阅读说明：本技术 冷却和电源布置 (Cooling and power supply arrangement ) 是由 K·L·凡佩尔特 L·M·史蒂文斯 于 2020-01-22 设计创作，主要内容包括：本申请公开了冷却和电源布置。一种系统,包括包壳,该包壳包括数据存储包壳。该数据存储包壳包括多个存储层和共享冷却区域。该系统进一步包括位于多个存储层中的每一个内的数据存储设备以及位于数据存储包壳内的共享冷却区域中的第一组鼓风机和第二组鼓风机。第一组鼓风机和第二组鼓风机被布置成冷却数据存储设备。(The present application discloses cooling and power supply arrangements. A system includes an enclosure including a data storage enclosure. The data storage enclosure includes a plurality of storage tiers and a shared cooling area. The system further includes a data storage device located within each of the plurality of storage tiers and a first set of blowers and a second set of blowers located in a shared cooling area within the data storage enclosure. The first set of blowers and the second set of blowers are arranged to cool the data storage device.)

1. A system, comprising:

an enclosure comprising a data storage enclosure comprising a plurality of storage tiers and a shared cooling area;

a data storage device located within each of the plurality of storage tiers; and

a first set of blowers and a second set of blowers located in the shared cooling area within the data storage enclosure and arranged to cool the data storage devices, the first set of blowers located at a first elevation and the second set of blowers located at a second elevation.

2. The system of claim 1, wherein a number of storage tiers in the data storage enclosure is less than a number of blowers in the data storage enclosure.

3. The system of claim 1, wherein the enclosure comprises a power supply enclosure separate from the data storage enclosure, the system further comprising:

a power supply unit located within the power supply enclosure.

4. The system of claim 3, wherein each of the power supply units includes a dedicated blower.

5. The system of claim 3, wherein the power supply unit is electrically coupled to one or more of the data storage devices and/or one or more of the first set of blowers and the second set of blowers.

6. The system of claim 1, wherein one or more of the data storage layers have a first height, wherein one or more of the blowers of the first and second sets of blowers have a second height that is higher than the first height.

7. The system of claim 1, further comprising:

a rack housing the enclosure and a plurality of other enclosures, each having a separate respective data storage enclosure and power supply enclosure.

8. A data storage system, comprising:

a frame, comprising:

a first enclosure having a first data storage enclosure comprising a first plurality of data storage layers and a first shared cooling area;

a first set of data storage devices located between the first plurality of data storage layers;

a first set of blowers located in the first shared cooling area within the first data storage enclosure and arranged to cool the first set of data storage devices;

a first power supply enclosure housed within the first enclosure;

a first power supply unit located within the first power supply enclosure;

a second enclosure having a second data storage enclosure comprising a second plurality of data storage layers and a second shared cooling area;

a second set of data storage devices located between the second plurality of data storage layers;

a second set of blowers located in the second shared cooling area within the second data storage enclosure and arranged to cool the second set of data storage devices;

a second power supply enclosure housed within the second enclosure; and

a second power supply unit located within the second power supply enclosure.

9. The data storage system of claim 8, wherein the first plurality of data storage layers has a first height, wherein the first set of blowers has a height greater than the first height.

10. A method for powering and cooling an electronic device, the method comprising:

providing power to the electronic device between a plurality of slidable device layers in an enclosure via one or more power supply units located within a power supply enclosure; and

powering, via the one or more power supply units, a blower located in a shared cooling area in the enclosure to draw air across each of the plurality of slidable device layers.

Disclosure of Invention

In some embodiments, a system includes an enclosure having a data storage enclosure. The data storage enclosure includes a plurality of storage tiers and a shared cooling area. The system further includes a data storage device, a first set of blowers, and a second set of blowers. The data storage device is located within each of a plurality of storage tiers, and the first set of blowers and the second set of blowers are located in the shared cooling area within the data storage enclosure. The first set of blowers is located at a first elevation and the second set of blowers is located at a second elevation.

In certain embodiments, a data storage system includes a rack. The housing includes a plurality of enclosures. Each enclosure includes a power supply enclosure and a data storage enclosure having a plurality of data storage layers and a shared cooling area. Each enclosure includes a data storage device located between the plurality of data storage layers and a blower located in the first shared cooling area for cooling the data storage device. A power supply unit is located within the power supply enclosure.

In certain embodiments, a method for powering and cooling an electronic device is disclosed. The method includes powering electronic devices located between a plurality of slidable device layers in an enclosure via one or more power supply units located within the power supply enclosure. The method also includes powering, via the one or more power supply units, a blower located in a shared cooling area in the enclosure to draw air across each of the plurality of slidable device layers.

While various embodiments are disclosed, still other embodiments of the present invention will become apparent to those skilled in the art from the following detailed description, which shows and describes illustrative embodiments of the invention. Accordingly, the drawings and detailed description are to be regarded as illustrative in nature and not as restrictive.

Drawings

FIG. 1 illustrates a perspective view of a storage system according to certain embodiments of the present disclosure.

FIG. 2 illustrates a top view of an enclosure according to certain embodiments of the present disclosure.

FIG. 3 illustrates a perspective view of the rear end of the enclosure of FIG. 2, in accordance with certain embodiments of the present disclosure.

FIG. 4 illustrates a side cross-sectional view of the enclosure of FIGS. 2 and 3, according to certain embodiments of the present disclosure.

While the disclosure is susceptible to various modifications and alternative forms, specific embodiments have been shown by way of example in the drawings and will be described in detail below. However, the disclosure is not intended to be limited to the particular embodiments described, but on the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the scope of the appended claims.

Detailed Description

Data storage systems are used to store and process large amounts of data. Maintaining the system within the desired temperature range can be challenging because systems typically generate a large amount of heat during operation. For example, during operation the data storage device and the power supply unit that powers the data storage device may generate heat. The data storage system may include a cooling device, such as a blower (e.g., a fan), that assists in operating the system within a desired temperature range. However, air blowers may generate unwanted acoustic energy that may be transmitted throughout the system and affect the performance of the data storage devices housed in the system. Certain embodiments of the present disclosure feature an arrangement of cooling devices and/or power supply units that reduces the amount of acoustic energy that affects the performance of a data storage device.

Fig. 1 shows a data storage device 100 including a rack 102 (e.g., enclosure), the rack 102 having a plurality of enclosures 104. Each enclosure 104 may include a plurality of drawers or storage tiers 106 that house electronic devices, such as data storage devices mounted within the drawers or storage tiers 106. Each enclosure 104 may itself be arranged in a drawer-like manner to slide into and out of the rack 102, although the enclosures 104 need not be so arranged.

FIG. 2 illustrates a top view of enclosure 200, enclosure 200 may be used in a data storage system, such as data storage system 100 of FIG. 1. For example, a rack, such as rack 102 in fig. 1, may include a plurality of individual enclosures, such as enclosure 200. Fig. 3 shows a perspective view of the rear of the enclosure 200, and fig. 4 shows a side cross-sectional view of the enclosure 200. The enclosure 200 is divided into a data storage enclosure 202 and a power supply enclosure 204.

The enclosure 200 includes a data storage device 206 (e.g., a hard disk drive and/or a solid state drive) located within a data storage enclosure 202, and includes a chassis 208. The exterior of the chassis 208 includes a front sidewall 210A, a first sidewall 210B, a second sidewall 210C, a first bottom wall 210D (shown in fig. 3 and 4), and a top cover 210E (shown in fig. 3 and 4).

The data storage enclosure 202 is shown as being formed from all or part of a front side wall 210A, a first side wall 210B, a second side wall 210C, a first bottom wall 210D (shown in fig. 3 and 4), a top cover 210E (shown in fig. 3 and 4), and a second bottom wall 210F (shown in fig. 3 and 4). The power supply enclosure 204 is shown as being formed by all or part of the front side wall 210A, the first side wall 210B, the second side wall 210C, the first bottom wall 210D, and the second bottom wall 210F. Each wall of the chassis 208 may be comprised of multiple wall components assembled together or of a single component (e.g., formed from a piece of sheet metal). The chassis wall may be made of metal (e.g., aluminum, steel) in the form of sheet metal. The enclosure 200 (including the data storage enclosure 202 and the power supply enclosure 204) extends between a front end 212 and a rear end 214.

When assembled, the chassis 208 houses and supports the data storage device 206, the cooling devices 216A-D, the power supply unit 218, and various other electrical components, such as wiring and circuit boards (not shown), the cooling devices 216A-D being referred to hereinafter as blowers (e.g., fan modules).

Data storage enclosure 202 houses data storage device 206. As shown in FIG. 2, data storage enclosure 202 includes eight separate rows of data storage regions 220A-H extending between first sidewall 210B and second sidewall 210C, although fewer or more rows of data storage devices 206 may be incorporated into data storage enclosure 202. As shown in FIG. 4, data storage enclosure 202 includes a plurality of data storage layers 222A-C. Each data storage layer 222A-C includes multiple rows of data storage devices 206. Data storage device 206, located on first data storage layer 222A, is supported by first bottom wall 210D of chassis 208; data storage devices 206 located on the second data storage layer 222B are supported by the second bottom wall 210G; and, data storage devices 206 located on third data storage layer 222C are supported by third bottom wall 210H. In certain embodiments, each separate data storage layer 222A-C includes separate sidewalls such that each data storage layer 222A-C forms a separate and at least partial enclosure.

In certain embodiments, the data storage enclosure 202 includes sliding members 224A-C coupled to or formed as part of the first and second sidewalls 210B, 210C. Sliding members 224A-C allow each of data storage layers 222A-C to slide into and out of data storage enclosure 202. Each data storage layer 222A-C may include a corresponding component (e.g., a wheel) operably coupled to sliding components 224A-C such that data storage layers 222A-C may be easily slid into and out of data storage enclosure 202.

The data storage enclosure 202 includes a cooling region 226 extending from the aft end 214 of the enclosure 200, with a plurality of blowers 216A-D located in the cooling region 226. The blowers 216A-D may be fan modules with blades 228 (shown in FIG. 3), the blades 228 rotating about respective axes of rotation 230. Blowers 216A-D are secured to rear wall 210J of chassis 208 (rear wall 210J is not shown in FIG. 3 to show details inside data storage enclosure 202) to secure to enclosure 200. In certain embodiments, a vibration damper, such as a rubber gasket, is coupled between the blowers 216A-D and the rear wall 210J to help reduce the amount of chassis vibrations transmitted to the remainder of the enclosure 200. As shown in fig. 3 and 4, two of the blowers (216A and 216B) are located at a different height than the other two blowers 216C and 216D located in the data storage enclosure 202 and are higher than the other two blowers 216C and 216D. The blowers 216A-D draw air from the front end 212 of the enclosure 200 toward the rear end 214 of the enclosure 200 and then expel the air out of the data storage enclosure 202.

As the density of data storage devices in the enclosure is higher, the enclosure requires more cooling to maintain the required operating temperature of the data storage devices. While adding more fans to the enclosure or increasing the speed at which the fans operate may provide better cooling for the enclosure, these approaches increase energy consumption and increase the amount of acoustic energy generated by the fans and transmitted in the enclosure. As the fan blades rotate, the fans generate acoustic energy (e.g., energy transmitted through air) that may affect the performance of the data storage device. When acoustic energy is transmitted to a data storage device, the data storage device vibrates, thereby affecting its data storage device's ability to enter data and read data. For hard disk drive data storage devices, the vibrations caused by the acoustic energy make it difficult for the read/write heads in the hard disk drives to settle on or follow the desired data tracks for data read and data write operations. As hard disk drives store more data per disk, the risk of acoustic energy affecting performance increases, thus requiring better positioning of the read/write heads. The impact on the performance of the data storage devices in the enclosure is particularly significant for the data storage devices located closest to the fan.

Instead of adding more fans and/or increasing the operating speed of fans, the data storage enclosure 202 of the present disclosure features blowers 216A-D that are "shared" among multiple data storage devices 206 and among multiple data storage levels. The data storage enclosure 202 includes fewer blowers 216A-D (e.g., four) than conventional enclosures. For example, conventional enclosures typically use multiple fans arranged to cool a single data storage layer in the enclosure, such that each data storage layer is associated with and cooled by a dedicated set of fans. In such conventional arrangements, the enclosure includes at least two fans for each data storage layer. In certain embodiments of the present disclosure, blowers 216A-D are positioned relative to data storage layers 222A-C such that air drawn by blowers 216A-D is drawn from and across the plurality of data storage layers 222A-C. As such, blowers 216A-D are shared and not located at locations dedicated to drawers or data storage layers. Using fewer blowers in an enclosure via sharing blowers between multiple data storage layers may help reduce the total amount of acoustic energy generated by the blowers in the enclosure.

The present disclosure features another method for reducing acoustic energy that involves incorporating larger than conventional blowers 216A-D in the data storage enclosure 202. In conventional arrangements with standard sized enclosures (e.g., 3U, 4U), the space for the fan is limited, thus limiting the size of fan that can be used. For example, fans in conventional containment arrangements are typically limited to approximately 80 millimeters in diameter or less. In certain embodiments of the present disclosure, the blowers 216A-D may have diameters in the range of, for example, 150 and 220mm, because the blowers 216A-D are not limited by the height of a single drawer and a single data storage layer. For example, the diameter of blowers 216A-D may be greater than the height of respective data storage layers 222A-C. Larger blowers may be operated at lower speeds to meet a given cooling demand than smaller blowers. For example, a smaller blower may need to be operated at 15000rpm to provide the same cooling effect as a larger blower operating at 7000 rpm. As such, in certain embodiments of the present disclosure, the blowers 216A-D may be operated within a range such as 5000-10000rpm as compared to the higher operating speeds (e.g., 12000rpm, 15000rpm) required when using smaller diameter air. A blower running at low speed generates less acoustic energy. The method of the present disclosure using fewer but larger blowers 216A-D may reduce the total amount of acoustic energy generated and transmitted throughout the data storage enclosure 202. As described above, reducing the amount of acoustic energy may mitigate performance degradation of the data storage device 206 located within the data storage enclosure 202.

The present disclosure features another method for reducing the effects of acoustic energy that places the blowers 216A-D farther from the data storage device 206 than conventional enclosures. In conventional enclosures, the fan is only one or two inches from the data storage device. The blowers 216A-D are farther from the data storage device 206 and the smaller the acoustic energy generated by the fans affects the data storage device. In certain embodiments of the present disclosure, the blowers 216A-D are five inches to six inches from the data storage device 206 (as measured along the longitudinal axis 232 of the enclosure 200). As a result, the space 234 in the cooling region 226 between the blowers 216A-D and the data storage device 206 is larger than for a conventional enclosure. At least a portion of the space 234 may be filled with one or more acoustic baffles to further attenuate acoustic energy affecting the data storage device 206. Further, some or all of the surfaces in the space 234 may be covered by a sound absorbing material 236 (e.g., a non-metallic material such as cloth fiber and a porous polymer-based material such as polyurethane foam). The sound absorbing material 236 may attenuate the acoustic energy generated by the blowers 216A-D.

The present disclosure also features a method for reducing the effects of chassis vibrations (e.g., energy transmitted through the chassis 208 itself). During operation, the blowers 216A-D generate chassis vibrations in addition to acoustic energy. Like acoustic energy, chassis vibrations can negatively impact the performance of the data storage device. In conventional enclosures, the proximity of the fan to the data storage device causes chassis vibrations to have a relatively short path to travel to the data storage device, which increases the risk that chassis vibrations will affect data storage device performance. In certain embodiments of the present disclosure, the blowers 216A-D are positioned such that chassis vibrations generated by the blowers 216A-D propagate a longer path along the chassis 208 before affecting the data storage device 206. For example, in certain embodiments of the present disclosure, chassis vibrations generated by one of the blowers 216A-D must propagate through the back wall 210J, through the second sidewall 210C, through the sliding members 224A-C, through corresponding components on the data storage layer, and through the bottom walls 210D, 210G, and 210H before reaching the data storage device 206. In addition, various components, such as dampers, may be placed along the path between the blowers 216A-D and the data storage device 206 to further mitigate chassis vibrations affecting the data storage device 206.

The present disclosure features another method for reducing acoustic energy by placing the power supply unit 218 in a separate enclosure and cooling the separate enclosure with its own blower. In a conventional enclosure, the power supply unit is located in the same enclosure as the data storage device and is cooled by the same fan. As the power supply unit 218 operates (e.g., converts wall power to 5 volts or 12 volts required for the data storage device), the power supply unit 218 generates heat, which requires that the conventional enclosure use more fans or more power than is required to cool the enclosure. Furthermore, the power supply unit may block the airflow within the enclosure. Thus, cooling the data storage device and the power supply unit using the same fan increases the acoustic energy generated in the enclosure.

In certain embodiments of the present disclosure, the power supply unit 218 is located in the power supply enclosure 204. As such, blowers 216A-D located within data storage enclosure 202 may be operated at a lower speed than the desired operating speed of blowers 216A-D when power supply unit 218 is located within data storage enclosure 202. The power supply enclosure 204 may include blowers 216E-G arranged to cool a power supply unit 218. In certain embodiments, the blowers 216E-G in the power supply enclosure 204 are directly attached as part of the power supply unit 218 or integrally formed as part of the power supply unit 218. The diameter of these blowers 216E-G (e.g., <40mm) may be smaller than the diameter of the blowers 216A-D in the data storage enclosure 202. The power supply unit 218 is electrically coupled to the data storage device 206 and/or one or more of the blowers 216A-G.

As described above, a rack, such as rack 102 in FIG. 1, may include multiple enclosures, such as enclosure 200 described above. In such an arrangement, the rack may include multiple enclosures, each having a separate data storage enclosure (e.g., data storage enclosure 202) and a separate power supply enclosure (e.g., power supply enclosure 204). Each separate data storage enclosure within the rack will include a plurality of data storage devices (located between the plurality of data storage layers) powered by one or more power supply units in the separate power supply enclosure. Each separate data storage device will further include its own blower unit to provide cooling for the respective data storage device.

As described above, the enclosure 200 and its components may be designed to incorporate one or more of the arrangements described above to improve the performance of the data storage system. For example, the enclosure 200 may be designed to reduce the total amount of acoustic energy and chassis vibrations that affect performance by one or more of the following: the method includes the steps of incorporating fewer blowers, incorporating a larger diameter blower, operating the blower at a reduced speed, incorporating sound dampening material, increasing the space between the data storage device and the blower, extending and/or otherwise attenuating the chassis vibration path between the data storage device and the blower, adding vibration dampeners along the chassis vibration path, and placing the power supply device in an enclosure separate from the data storage enclosure.

Various modifications and additions may be made to the disclosed embodiments without departing from the scope of the present disclosure. For example, although the embodiments described above refer to particular features, the scope of the present disclosure also includes embodiments having different combinations of features and embodiments that do not include all of the described features. Accordingly, the scope of the present disclosure is intended to embrace all such alternatives, modifications, and variations as fall within the scope of the claims, and all equivalents thereof.