rear perspective view of an exhaust baffle block mounted on a main body with an optional exhaust chamber cover that is installed in accordance with an embodiment of the present invention.

13 is a cross-sectional side view of a housing in accordance with an embodiment of the present invention.

The implementation of the invention

The present invention relates to systems and methods for placing electronic equipment in a noise canceling housing that allows air to flow into and out of the housing. One embodiment of the invention does not have a device for moving air, relying heavily on fans present for air exchange in electronic equipment housed in a housing. The housing of the present invention provides air inlet to the housing through the structure of the intake walls and air outlet from the housing through the design of the exhaust walls. The design of the partitions is made of elastic materials that are deformed into a shape that prevents line of sight through the design of the partitions. Elastic materials have noise-canceling properties. Within the scope of the present invention are embodiments that may have an intake air chamber into which cooling air enters before entering through the structure of the intake baffles and into the housing. Similarly, in some designs, an exhaust air chamber is provided, which includes air leaving the structure of the exhaust partitions. Optional chambers for intake and exhaust air also help reduce the amount of noise leaving the enclosure. Also within the scope of the present invention are embodiments of the present invention that can use cable outgoing ports allowing cables and wires to pass through the cable outgoing port while blocking noise transmission through this port.

Figure 1, in General terms, 100, shows an embodiment of the present invention. The housing 100 has a main part, usually box-shaped, has four sides, including a left side 102, a right side 104 (not visible), an upper side 106 and a lower side 108 (not visible). The housing 100 may be designed to accommodate various types of electronic equipment. In one design, the internal dimensions of the enclosure 100 are such that the HP BladeSystem c3000 Enclosure system tightly enters the enclosure 100. The housing 100 may be constructed of various materials, such as wood, metal, or medium density fiberboard, coated with wood, plastic, or metal laminate. In an embodiment, portions of the inner surface of the walls of the housing 100 may be coated with materials having sound absorbing or noise suppressing properties. One set of materials suitable for such purposes includes ACOUSTIML ™ multilayer soundproofing material (commercially available from Acoustic Products, LTD, Chesham, U.K.). In particular, for use in embodiments of the present invention, a 3-layer acoustic composite material of 6.9 mm, 12 mm and / or 13 mm from this manufacturer is suitable. This 3-layer material is constructed of a rubbery acoustic screen placed between two layers of acoustic porous material. Due to the placement of a dense acoustic screen between two porous layers, the material has a high value of sound transmission loss and enhanced low-frequency absorption characteristics.

Other examples of materials suitable for such purposes include anti-vibration polymer absorbent materials (for absorbing vibrations) and / or polyurethane foam (such as the commercially available PYROSORB Flame Resistant Acoustic Foam). Polyurethane foam can be either a flat porous material (for example, a porous material with a uniform thickness of 10 mm or 25 mm) or a porous cellular material. Examples of anti-vibration polymer absorbent materials include a 1.8 mm thick flexible chlorinated polyethylene (CPE) TS3 polymer absorbent sheet used in the automotive industry. To increase ease of use, the absorbent sheet may have an adhesive backing. Additional examples include one or a combination of the following: polymeric porous materials, fiberglass, carpet and other anti-vibration sheet materials. Coating parts of the inner walls of the housing 100 with anti-vibration material helps to reduce the amount of noise transmitted to the walls of the housing 100, thereby reducing the amount of noise passing outside the housing 100 through the walls.

Electronic equipment (not shown) may be located in the housing 100 and supported on the lower side 108. The housing 100 has an intake wall structure 110 that is attached to the front of the housing 100, and an exhaust wall structure 112 that is attached to the rear of the housing 100. Design 110 inlet baffles and outlet baffle structure 112 may be detachably connected to the housing 100 so that air will enter the housing 100 through the inlet baffle structure 110 and exit through the baffle structure 112 starting baffles by the operation of cooling fans contained in electronic equipment located in the housing 100. The design of the intake baffles and the design of the exhaust baffles can be connected to the housing 100 by a mechanism comprising a pin and a groove described in more detail below.

The housing 100 can be made with a port 114 for cables, which allows cables to enter the housing without significantly violating the noise-canceling characteristics of the housing. Cable port 114 is described in more detail below. The housing 100 also optionally includes an intake air chamber cover 116 cooperating with an intake wall structure 110 to form an intake air chamber. Similarly, the housing 100 may include an exhaust air chamber cover 118 cooperating with the exhaust partition structure 112 to form an exhaust air chamber. These features are described in more detail below.

FIG. 2 is a front view of a housing 100 with an intake wall structure 110 mounted in a working position. The inlet baffle structure 110 has a plurality of baffles 210 spaced apart from one another. The distance between the baffles 210 forms a plurality of ventilation openings 220. The ventilation openings 220 allow air outside the casing 100 to pass between the baffles 210 into the casing 100. However, although between the baffles 210, there are ventilation 220 air can flow, the baffles 210 are shaped to prevent line of sight through the inlet baffles structure 110. The inlet baffle structure 110 has a four-sided frame structure 230 cooperating with individual baffles 210 to define a special shape for the baffles, as described in more detail below. The inlet baffle structure 110 may be constructed from the same materials as outlined above for the housing 100.

FIG. 3 shows a perspective view of a structure 112 of the exhaust baffles disconnected from the main body of the housing 100. The construction 112 of the exhaust baffles is characterized by features similar to those of the construction 110 of the intake baffles. Namely, the structure 112 of the exhaust baffles also has a plurality of baffles spaced apart from one another with ventilation openings between them. The design 112 of the exhaust baffles has two mounting levers 310 that are adapted to the rear of the main part of the housing 100. Each mounting lever has an upper and lower grooves 320, each of which mates with an additional pin (not shown) inside the main part of the housing 100. Thus, a fixing mechanism comprising a pin and a groove allows for the disconnection and replacement of the structure of 112 exhaust partitions without the use of tools. Optionally, the exhaust baffle structure 112 may be rigidly connected to the housing 100. The intake baffle structure 110 may also be equipped with a locking mechanism to prevent unwanted removal of electronic equipment from the housing 100 or interference with its operation. The design of the inlet partitions 110 has similar features, ensuring its installation on the front of the main part of the housing 100.

4A-C show a series of perspective views of the structure of the inlet baffles 110 with the optional filter device 410 installed. The filter device 410 is inserted into the grooves in the mounting levers 420 and held near the partitions 210. Thus, the filter device 410 is located between the partitions 210 and the interior housing 100. The filter device 410 is constructed of filter material known to specialists in the field of technology, and prevents dirt, dust and other specific contamination and thereby increases the life of the equipment inside. The filter device 410 is easily removable for cleaning or replacing it.

Figure 5 shows a perspective view with a cut of the main part of the housing 100, the structure 110 of the inlet partitions and the structure 112 of the outlet partitions. This figure depicts how these partition designs allow air to enter the housing 100 (indicated by arrow 510) and exit the housing 100 (indicated by arrow 520), while reducing the amount of noise that leaves the housing 100 (indicated by arrows 530).

Fig. 6A is a cross-sectional side view of the inlet baffle structure 110. As mentioned above, the inlet baffle structure 110 has a plurality of spaced apart baffles 210 for creating a plurality of ventilation openings 220. The cross-sectional area of the ventilation openings 220 is selected to provide sufficient air flow through the housing 100 in accordance with the requirements of a particular application. In the described embodiment, 30% of the total cross-sectional area bounded by the inlet baffle frame is open to airflow (indicated as 605). Larger or smaller areas of the open area are also within the scope of the present invention.

Moreover, the shape and location of the partitions 210 impede direct visibility from outside the housing 100 (indicated as 610) into the housing 100 (designated as 620). Particularly, in the embodiment depicted in this figure, the lowermost part 630 of one partition is vertically overlapped with the uppermost part 640 of the other partition. Thus, each path (labeled 650a-c) of noise from inside the enclosure to the outside of the enclosure will include one or more reflections from the partitions 210. Due to the fact that the partitions 210 are constructed of noise-canceling material, a certain amount of sound energy will be absorbed at each reflection. Consequently, any noise leaving the enclosure 100 is reduced. Noise with some paths will not be able to leave the enclosure 100 at all (shown as a noise path of 650 s).

Partitions 210 are constructed of a multilayer elastic material that absorbs some of the sound energy of the noise trying to leave the housing 100. In addition, since the material is resilient, vibrations that could otherwise be generated in or transmitted through the rigid material of the partitions are reduced. In one illustrated example, the partition material is the three-layer ACOUSTIML ™ material described above. In a relaxed state, this sandwich multilayer structure is substantially flat.

In one embodiment, partitions are formed of four strips of a three-layer acoustic composite material, as shown in FIG. 6B, essentially creating a double-thickness layer of a three-layer acoustic composite material. 6B also illustrates a cross-sectional view of said three-layer acoustic composite material. The first layer of acoustic porous material 690a is attached to the dense acoustic screen material 690b, which is then attached to the second layer of acoustic porous material 690 s. The main strip of this composite material 670a is connected to three other bands — the leading edge band 670b, the middle band 670c and the trailing edge band 670d. The gap 680a between the front edge strip 670b and the middle strip 670c and the gap 680b between the middle strip 670c and the rear edge strip 670d provide increased flexibility of the multilayer composite partition, which allows the arranged rectangular stripes to be more easily deformed, as described below. The size of the gaps 680a-b and the number of such gaps may vary depending on the desired shape of the deformed partition. Similarly, gaps 680a-b may be omitted and will remain within the scope of the present invention.

The arranged rectangular stripes of elastic material are deformed into substantially V-shaped partitions by connecting each edge of the long sides of the rectangle with support elements that are separated by a distance less than the length of the short edge of this rectangle. 6A-B illustrate one such embodiment. The supporting elements 660 are connected to opposite edges of the long sides of the rectangular strips of material that form one of the partitions 210 (the supporting element 660 is shown in FIG. 5 in the amount of one only as an illustrative example). Since the distance between the support members 660 is less than the length of the short edge of the rectangular strip of the partition material, the partition material is deformed into the substantially V-shaped partition mentioned above. Support elements 660 may be constructed of metal, plastic, wood, or other suitable materials that can support said elastic material in a desired deformed shape. Supporting elements 660 can be mounted inside circular cutouts 665 in the inner wall of the inlet partition structure 110, which provide support and control the distance between the supporting elements 660. The supporting elements 660 can also be attached to the inlet partition structure frame by gluing, welding, mechanical fasteners and other known ways.

The sides of the V-shaped partitions shown in FIGS. 6A-B are approximately equal in length and are at an angle of approximately 88 degrees to each other (i.e., each support member 660 is at an angle of 44 degrees relative to the horizontal). However, larger or smaller angles may be used, remaining within the scope of the present invention. Additionally, other cross-sectional shapes are contemplated, such as a U-shape, uneven curved shapes, and linear shapes. For example, you can leave the resilient material in its calm state (i.e., essentially flat) and mount it relative to other essentially flat partitions so as to block direct visibility from the inside to the outside.

Fig. 7 shows a cross-sectional side view of the housing 100. As mentioned above, parts of the inner surface of the walls of the housing 100 may be coated with sound absorbing (sound absorbing) material (s). As shown in this figure, the upper side 106 comprises a sound-absorbing material 710 located on it. In this case, the lower side 108 also contains a sound-absorbing material 720 located on its inner surface. The floor portion 730 is located on top of the sound-absorbing material 720 for supporting electronic equipment placed inside the housing 100 The floor portion 730 protects the noise absorption material 720 from damage when installing and / or removing equipment from the housing 100. Although not shown, noise absorption material could located on the left side 102 and the right side 104. The sound absorbing material located on the inner walls of the housing 100 reduces the amount of noise that is absorbed and re-emitted by the walls of the housing. The sound absorbing material used here may be one or a combination of the materials mentioned above. However, it is contemplated that other materials may be used as the noise canceling material to suppress the low-frequency noise generated by the electronics inside the cabinet 100 and to prevent the passage of noise through the cabinet structure.

The sound-absorbing material may also be located on one or more inner surfaces of the walls of the cover 116 of the intake air chamber and cover 118 of the exhaust air chamber. As mentioned above, the intake air chamber cover 116 cooperates with the intake wall structure 110 to form an intake air chamber 740. This camera reduces the amount of noise perceived from the outside of the housing 100 by directing the leaving sound to the sound-absorbing material 750 and then down through the inlet 760 of the intake air chamber to the ground. In this case, the cover 118 of the chamber for exhaust air interacts with the design 112 of the exhaust baffles to form a chamber 770 for exhaust air. The sound absorbing material 780 and the exhaust port 790 of the exhaust air chamber also reduces the amount of noise perceived from the housing 100. FIG. 7 displays a sound absorbing material covering the entire surface of the inner walls of the housing 100. However, an embodiment is also proposed in which the sound absorbing materials cover only part of the walls while providing the required noise absorption effect.

Fig. 8A is a sectional side view of Fig. 7 with electronic equipment 800 installed in the housing 100. As described above, the electronic equipment 800 fits tightly into the housing 100 so that the outer surface of the electronic equipment 800 is in contact with the noise canceling material located on the inner surface of the walls of the housing 100. This arrangement forms an inlet plenum 810 between the structure 110 of the inlet partitions and electronic equipment 800 and an outlet plenum 820 between the equipment and the structure 112 of the outlet partitions . Since the electronic equipment 800 fits tightly inside the housing 100, the inlet plenum 810 and the outlet plenum 820 are substantially isolated from each other. Thus, the air leaving the electronic equipment 800 is led outside the housing 100 through an exhaust assembly (designated entirely as 830), while fresh air (i.e., relatively cooler air) is drawn into the housing through an intake assembly (designated entirely like 840). Thus, the relatively hotter air leaving the electronic equipment does not return to the inlet plenum repeatedly, which helps to cool the equipment.

Due to the tight placement inside the housing 100, the electronic equipment 800 is substantially coated with noise reduction material. As described above, this material is constructed from multiple layers. In the middle of this many layers is a dense material such as an acoustic screen. Such material is limited on each side by an acoustic porous material. Using the described arrangement, the amount of vibration energy generated by the electronic equipment 800, which is transmitted to the walls of the housing 100, is significantly reduced. The laminated material holds the specified equipment firmly in place within the housing 100, however, since there are no rigid connections between the electronic equipment 800 and the walls of the housing 100, it is very small the amount of vibration energy reaches the walls from which the energy will be emitted as noise.

Although the embodiment described above describes electronic equipment that fits tightly into the housing 100, other designs do not require such a tight fit. FIG. 8B illustrates an alternative embodiment of an embodiment designed to accommodate electronic equipment 850 that is smaller than the internal size of the housing 100. One or more can be added to maintain the inlet plenum 810 and outlet plenum 820 that are substantially isolated from each other. internal walls 860. Such internal walls can be constructed of rigid or flexible materials so long that the path along which a significant amount of air passes between the plenum E, passed through the equipment. Additionally, an optional fan 870 (e.g., a fan unit) may be added to assist in removing warm air from the exhaust ventilation chamber 820. However, depending on the specific electronic equipment located in the housing 100, the fans available in the equipment may be sufficient to remove air from the housing 100.

FIG. 9 depicts a cable port 900 assembly for attachment to a main body of a housing 100. Cable port 900 has a cable port housing 910 that connects to a main body of a housing 100 in the vicinity of the outlet structure 112. The cable port 900 also includes a cable port cover 920 that interfaces with the cable port case 910 to form a noise canceling insulation that conducts the cable externally to the case 100. In some embodiments, the cable port 900 communicates with the outlet structure 112 to attach the outlet assembly (830 to figa) to the main part of the housing 100.

To illustrate the installation of the cable, FIG. 10 depicts a cable port 900 attached to the main body of the housing 100 with the cable port cover 920 removed. The cable port 900 can be attached to the bottom side 108 (not visible) of the housing 100 using various methods so that it is fixedly or removably attached. For example, the cable port 900 may be attached to the bottom side 108 of the housing 100 using nuts and bolts, screws, or other fasteners, or by welding, soldering, or gluing.

Cable port 900 typically has a box-shaped structure, including left 1010, right 1020, front 1030 and rear 1040 vertical sides. The cable port has a bottom side 1050 and a cable port baffle 1060. Each of the front vertical side 1030 and the rear vertical side 1040 has an opening that allows the cable to pass (1070 and 1080, respectively). The cable port baffle 1060 is located within the cable port 900 and is wide enough to prevent line of sight between the holes 1070 and 1080. When the cable port cover 920 is removed, the cables 1090 can be passed through the hole 1070 in the front vertical side 1030, bending around the cable port baffle 1060 and through the rear vertical side 1080 without having to pass the cable through any openings. This allows, as an advantage, to place cables 1090 having a large end connector, without first having to remove the connectors and then return them as soon as the cables 1090 are in place. Similarly, cables 1090 can be easily removed from cable port 900 without having to modify the end connectors present on cables 1090.

Any one or more sides of the five sides of the cable port 900 may be constructed from materials similar to those used for the walls of the housing 100 described previously. Similarly, the inner surfaces of the sides of the cable port 900 may be treated or coated with materials having noise reduction properties similar to those mentioned above. In an exemplary embodiment, the inner surface of the lower side 1050 of the cable port 900 is coated with a cellular polyurethane porous material of a thickness of 10 and / or 25 mm. Although not shown, a cellular type polyurethane porous material is also placed on the bottom surface of the cable port lid 920 so that when the lid 920 is fixed in place, the layers of polyurethane dense material on the lid 920 and the lower side 1050 have shapes corresponding to each other. When the layers of dense cellular material are pressed against each other, they form a noise-canceling insulation around cables 1090. Optionally, small vertical slots (not shown) can be made around the cable 1090 in polyurethane porous material to make insulation around cables 1090.

11 depicts a cable port 900 of FIG. 10 with a cable port cover 920 mounted on a cable port housing 910. As shown in the figure, the cables 1090 pass through the cable port to the housing 100, while the noise canceling material located on the inner surfaces of the cable port housing 910 and the cable port cover 920 interacts to reduce the amount of noise leaving the housing 100.

12A-B show a rear perspective view of the exhaust baffle structure 112 mounted on the main body of the housing 100 with the optional exhaust chamber cover 118 installed. The cable port 900 is also illustrated. As shown in the figure, the outlet baffle structure 112 and the cable port 900 cooperate to substantially seal the rear of the main body 100. Moreover, the baffle structure 112 and the cable port 900 are arranged relative to each other so that the structure 112 exhaust baffles can be removed and returned back to the housing 100 without affecting the placement of cables passing through the cable port 900.

13 is a side sectional view of a housing 1300 in accordance with an embodiment of the present invention. The housing 1300 has some features similar to those described above and associated with the housing 100. However, the design of the partitions, the characteristics of the internal air flow and the cable port are different from the housing 100. In particular, the housing 1300 is constructed from the same materials as described above, and contains a cover 1305 of the chamber for intake air, a main part 1310 and a cover 1315 of the chamber for exhaust air. As in the previous embodiment, the electronic equipment 800 fits tightly into the housing so that the outer surface of the electronic equipment 800 is in contact with noise reduction material located on the inner surface of the walls of the housing 1300. An optional filter device 410 can also be installed, as described in more detail above.

The cover 1305 of the intake air chamber is internally coated with noise canceling material 1320 and contains two curved partitions 1325a and 1325b, which are constructed from the ACOUSTIML ™ material described above. Like the other partition structures described above, curved partitions 1325a-b can be constructed from other types of noise canceling material. A curved partition 1325a is attached to a noise canceling material covering the inside of the lid of the chamber 1305 along the lower part of the partition and its upper end. This makes it possible to hold the curved portion 1330a of the partition 1325a, which is loosely fixed inside the intake air chamber. As described above, since the septum material is resilient, vibrations that could otherwise occur in the rigid septum material or be transmitted by it are reduced. In addition, it is believed that the curved shape helps to equalize the air flow in the main body 1310.

A curved partition 1325b is secured to its upper end by means of a support member 1335 functioning in the same manner as the support member 660 described above. The lower part of the curved partition 1325b is attached to the anchor 1340. The anchor 1340 may be a rigid panel overlapping a portion of the intake air chamber and may be made, for example, of medium density fiberboard. The walls of the cover 1305 of the intake air chamber, the noise canceling material covering its inner surface, and the curved partitions 1325a-b define three spaces within the intake chamber. The airspace 1345a is defined by a coating of a noise canceling material and a curved partition 1325a; this airspace provides additional noise reduction measures by reducing the amount of sound energy transmitted to the walls of the lid of the intake air chamber. The air space 1345b is defined by curved partitions 1325a and 1325b and provides alignment of the trajectory of the air flow for the air entering the body 1300, while also allowing any sound energy coming out of the main part 1310 to be reflected from the curved partitions 1325a-b, thereby reducing the level noise caused by this. The air space 1345c is defined by a curved partition 1325b and a filter device 410 (or the wall of the main part 1310 if the filter device 410 is not installed). Airspace 1345 s provides alignment of the path of the air flow for incoming air and noise reduction properties. Additional curved partitions and defined by them air spaces are also within the scope of the present invention.

The cover 1315 of the exhaust chamber is internally coated with a noise canceling material 1350 and also has a curved partition 1355. A curved partition 1355 is attached to the noise canceling material covering the inner surface of the cover 1315 of the exhaust chamber along the entire line of the lower part of the said partition and its upper end. This allows you to hold the curved part 1360 of the partition 1355, which is loosely fixed inside the chamber for exhaust air. As described above, since the septum material is resilient, vibrations that could otherwise occur in the rigid septum material or be transmitted by it are reduced. In addition, it is believed that the curved shape helps to equalize the air flow in the main body 1310, thereby reducing the likelihood of creating air pockets. This further reduces the likelihood of local overheating in the housing.

The cover 1315 of the chamber for exhaust air contains a design 1365 of partitions. Partitions of this structure may be constructed in the same manner as described above with respect to partitions of structure 110. In particular, partitions are constructed of one or more strips of a multilayer acoustic composite material. Also, by means of supporting elements 1370, similar to supporting elements 660, partitions can be held in place while maintaining the desired shape. Thus, as described above, the design 1365 of the partitions provides gaps between the partitions, which allows air to flow through the partitions, while at the same time providing the possibility of suppressing the output noise. As with the other partition designs described herein, the edges of the long sides of the partitions are held in place so that the portion located between these edges is supported in an elastic state.

As shown in FIG. 13, the partitions of the structure 1365 should not extend over the entire height of the exhaust air chamber. Conversely, a relatively large gap 1375 can be maintained above the uppermost partition and below the upper edge of the curved partition 1355. This provides a continuous air flow flowing on top of the inside of the main part 1310 into the exhaust air chamber and along the curved partition 1355, thereby reducing the likelihood of creating air pockets and local overheating associated with them. Despite the fact that this figure shows partitions located along the height of the chamber, occupying a little more space than half the height of the chamber, partitions can also pass along the entire height of the chamber or any part of it. Similarly, the number of partitions may also differ from their number in this figure.

Partition structure 1365, curved partition 1355, and noise canceling material 1350 interact to define two air spaces 1380c and 1380b. The airspace 1380 s is defined by the noise canceling material 1350 and the curved partition 1355; this airspace provides additional noise reduction measures by reducing the amount of sound energy transmitted to the walls of the exhaust chamber lid. The air space 1380b is defined by the curved partition 1355 and the partition structure 1365 and provides alignment of the path of the air flow exiting the housing 1300, while also reflecting any sound energy leaving the main part 1310 from the curved partition 1355 and / or the partition structure 1365, thereby thereby reducing the level of perceived sound.

The housing 1300 comprises a cable port 1385, characterized by a large number of features of the cable port 900 described above. In particular, cable port 1385 typically has a box-shaped shape, is internally coated with noise-canceling material, contains a cable port cover, has openings to allow cables to pass through it, and has at least one barrier to block line of sight through the cable port. Considering the whole case, relative to cable port 900, cable port 1385 is shorter than cable port 900 (when measuring length from left to right in the figure). In addition, the cable port 1385 is located further from the rear of the electronic equipment 800 than in the previously described embodiment. Additionally, part of the curved partition 1390 is attached to the floor of the housing, while the other end of the partition is attached to or rests on the cable port 1385. This curved partition 1390 and the increased distance with respect to the rear of the electronic equipment 800 reduces the likelihood of air retention in the space 1395, thereby reducing the amount of heat remaining in the housing.

The housing 1300 includes a backflow preventing device 1400 mounted on the bottom of the cover 1315 of the exhaust air chamber, in the middle near the outlet of this chamber. In one embodiment, the device 1400 is a brush strip that extends across the width of the housing 1300 (the width does not fall into the plane of the drawing). The device 1400 reduces the amount of hot exhaust air passing under the housing 1300 and re-entering through the inlet of the intake air chamber. In addition to significantly reducing or preventing the passage of air, the brush strip remains flexible enough to allow the housing to be moved without causing damage to the device 1400. Also, the flexibility of the brush strip helps maintain close contact with possible uneven surfaces on which the housing 1300 can rest. The backflow preventer 1400 can be removable or rigidly mounted and may be located elsewhere on the bottom of the housing 1300.

The terms and expressions used in this document are used to describe and do not limit the scope of the invention. The use of such terms and expressions does not intend to exclude equivalents of the features shown or described or their parts; it is understood that various changes are possible within the scope of the present invention according to the claims. In addition, optional features and numerous embodiments are described herein. It should be understood that the features of one particular embodiment can be used in other embodiments, while remaining within the scope of the present invention.

Claims (15)

1. A housing for suppressing noise generated within the housing, comprising: a housing structure forming an inner chamber, an air inlet and an air outlet, the housing structure being configured to interact with electronic equipment located inside it to define an inlet plenum and an outlet plenum in the inner chamber, while at least one of these openings for air inlet and for air outlet includes the design of partitions from a variety of fumes OK, containing elastic material, forming a lot of holes that are connected downstream with the inner chamber and the space outside the housing structure, and each of the partitions contains an elongated part of an elastic noise-canceling material having a substantially flat profile at rest and a curved profile in a deformed state, at the same time, it is possible to sequentially pass air from outside the housing structure through the hole for air inlet into the inlet plenum, through electronic equipment leading into the exhaust plenum, and the air outlet from the hull structure through the air outlet hole made in the hull structure. 2. The housing according to claim 1, characterized in that the partitions are located on the line of direct visibility from the inside of the housing structure to the outside while maintaining open ventilation ducts between the partitions. 3. The housing according to claim 1, characterized in that it comprises a device for moving air from inside the housing structure to the exterior of the housing structure. 4. The housing according to claim 1, characterized in that the housing structure comprises a separator in the inner chamber, interacting with the electronic equipment located inside it to define the inlet plenum and the outlet plenum. 5. The housing according to claim 1, characterized in that the housing construction further comprises an upper wall, a first side wall, a second side wall and a lower wall, wherein at least one of said walls has a noise canceling material located thereon. 6. The housing according to claim 5, characterized in that the housing structure has a first axis extending from the air inlet to the air outlet, and a second axis perpendicular to the first axis, and the housing further comprises an elongated portion extending along the second axis, wherein said elongated portion is located below said lower wall between the air inlet and the air outlet and is configured to connect to at least part of the bottom wall and part of the surface on which the body rests c, so as to prevent air recirculation between the air outlet and the air inlet. 7. The housing according to claim 6, characterized in that said elongated part comprises a brush strip. 8. The housing according to claim 1, characterized in that the housing construction additionally forms an opening for a port in the housing structure, and the housing further comprises a port for outputting cables comprising a port structure configured to receive a port opening, wherein the port design defines an open top part and has at least one inner surface, while the noise canceling material is located on at least one inner surface of the port structure, the cover is removable attaching to the port structure to said open top, the lid having an inner surface on which the noise canceling material is located, while the noise canceling material located on the inner surface of the port structure interacts with the noise canceling material located on the specified inner surface of the lid when the lid is attached to port structure, to ensure insulation of at least one cable passing through the port structure into the hull structure, thus ohm in order to prevent the noise generated in the hull structure through the port structure. 9. The housing according to claim 8, characterized in that the housing structure has a first axis extending from the air inlet to the air outlet, and a second axis perpendicular to the first axis, and the housing further comprises an elongated portion extending along the second axis, wherein said elongated portion is located below said lower wall and is in contact with the lower outer surface of the port structure, wherein the elongated portion is configured to connect at least a portion of the lower outer surface of the port the port and part of the surface on which the housing rests, so as to prevent air recirculation between the air outlet and the air inlet. 10. The housing according to claim 9, characterized in that said elongated part comprises a brush bar. 11. The housing according to claim 1, characterized in that it further comprises an inlet structure having a plurality of walls that form an inlet for intake air, connected in a flow to a space outside the housing structure, a chamber for intake air and an outlet for intake air downstream with an air inlet, and at least one of the plurality of walls has a noise reduction material located thereon. 12. The housing according to claim 11, wherein the noise canceling material includes a curved partition extending between a portion of the intake air inlet and the intake air inlet, the curved partition interacting with at least one of the plurality of walls to define a curvilinear air flow paths inside the intake air chamber. 13. The housing according to claim 1, characterized in that it further comprises an exhaust structure having a plurality of walls that form an exhaust air inlet connected in a flow to an air outlet, an exhaust air chamber and an exhaust outlet connected downstream of the space outside the hull structure, at least one of the plurality of walls has a noise reduction material located thereon. 14. The housing according to claim 13, characterized in that the noise canceling material includes a curved partition extending between a part of the exhaust air inlet and the exhaust air outlet, the curved partition interacting with at least one of the plurality of walls to define a curvilinear air flow paths inside the exhaust air chamber. 15. The housing according to claim 1, characterized in that it further comprises a filtering device located in the air inlet.

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