WO2020187182A1

WO2020187182A1 - Processing apparatus and processing method therefor

Info

Publication number: WO2020187182A1
Application number: PCT/CN2020/079506
Authority: WO
Inventors: 何涛; 洪清泉
Original assignee: 上海小麦互动企业发展有限公司
Priority date: 2019-03-15
Filing date: 2020-03-16
Publication date: 2020-09-24

Abstract

Provided are a processing apparatus and a processing method therefor. The processing apparatus comprises at least one processing unit, an auxiliary processing unit and a shell, wherein the processing unit is mounted at an inner side of the shell, the auxiliary processing unit is mounted at the inner side of the shell, and each processing unit is respectively connected to the auxiliary processing unit and enters an operating state.

Description

Processing device and processing method

Technical field

The invention relates to the field of data processing equipment, in particular to a processing device and a processing method thereof.

Background technique

A server is a device that provides computing services and can process a large amount of data.

When the server fails, data processing will be interrupted, thereby affecting the processing process and processing results. The server is responsible for the processing work of the central processing unit and the motherboard chipset. Once the components in the central processing unit and the motherboard chipset are damaged, the server will fail and cannot be used.

The development of the Internet has brought about the explosive growth of data, and efficient data processing in the era of big data is particularly important. However, the huge amount of data depends on the processing capacity of the processing server, especially the server chip. The chip is the core of the server's data processing. To ensure the operation of the server, the security and normal operation of the chip must be guaranteed. The chip processes the data according to the instructions. When the chip fails, the server will not operate normally, lose computing power, and the data cannot be effectively processed. In the Internet age, any time delay may cause data to lose timeliness, even if it is only a short, transient failure.

In order for data to be processed in a timely and effective manner, the processing capacity of the server needs to be better exploded. The processing power of the server is provided by the chip. Once the chip fails, the time for replacing or repairing the chip must be consumed, and it is difficult to effectively control it. Waiting for the chip to be replaced and re-processing the data will inevitably cause the interruption of the data processing. The processing may fall short, or the data may lose validity. Therefore, the consequences of continuing data processing after waiting for the original server to be repaired on the same server are unpredictable and may cause losses. Migrating data from a failed original server to a new server with processing capabilities will also cause interruptions in data processing and cause unpredictable consequences.

In addition, stopping the operation of the server to replace the chip will also cause huge cost loss. Disassembling the entire server to replace the chips in it will not only cause the middle of data processing, but will also cause cost consumption due to the time of disassembly, replacement and installation.

When the client processes the content output, it will occupy the client's hardware performance and software environment, so the efficiency of content output is limited by the client's own conditions. When the client itself is not enough to process the content output, it is easy to cause the delay of the content output and the content loss. In the game field, to play online games, you need to download and install the game client first, which causes the performance of mobile phones, computers and other devices to be occupied by the game client, which affects the processing efficiency of the device and is prone to content delay.

Therefore, a technology is needed to solve the above problems.

Summary of the invention

Another advantage of the present invention is to provide a processing device and a processing method thereof. The processing unit of the processing device is separately detachable and mounted on the processing device, and the processing units are independent of each other.

Another advantage of the present invention is to provide a processing device and a processing method thereof, wherein the processing unit of the processing device is installed and removed by hot plugging.

Another advantage of the present invention is to provide a processing device and a processing method thereof. The processing unit of the processing method device is installed and disassembled by hot plugging.

Another advantage of the present invention is to provide a processing device and a processing method thereof. The processing units of the processing device are independent of each other and do not interfere with each other.

Another advantage of the present invention is to provide a processing device and a processing method thereof. The processing device provides an auxiliary processing unit to provide processing assistance to the processing unit.

Another advantage of the present invention is to provide a processing device and a processing method thereof. The processing unit and the auxiliary processing unit of the processing device are installed in a housing to form the processing device.

Another advantage of the present invention is to provide a processing device and a processing method thereof. The processing unit of the processing device is independently connected to the auxiliary processing unit, and the auxiliary processing unit provides processing for each processing unit. Auxiliary.

Another advantage of the present invention is to provide a processing device and a processing method thereof. The processing units of the processing device work independently of each other and also work in cooperation.

Another advantage of the present invention is to provide a processing device and a processing method thereof. The housing of the processing device has an independent support channel for installing the processing unit.

Another advantage of the present invention is to provide a processing device and a processing method thereof. The processing unit of the processing device includes at least one first connector, the housing includes at least one second connector, and the first The connecting member is arranged in the supporting channel, the processing unit is installed to the supporting channel, and the first connecting member and the second connecting member are connected.

Another advantage of the present invention is to provide a processing device and a processing method thereof. The processing unit of the processing device includes at least one sub-processing unit, and the sub-processing unit is detachably mounted on the processing unit. The sub-processing unit is hot-swappable.

Another advantage of the present invention is to provide a processing device and a processing method thereof. The processing device removes and installs the processing unit through hot plugging, so that the processing device maintains a working state.

Another advantage of the present invention is to provide a processing device and a processing method thereof, wherein the processing device removes and installs the sub-processing unit through hot plugging, so that the other processing units of the processing device keep working.

Another advantage of the present invention is to provide a processing device and a processing method thereof. The processing device realizes disassembly and installation of the processing unit and the sub-processing unit through hot plugging, thereby reducing costs and saving time.

Another advantage of the present invention is to provide a processing device and a processing method thereof. The processing device is equipped with a processing system, and the processing system manages the processing unit.

Another advantage of the present invention is to provide a processing device and a processing method thereof. The processing device is used for content processing, wherein the processing device receives a content request from a client and generates the content requested by the client.

Another advantage of the present invention is to provide a processing device and a processing method thereof. The processing device transmits content to the client in the form of a content stream, improves transmission and playback efficiency, and controls content delay.

Another advantage of the present invention is to provide a processing device and a processing method thereof. The processing device allocates the processing unit to the client, and the processing unit processes the content request of the client.

Other advantages and features of the present invention are fully embodied by the following detailed description and can be realized by the combination of means and devices specifically pointed out in the appended claims.

According to one aspect of the present invention, a processing device of the present invention that can achieve the foregoing objectives and other objectives and advantages includes:

At least one processing unit;

An auxiliary processing unit; and

A housing, wherein the processing unit is installed inside the housing, and the auxiliary processing unit is installed inside the housing, wherein the processing unit and the auxiliary processing unit are connected to enter a working state .

According to an embodiment of the present invention, the processing unit includes a base and a mounting side wall, the mounting side wall is fixed to the base, and the mounting side wall is formed by vertically extending from one end of the base.

According to an embodiment of the present invention, the processing unit includes at least one sub-processing unit, and the sub-processing unit is detachably mounted on the base.

According to an embodiment of the present invention, the processing unit includes at least one first connecting member, the first connecting member is disposed on a side of the base opposite to the mounting side wall, and the sub-processing unit is connected to The first connecting member.

According to an embodiment of the present invention, the processing unit includes a holding member, and the holding member is installed on the outer side of the installation side wall.

According to an embodiment of the present invention, the housing includes a housing base and a cover, the cover covering the housing base, wherein the housing base includes a front wall, and the front wall is arranged One or more installation openings, the periphery of the installation opening extends toward the inner side of the housing to form an inner wall, and the inner wall surrounds to form a support channel.

According to an embodiment of the present invention, the processing element is installed in the supporting channel.

According to an embodiment of the present invention, the housing base includes at least one connecting body formed between two side walls of the housing base, and the processing unit and the auxiliary processing unit are respectively installed On both sides of the connecting main body, wherein the connecting main body is provided with at least one second connecting member, and the second connecting member faces the supporting channel.

According to an embodiment of the present invention, the auxiliary processing unit is connected to each of the second connecting members, and the processing unit and the auxiliary processing unit are connected by the first connecting member and the second connecting member. Connected, the processing unit enters the working state.

According to an embodiment of the present invention, the housing includes a mounting portion and an auxiliary portion, the mounting portion and the auxiliary portion are respectively formed on both sides of the connecting body, wherein the processing unit is mounted on the The installation part, the auxiliary part has an auxiliary space, and the auxiliary processing unit is installed in the auxiliary space.

According to an embodiment of the present invention, the auxiliary processing unit includes at least one energizing element, the energizing element is enerably connected to the second connector, and the processing unit is installed in the supporting channel, The processing unit obtains energy from the energy supply element through the connection of the first connection member and the second connection.

According to an embodiment of the present invention, the auxiliary processing unit includes at least one storage element, the storage element is connected to the second connector, the processing unit is installed in the supporting channel, and the processing unit passes through the The connection between the first connector and the second connection is for data transmission with the storage element, wherein the processing unit stores data in the storage element.

According to an embodiment of the present invention, the auxiliary processing unit includes at least one network control element, the network control element is connected to the second connector, the processing unit is installed in the support channel, and the network control The element provides a communication network for the processing unit through the connection of the first connector and the second connection.

According to an embodiment of the present invention, the processing unit is installed in the supporting channel, and a heat dissipation channel is formed between the base and the inner wall, wherein the heat dissipation channel communicates with the auxiliary space.

According to an embodiment of the present invention, the auxiliary processing unit includes at least one heat dissipation element, the heat dissipation element is installed in the auxiliary space, and provides heat dissipation for the processing unit through the communication between the auxiliary space and the heat dissipation channel .

According to an embodiment of the present invention, a processing system is further carried, the processing system is communicatively connected to the processing device for content processing, wherein the processing system includes:

An initial module, the initial module is communicatively connected to the second connecting member to detect whether the processing unit is installed and disassembled, wherein the initial module selects a processing unit from the processing unit as a Management unit; and

A management module, the management module is communicatively connected to the initial module to obtain the management unit, and the management unit manages the other processing units through the management module.

According to an embodiment of the present invention, the initial module detects the performance of the processing unit in a working state to generate a management value, and the initial module selects the processing unit as the management unit according to the management value, wherein The performance of the management unit is adapted to the management value.

According to an embodiment of the present invention, further comprising at least one management unit installed in the auxiliary part, and the management unit is communicatively connected to the auxiliary processing unit so that the auxiliary processing unit assists the The management unit performs processing, and the management unit is communicatively connected to the second connector, and is detachably connected to the processing unit through the second connector.

According to an embodiment of the present invention, the management unit monitors whether the working state of each processing unit is normal, when the processing unit is processing at least one task, the processing unit is in a normal working state, and when the processing unit Stop processing data, the processing unit is in an abnormal working state, and when the processing unit does not process data, the processing unit is in an idle working state.

According to an embodiment of the present invention, the processing unit stores data in the storage element in real time. When the management unit detects that the processing unit is in an abnormal working state, the management unit obtains all data from the storage element. Data of the processing unit, and assign the data to another processing unit.

According to an embodiment of the present invention, the management unit acquires the data of the processing unit in an abnormal working state, and transfers the data to another processing unit in a normal working state for processing.

According to an embodiment of the present invention, the management unit analyzes a remaining processing capacity of the processing unit in a normal working state, and the management unit assigns the task to the processing unit with sufficient remaining processing capacity.

According to an embodiment of the present invention, the management unit assigns the task to the idle processing unit.

According to an embodiment of the present invention, the management unit receives at least one content request sent by at least one client, wherein the content request requests at least one content, the management unit generates the content request as a task, the The management unit assigns the task to the processing unit, and the processing unit is connected to the client, wherein the processing unit processes the task and produces the content requested by the client.

According to an embodiment of the present invention, the processing unit processes the content into a set of content units, the processing unit transmits the content units to the client in the form of a content stream, and the client plays the content Stream, forming the content.

According to an embodiment of the present invention, the processing unit includes at least one sub-processing unit, the sub-processing unit is connected to the auxiliary processing unit to enter a working state, wherein the sub-processing unit serves as a management sub-unit to manage The other processing units and the sub-processing units.

According to an embodiment of the present invention, the processing unit includes at least two sub-processing units connected to the auxiliary processing unit to enter a working state, and one of the sub-processing units is used as a management sub-unit to manage The other processing unit and the sub-processing unit, and the other sub-processing unit performs data processing.

According to another aspect of the present invention, a processing device of the present invention that can achieve the foregoing objectives and other objectives and advantages includes:

At least one processing unit;

An auxiliary processing unit; and

A housing, wherein the processing unit and the auxiliary processing unit are respectively mounted to the inner cavity of the housing, and the processing unit is detachably connected to the auxiliary processing unit.

At least one processing unit;

An auxiliary processing unit; and

A housing, wherein the housing includes a connecting body, and the processing unit and the auxiliary processing unit are respectively installed on both sides of the connecting body and connected to each other through the connecting body.

At least one processing unit;

An auxiliary processing unit; and

A housing, wherein a front wall of the housing is provided with one or more installation openings, and each of the installation openings is distributed in an array on the front wall, wherein the installation openings are separated from the periphery of the installation openings An inner wall extends to the inside of the housing, and each of the inner walls surrounds to form a support channel. The processing unit is detachably mounted on the support channel, and the auxiliary processing unit is mounted on the housing opposite to On the other side of the front wall.

According to one aspect of the present invention, the present invention further provides a processing method including the following steps:

(A) Select a processing unit as a management unit;

(B) Assign the task to the processing unit;

(C) Generate at least one content;

According to an embodiment of the present invention, the following steps are further included between the step (A) and the step (B):

At least one content request sent by at least one client is generated at least one task.

According to an embodiment of the present invention, it further includes the following steps:

Processing the content into a set of content units;

Stream the content unit to the client.

Through the understanding of the following description and the drawings, the further objectives and advantages of the present invention will be fully embodied.

These and other objectives, features and advantages of the present invention are fully embodied by the following detailed description, drawings and claims.

Description of the drawings

1A and 1B are perspective views of a processing device according to a preferred embodiment of the present invention.

Fig. 2 is a perspective view of a processing unit of the processing device according to the above-mentioned preferred embodiment of the present invention.

Fig. 3 is a schematic diagram of the processing device according to the above-mentioned preferred embodiment of the present invention.

Fig. 4 is a schematic diagram of the processing device according to a modified embodiment of the above-mentioned preferred embodiment of the present invention.

Fig. 5 is a rear view of the processing device according to the above-mentioned preferred embodiment of the present invention.

Fig. 6 is a schematic diagram of the processing device according to the above-mentioned preferred embodiment of the present invention.

Fig. 7 is another modified embodiment of the processing device according to the above-mentioned preferred embodiment of the present invention.

Fig. 8 is a system block diagram according to the above preferred embodiment of the present invention.

Fig. 9 is a structural block diagram of the above-mentioned preferred embodiment according to the present invention.

10A and 10B are schematic diagrams of the installation of the processing unit according to the above-mentioned preferred embodiment of the present invention.

Fig. 10C is a flowchart of the above-mentioned preferred embodiment according to the present invention.

11A and 11B are schematic diagrams of disassembly and installation of the processing unit according to the above-mentioned preferred embodiment of the present invention.

Fig. 11C is a flowchart of the above-mentioned preferred embodiment according to the present invention.

12A to 12B are schematic diagrams of disassembled at least one sub-processing unit of the processing unit according to the above-mentioned preferred embodiment of the present invention.

Fig. 13 is a schematic diagram of another modified embodiment of the above-mentioned preferred embodiment according to the present invention.

Fig. 14 is a schematic diagram of content processing performed by the processing device according to the above-mentioned preferred embodiment of the present invention.

detailed description

The following description is used to disclose the present invention so that those skilled in the art can implement the present invention. The preferred embodiments in the following description are only examples, and those skilled in the art can think of other obvious variations. The basic principles of the present invention defined in the following description can be applied to other embodiments, modifications, improvements, equivalents, and other technical solutions that do not depart from the spirit and scope of the present invention.

Those skilled in the art should understand that, in the disclosure of the present invention, the terms "longitudinal", "lateral", "upper", "lower", "front", "rear", "left", "right", " The orientation or positional relationship indicated by "vertical", "horizontal", "top", "bottom", "inner", "outer", etc. are based on the orientation or positional relationship shown in the drawings, which is only for the convenience of describing the present invention And to simplify the description, rather than indicating or implying that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, so the above terms should not be understood as limiting the present invention.

It can be understood that the term "a" should be understood as "at least one" or "one or more", that is, in one embodiment, the number of an element may be one, while in other embodiments, The number can be multiple, and the term "one" cannot be understood as a restriction on the number.

The invention provides a processing device. As shown in FIG. 1 to FIG. 14 in a preferred embodiment of the present invention, the processing device includes at least two processing units 10, at least one auxiliary processing unit 20 and a housing 30. The processing unit 10 and the auxiliary processing unit 20 are respectively installed in the housing 30. Wherein, the casing 30 wraps the processing unit 10 and the auxiliary processing unit 30. The housing 30 has an inner cavity, and the processing unit 10 and the auxiliary processing unit 20 are respectively installed in the inner cavity of the housing 30.

The housing 30 includes a housing base 31 and a cover body 32. The cover body 32 is detachably mounted on the housing base 31. The cover body 32 and the housing base 31 are formed between The inner cavity of the housing 30. The processing unit 10 and the auxiliary processing unit 20 are installed on the housing base 31 and are accommodated in the inner cavity of the housing 30.

Wherein, the housing base 31 includes a front wall 311, a rear wall 312, and two side walls 313. The front wall 311, the side walls 313, the rear wall 312 and the other side wall 313 surround the The side wall of the housing base 31. The processing unit 10 is pushed into the casing 30 from the side of the front wall 311 to be installed in the casing 30. Wherein, the front wall 311 is provided with at least one installation opening 310, and a supporting channel 3100 is respectively extended from the installation opening 310 to the inside of the housing 30, and the supporting channel 3100 is used for installing the processing unit 10.

In an example of the present invention, the front wall 311 is provided with a plurality of installation openings 310. There is a certain distance between the installation openings 310 for the processing units 10 to pass through to be installed in the support channel 3100. The supporting channels 3100 are independent of each other. Preferably, each of the supporting channels 3100 can be used to install one processing unit 10 respectively.

An inner wall 3111 is formed extending from the periphery of each installation opening 31 toward the inside of the housing 30 respectively. The inner wall 3111 surrounds the supporting channel 3100. When the processing unit 10 is installed in the supporting channel 3100, the processing unit 30 is surrounded by the inner wall 3111. The processing unit 10 is supported by the bottom of the inner wall 3111 so that the processing unit 10 is stably installed in the supporting channel 3100.

2, the processing unit 10 includes a base 11 and a mounting side wall 12. The mounting side wall 12 is fixed to the base 11 and is perpendicular to the base 11. The installation side wall 12 extends vertically from one end of the base 11. Wherein, the inner side of the installation side wall 12 faces the side of the base 11. The processing unit 10 further includes a holding member 13 which is fixed to the outer side of the installation side wall 12. The holding member 13 is for holding. Preferably, the holding member 13 is implemented as a handle.

The mounting side wall 12 is provided with at least one through hole 120. The through hole 120 communicates with the outside and the inside of the mounting side wall 12.

The processing unit 10 further includes one or more sub-processing units 14, and the sub-processing units 14 are installed on the base 11. The sub-processing unit 14 is used to process data. Each of the sub-processing units 14 is detachably mounted on the base 11.

The processing unit 10 further includes at least one first connecting member 15, and the first connecting member 15 is disposed on the side surface of the base 11. The first connecting member 15 extends outward from the side wall of the base 11. The first connecting member 15 and the installation side wall 12 are divided into two sides of the base 11. When the processing unit 10 is installed in the housing 30, the first connecting member 15 connects the processing unit 10 and the housing 30.

The first connecting member 15 is connected to the sub-processing unit 14. Preferably, each of the sub-processing units 14 is independently connected to the first connecting member 15. The sub-processing units 14 do not affect each other.

In an example of the present invention, the processing unit 10 further includes at least one communication unit 16, the communication unit is detachably mounted on the base 11, and the communication unit 16 is connected to the sub-processing unit 14, The communication unit 16 is connected to the first connector 15, and the communication unit 16 provides the sub-processing unit 14 with communication with other sub-processing units 14. The sub-processing unit 14 is connected to the first connector 15 through the communication unit 16.

The processing unit 10 is installed into the support channel 3100 through the installation opening 310. The size of the installation opening 310 is adapted to the size of the installation side wall 12 of the processing unit 10. The installation side wall 12 is located at one end of the base 11, and the height of the installation side wall 12 is higher than that of the installation side wall 12. The height of the base 11, when the processing unit 10 is installed into the support channel 3100 through the installation opening 310, the base 11 moves into the support channel 3100, and the installation side wall 311 closes the installation Opening 310. The base 11 occupies a part of the supporting channel 3100, and the remaining supporting channel 3100 forms a heat dissipation channel 3120. That is, when the processing unit 10 is installed in the supporting channel 3100, the heat dissipation channel 3120 is formed between the base 11 and the inner wall 3111.

Wherein, the processing unit 10 is pushed into the supporting channel 3100 by holding the holding member 13.

3, the housing 30 further includes at least one connecting body 314, the connecting body 314 is arranged on the housing base 31, the processing unit 10 and the auxiliary processing unit 20 are respectively installed in the The two sides of the main body 314 are connected. The distance between the connecting body 314 and the front wall 311 is suitable for the installation of the processing unit 10. The auxiliary processing unit 20 is connected to the connecting body 314. Wherein, the connecting body 314 is formed between the two side walls 313.

The inner wall 3111 forming the supporting channel 3100 extends from the front wall 311 to the connecting body 314. One end of the supporting channel 3100 is formed in the mounting opening 310, and the other end of the supporting channel 3100 extends to one side of the connecting body 314. When the processing unit 10 is installed in the supporting channel 3100, the installation side wall 311 at one end of the processing unit 10 is attached to the installation opening 310, and the other end of the processing unit 10 is attached to the connection Main body 314.

The connecting body 314 is provided with one or more second connecting members 3141, and one end of each second connecting member 3141 faces each of the supporting channels 3100 respectively. Wherein, the first connecting member 15 of the processing unit 10 is disposed on the other side of the base 11 relative to the installation side wall 12. When the processing unit 10 is installed in the supporting channel 3100, the first connection member 15 and the second connection 3141 are connected. Preferably, the first connecting member 15 and the second connecting member 3141 are coupled.

The housing 30 includes a mounting portion 33 and an auxiliary portion 34, and the mounting portion 33 and the auxiliary portion 34 are respectively formed on two sides of the connecting body 314. Wherein, the processing unit 10 is installed in the installation portion 33, the auxiliary processing unit 20 is installed in the auxiliary portion 34, and the auxiliary processing unit 20 is connected to the processing unit 10 to form the processing unit 10Provide processing assistance.

The mounting portion 33 is formed between the front wall 311 of the housing 30 and the side of the connecting body 314. The front wall 311 is provided with a plurality of installation openings 310, and there is a certain interval between the installation openings 310. Preferably, the mounting openings 310 are arranged on the front wall 311 in an array. The inner wall 3111 is respectively extended from each of the mounting openings 310 toward the inside of the housing 30. Each of the inner walls 3111 surrounds each of the supporting channels 3100. The supporting channels 3100 are distributed in an array on the mounting portion 33 of the housing 30. When the processing unit 10 is installed to the supporting channel 3100 through the installation opening 310, the inner wall 3111 surrounds the processing unit 10, and each processing unit 10 is separated by the inner wall 3111, and each The processing unit 10 is mounted to the mounting portion 33 in an array.

In other words, the support channels 3100 formed by the inner walls 3111 are distributed in an array on the housing 30, so that the processing units 10 respectively mounted to the support channels 3100 are distributed in an array.

The casing 30 has an auxiliary space 3400 formed in the auxiliary portion 34 of the casing 30, and the auxiliary space 3400 is in communication with the supporting passage 3100. When the processing unit 10 is installed in the supporting channel 3100, the heat dissipation channel 3120 formed between the base 11 and the inner wall 3111 communicates with the auxiliary space 3400.

When the processing unit 10 is mounted to the supporting channel 3100, the processing unit 10 is mounted to the mounting portion 33 on the side of the connecting main body 314, and the first connecting piece 15 of the processing unit 10 It is connected to the second connecting member 3141 of the connecting body 314. Each of the second connecting members 3141 is connected to the auxiliary processing unit 20 independently. Each of the processing units 10 is independently connected to the auxiliary processing unit 20 through the connection of the first connecting member 15 and the second connecting member 3141 respectively.

The auxiliary processing unit 20 is installed in the inner cavity of the housing 30, and the auxiliary processing unit 20 provides processing assistance for the processing unit 10. The auxiliary processing unit 20 is installed in the auxiliary space 3400 on the side of the connecting body 314. The auxiliary processing unit 20 is connected to each of the second connecting members 3141 of the connecting main body 314, and the auxiliary processing unit 20 passes through the connecting main body 314 and the processing unit 10 mounted to the mounting portion 33. connection. The processing unit 10 and the auxiliary processing unit 20 are respectively distributed on both sides of the connecting body 314 and connected by the connecting body 314. Each of the processing units 10 is independently connected to the auxiliary processing unit 20 through the second connecting member 3141.

The auxiliary processing unit 20 includes at least one energy supply element 21, and the energy supply element 21 is enerably connected to the processing unit 10 to provide energy for the processing unit 10. Wherein, the energy supply element 21 is connected to each of the second connecting members 3141. The auxiliary processing unit 20 includes at least one storage element 22, and the storage element 22 is communicatively connected to the processing unit 10 to store data of the processing unit 10.

Wherein, the storage element 22 may be implemented as a hard disk, an optical drive, a memory, or a combination of one or more.

Wherein, the energy supply element 21 is energetically connected to the second connection piece 3141, and the energy supply element 21 provides energy through the second connection piece 3141. When the first connecting piece 15 and the second connecting piece 3141 of the processing unit 30 are connected, the first connecting piece 15 is connected to the energy supply element 21 through the second connecting piece 3141, and the The energy provided by the energy supply element 21 enters the first connecting member 15 through the second connecting member 3141.

The storage element 22 is communicatively connected to the second connector 3141. When the processing unit 10 is installed in the support channel 3100, the first connector 15 and the second connector 3141 are in communication data transmission. The processing unit 10 communicates with the storage element 22 through the communication of the first connection piece 15 and the second connection piece 3141, and the processing unit 10 and the storage element 22 are communicatively connected to each other for data processing. Transmission, the processing unit 10 stores data to the storage element 22, and the processing unit 10 obtains data from the storage element 22.

In other words, the processing unit 10 forms an energy connection and a data connection with the auxiliary processing unit 20 through the connection of the first connection 15 and the second connection 313.

The second connecting members 3141 located in the supporting channels 3100 communicate with each other. When each second connecting member 3141 is connected to the first connecting member 15 of the installed processing unit 10, each The processing units 10 are connected to each other, and data is transmitted between the processing units 10.

In other words, after the processing units 10 are installed in the supporting channel 3100, the processing units 10 can transmit data to each other.

Each of the second connecting members 3141 is independently connected to the auxiliary processing unit 20, so that each of the processing units 10 installed from the supporting channel 3100 is connected to the auxiliary processing unit 20 independently.

Each of the second connecting members 3141 is independently connected to the energy supply element 21, so that the energy supply element 21 supplies energy to the processing unit 10 through each of the second connecting members 3141. Each of the second connecting members 3141 is independently connected to the storage element 22, so that each of the storage elements 22 is connected to the processing unit 10 through each of the second connecting members 3141 to form a data path.

Each of the processing units 10 is independently connected to the storage element 22 through the connection of each of the first connecting pieces 15 and each of the second connecting pieces 3141.

The auxiliary processing unit 20 further includes a network control element 23, and the network control element 23 is installed in the auxiliary space 3400 in the housing 30. The network control element 23 is communicatively connected to each of the second connectors 3141. When the second connector 3141 is connected to the first connector 15 of the processing unit 10, the network control element 23 communicates The ground is connected to the processing unit 10. The network control element 23 is communicatively connected to each of the processing units 10 installed in the supporting channel 3100. When the network control element 23 is activated, the network control element 23 provides a network for each processing unit 10 so that each processing unit 10 is located in a communication network. The processing units 10 communicate with each other. Each of the processing units 10 communicates with other equipment outside the processing device through a communication network.

The network control element 23 is connected to the storage element 22 to provide a network for the storage element 22. When the network control element 23 is activated, the storage element 22 and each of the processing units 10 are located in the communication network, between each of the processing units 10, and between each of the processing units 10 and the storage element 22. data transmission. The data path is formed.

Wherein, the communication unit 16 of the processing unit 10 is connected to the network control element 23 through the connection of the first connector 15 and the second connector 3141. The communication unit 16 obtains a communication network from the network control element 23. The sub-processing unit 14 communicates with the other sub-processing unit 14 and the sub-processing unit 14 of the other processing unit 10 through the communication unit 16. Wherein, when each of the processing units 10 is installed in the supporting channel 3100, the first connecting members 15 are in communication with each other.

When the processing unit 10 is installed in the supporting channel 3100, the first connecting member 15 and the second connecting member 3141 are connected, and the first connecting member 15 and the second connecting member 15 of the other processing units 10 are connected to each other. The two connecting parts 3141 enable the processing unit 10 to be connected with other processing units 10 for communication and data transmission. Each of the processing units 10 is connected to the other processing units 10 through the connection body 314 to perform communication and data transmission.

The auxiliary processing unit 20 further includes at least one heat dissipation element 24, the heat dissipation element 24 is installed in the auxiliary portion 34, and the heat dissipation element 24 provides heat dissipation for the processing unit 10. The heat dissipation element 24 is installed on the rear wall 312 of the housing base 31, one side of the heat dissipation element 24 faces the auxiliary space 3400, and one side of the heat dissipation element 24 faces the housing 30 The heat dissipation element 24 communicates with the auxiliary space 3400 and the outer side of the housing 30. Air circulates between the auxiliary space 3400 and the outer space of the housing 30 through the heat dissipation element 24.

It is worth mentioning that the height of the connecting body 314 is lower than the height of the side wall 313 of the housing base 32, so that the heat dissipation channel 3120 and the auxiliary space 3400 are connected, and the heat dissipation channel 3120 is The air is communicated with the space outside the housing 30 through the auxiliary space 3400 and the heat dissipation element 24.

When the sub-processing unit 14 performs data processing, the sub-processing unit 14 generates heat so that the air at the heat dissipation channel 3120 is heated, wherein the through hole 120 of the mounting side wall 12 communicates with the heat dissipation channel 3120 As well as the air outside the mounting side wall 12, the air at the heat dissipation channel 3120 circulates to the outside through the through hole 120 when heated, for heat dissipation. The heat dissipation element 24 assists air to flow outward from the heat dissipation channel 3120 through the through hole 120. The air at the heat dissipation channel 3120 enters the auxiliary space 3400 and is discharged to the outside of the housing 30 through the heat dissipation element 24. The heat dissipation element 24 provides heat dissipation assistance for the air at the heat dissipation channel 3120.

After the inner cavity of the housing 30 is occupied by the processing unit 10, the auxiliary processing unit 20, and the connecting body 314, the remaining space communicates with each other to provide air circulation and facilitate heat dissipation. The processing unit 10 is installed to the processing device and occupies a part of the space of the support channel 3100, and the heat dissipation channel 3120 is formed between the processing unit 10 and the inner wall 3111 of the support channel 3100. There is a certain space interval between one end of the connecting body 314 and the cover 32. One end of the heat dissipation channel 3120 communicates with the through hole 120 of the installation side wall 12 of the processing unit 10, and the heat dissipation channel 3120 communicates with the outside through the through hole 120. The other end of the heat dissipation channel 3120 communicates with the auxiliary space 3400 through the space between the connecting body 314 and the cover 32. The heat generated during the operation of the processing unit 10 flows outward from the heat dissipation channel 3120, and the heat at the heat dissipation channel 3120 can be discharged to the outside through the through hole 120, or through the connection body 314 and the The space between the covers 32 flows into the auxiliary space 3400 and exits the housing 30 through the heat dissipation element 24.

The cover body 32 includes a cover body 321 and two cover body side walls 322, and each cover body side wall 322 extends vertically from two ends of the cover body 321. The size of the side wall 322 of the cover is suitable for the size of the side wall 313 of the housing base 31. The front wall 311, the two side walls 312 and the rear wall 313 surround the opening of the housing base 31. The cover body 321 is suitable for covering the opening of the housing base 31.

Wherein, the cover side wall 322 is provided with at least one vent, and the side wall 313 of the housing base 31 is provided with at least one vent. When the cover 32 is installed on the housing In the base 31, the side wall 322 of the cover body communicates with the vent of the side wall 313, and communicates with the heat dissipation channel 3120 for heat dissipation. The heat in the inner cavity of the casing 30 can also be discharged to the casing 30 through the vents of the side wall 322 of the cover body and the side wall 313 of the casing base 31.

In other words, the side wall 322 and the side wall 313 of the cover body are respectively provided with the vents for ventilation. The rear wall 312 of the housing base is provided with at least one vent for ventilation.

Each of the processing units 10 is detachably connected to the housing 30. When at least one processing unit 10 is installed in the housing 30 and communicates with the auxiliary processing unit 20, the processing device operates.

It is worth mentioning that the housing 30 further includes one or more interfaces 35, the interfaces 35 are arranged on the outside of the housing 30, and the processing device is connected to other devices through the interfaces 35. The interface 35 is implemented as a combination of one or more of USB interface, DisplayPort (display interface), VGA (Video Graphics Array, video graphics array) interface, network management interface, serial port, etc. The type and number of the interfaces 35 are not limited.

As shown in FIG. 4, the auxiliary part 34 is provided with at least one management unit 10', and the management unit 10' is connected to each of the second connectors 3141, and the management unit 10' and the auxiliary processing unit 20 Connected to each other, the auxiliary processing unit 20 provides processing assistance to the management unit 10'. In other words, the processing device includes the management unit 10'. When the processing unit 10 is installed in the processing device, the management unit 10' is connected to the processing unit 10 to manage the processing unit 10 .

Wherein, the energy supply element 21 is energetically connected to the management unit 10' to provide energy for the management unit 10'. The storage element 22 is communicatively connected to the management unit 10' to perform data transmission with the management unit 10'. The network control element 23 is communicatively connected to the management unit 10', and provides a communication network for the management unit 10'.

The processing unit 10 is detachably mounted on the mounting part 33, and the management unit 10 ′ is communicatively connected to each of the second connectors 3141. When the processing unit 10 is installed in the processing device, that is, the processing unit 10 is connected through the first connecting piece 15 and the second connecting piece 3141, the processing unit 10 and the management unit 10' The connection is made by the connection of the first connecting piece 15 and the second connecting piece 3141. The management unit 10' manages the processing unit 10 installed in the processing device.

As shown in FIG. 7 in a modified embodiment of the present invention, the front wall 312 of the housing 20 is provided with a plurality of the mounting openings 310 distributed in an array. The rear wall 312 of the housing 30 of the processing device may also be provided with the mounting openings 310 distributed in an array. Compared with the processing device disclosed in the foregoing preferred embodiment, the processing device disclosed in this modified embodiment can be provided with the mounting openings 310 on both the front and rear sides, and the mounting openings 310 can be provided from the front and rear sides respectively. The installation opening extends inward to form the inner wall 3111 surrounding the support channel 3100. The processing unit 10 is installed to the support channel 3100 from the installation opening 310 on the front and rear sides, respectively.

The two sides of the connecting body 314 face the processing unit 10 on the front and rear sides, respectively. The auxiliary processing unit 20 is arranged on one side of the connecting body 314. The auxiliary portion 34 and the mounting portion 33 are formed from one side of the connecting body 314 to the rear wall 312 respectively. As shown in FIG. 7, the mounting portion 33 is formed from one side of the connecting body 314 to the upper part of the rear wall 312, and from one side of the connecting body 314 to the lower part of the rear wall 312 The auxiliary part 34 is formed in between. The processing unit 10 and the auxiliary processing unit 20 are mounted to the mounting part 33 and the auxiliary part 34, respectively.

The side of the connecting body 314 facing the rear wall 312 is provided with the second connecting pieces 3141 distributed in an array, and each of the second connecting pieces 3141 respectively faces each of the supporting channels for connecting the processing unit 10.

The mounting portion 33 is formed between the front wall 311 and one side of the connecting main body 314, and the front wall 311 is provided with the mounting openings 310 distributed in an array, and is respectively inward from each of the mounting openings 310 The supporting channel 3100 is extended, and the inner wall 3111 surrounds the supporting channel 3100 distributed in an array. The processing unit 10 is installed in the supporting channel 3100.

It is worth mentioning that, in an example of the present invention, a heat dissipation space is formed between the front wall 311 and the connecting body 314 for heat dissipation. 7, the upper part of the front wall 311 and the connecting body 314 form a completely connected heat dissipation space, the upper part of the front wall 311 is provided with at least one vent, the vent and the The heat dissipation space is connected for heat dissipation. The mounting portion 33 is formed between the lower portion of the front wall 311 and the connecting body 314, and the heat dissipation channel 3120 of the mounting portion 33 communicates with the heat dissipation space. The heat dissipation channel 3120 on the other side of the connecting body 314 communicates with the heat dissipation space through the space between the connecting body 314 and the cover 32. That is to say, the heat dissipation channels 3120 on both sides of the connecting body 314 are connected to the heat dissipation space for heat dissipation.

The mounting portion 33 can be formed between the connecting main body 314 and the front wall 311 for installing the processing unit 10, and the heat dissipation space can also be formed, communicating with the heat dissipation channel 3120 for heat dissipation. The auxiliary part 34 can be formed between the connecting main body 314 and the rear wall 312 for installing the auxiliary processing unit 20, or the auxiliary part 34 and the mounting part 33 can be formed separately for installation. The auxiliary processing unit 20 and the processing unit 10 are described. The processing unit 10 may be installed on the same side of the connection main body 314, or may be installed on the same side of the connection main body 314.

According to another aspect of the present invention, the present invention further provides a hot plugging method. The hot plugging method includes the following steps:

(A) Install the processing unit 10 on the support channel 3100;

(B) Remove the processing unit 10 from the supporting channel 3100.

The processing unit 10 can be removed and installed during the operation of the processing device.

As shown in FIGS. 3 and 8, the present invention provides a processing system 40, wherein the processing device is mounted on the processing system 40, and the processing device performs content processing through the processing system 40. The processing system 40 includes an initial module 41 which is communicatively connected to each of the second connectors 3141 to detect whether the processing unit 10 is connected to the second connector 3141. The initial module 41 detects whether the processing unit 10 and the second connector 3141 are disconnected. When the processing unit 10 and the second connector 3141 are connected, the initial module 41 detects that the processing unit 10 enters the working state, and the initial module 41 selects one of the processing units 10 in the working state As a management unit 10 ′, the management unit 10 ′ manages other processing units 10.

When the processing unit 10 is hot-plugged, the initial module 41 performs initial processing according to the processing unit 10 updated by the hot-plugging. Wherein, the initial module 41 connects the newly added processing unit 10 and the management unit 10 ′, so that the management unit 10 ′ manages the processing unit 10.

The initial module 41 selects the management unit 10 ′ according to the state of each processing unit 10. The processing capability of each processing unit 10 is determined by the performance of each processing unit 10. The management unit 10' manages the remaining processing units 10, and the initial module 41 selects the processing unit 10 with sufficient processing capacity as the management unit 10'.

When the processing unit 10 is installed in the processing device by hot plugging, the initial module 41 detects the performance of the newly added processing unit 10, and when the performance of the processing unit 10 is better than the current management For the performance of the processing unit 10 of the unit 10', the initial module 41 selects the newly added processing unit 10 as the management unit 10'.

The initial module 41 selects the management unit 10' according to the situation of the processing unit 10 to be managed. The initial module 41 analyzes the number and performance of the processing units 10 currently entering the working state, and determines a management value. The initial module 41 accordingly selects the processing unit 10 with sufficient performance as the management unit 10' according to the management value. The performance of the management unit 10' can fully manage the remaining processing units 10.

When the initial module 41 detects the newly added processing unit 10, the initial module 41 detects the performance of the newly added processing unit 10. The initial module 41 generates the new management value. The initial module 41 analyzes the performance of the newly added processing unit 10 and the performance of the management unit 10', and the newly added processing unit 10 and the current processing unit as the management unit 10' From 10, the processing unit 10 that more closely matches the new management value is selected as the management unit 10'.

Further, the initial module 41 selects a sub-processing unit 14 of the processing unit 10 as a sub-management unit 14', and the initial module 41 selects the sub-management unit 14' according to the state of the sub-processing unit 14 . The sub-management unit 14 ′ manages the remaining sub-processing units 14 of the processing unit 10 and the sub-processing units 14 of other processing units 10.

The processing system 40 further includes a management module 42. The management module 42 obtains the management unit 10' from the initial module 41, and the management unit 10' manages the processing units 10 through the management module 42. .

The management unit 10' detects the status and processing conditions of each processing unit 10 entering the working state. That is to say, when the processing unit 10 is installed in the supporting channel 3100, the first connecting piece 15 and the second connecting piece 3141 of the processing unit 10 are connected to obtain energy, a communication network, and enter work. Status, the management unit 10' manages the processing unit 10.

Wherein, the management module 42 monitors each of the processing units 10. The management module 42 can replace the management unit 10' during the operation of the processing device. The management module 42 replaces the processing unit 10 as the management unit 10 ′ according to the state of the processing unit 10, and transfers the responsibilities of the management unit 10 ′ to another processing unit 10.

As shown in FIGS. 10A to 10C, when at least one processing unit 10 is installed in the housing 30, the first connecting member 15 and the second connecting member 3141 are in communication, and the energy supply element 21 is The processing unit 10 provides energy, and the processing unit 10 enters a working state. The processing unit 10 detects at least one task. The processing unit 10 serves as a management unit 10', and the management unit 10' manages the data processing of the processing device.

Wherein, the management unit 10' detects the task, and when no other processing unit 10 is installed in the processing device, the management unit 10' processes the task.

In an example of the present invention, the management unit 10' includes at least two sub-processing units 14, and the sub-processing units 14 process the tasks. One of the sub-processing units 14 of the management unit 10' serves as a management sub-unit to manage data processing, and the other sub-processing unit 14 of the management unit 10' performs data processing. In another embodiment of the present invention, the processing unit 10 includes one sub-processing unit 14, and the sub-processing unit 14 serves as the sub-management unit, that is, the processing unit 10 serves as the management unit 10' , Manage the other processing units 10 and the sub-processing units 14 of the processing unit 10.

When the new processing unit 10 is installed in the processing device, the first connecting member 15 of the processing unit 10 and the second connecting member 3141 of the mounting portion 33 are connected to form a data path and supply Can access. The processing unit 10 obtains energy and data so that the new processing unit 10 enters a working state. The processing unit 10 is connected to the processing unit 10 as the management unit 10' through the second connecting member 3141. The management unit 10 ′ detects that the new processing unit 10 is installed, and the management unit 10 ′ manages the data processing of the processing unit 10. The management unit 10' assigns the task to the processing unit 10 for the processing unit 10 to process.

Wherein, the management unit 10' transmits the task to the processing unit 10 through the data path formed by the second connection 313 and the first connection 15, and the processing unit 10 obtains the task, And deal with it.

When the new processing unit 10 is installed in the processing device, the management unit 10' detects the increase of the processing unit 10, and the management unit 10' allocates the task to be executed to the newly added The processing unit 10.

The management unit 10' detects whether there are newly added processing units 10 and the tasks to be executed. When the management unit 10' detects the newly added processing unit 10, the management unit 10' allocates the task to be processed to the newly added processing unit 10, and the newly added processing unit 10 10 is processed.

It is worth mentioning that when the management unit 10' detects that the processing unit 10 is newly added, and the management unit 10' does not detect the task that needs to be processed, the management unit 10' does not need to perform Task Assignment.

Wherein, the management unit 10' analyzes the working status of each processing unit 10. When the processing unit 10 is not in the state of executing the task, the management unit 10' analyzes that the working state of the processing unit 10 is idle. When the processing unit is in the state of executing the task, the management unit 10 ′ analyzes a remaining processing capacity of the processing unit 10 to process the processing unit 10. Each of the processing units 10 has a corresponding total processing capacity, the management unit 10' allocates the tasks to the processing units 10, and the management unit 10' analyzes and processes the tasks occupied by the processing unit 10 The total processing capacity is the remaining processing capacity of the processing unit.

The management unit 10' allocates the tasks according to the remaining processing capacity of the processing unit 10.

As shown in FIG. 4 in a modified implementation of the above-mentioned preferred embodiment of the present invention, the management unit 10 ′ is fixedly installed in the inner cavity of the housing 30. The management unit 10 ′ is preferably installed in the auxiliary part 34. The auxiliary processing unit 20 is fixedly installed inside the housing 30, the management unit 10' and the auxiliary processing unit 20 are connected to each other, and the auxiliary processing unit 20 provides processing assistance for the management unit 10' . In other words, the processing device includes the management unit 10'. When the processing unit 10 is installed in the processing device, the management unit 10' is connected to the processing unit 10 to manage the processing unit 10 .

The processing unit 10 is detachably mounted on the mounting part 33, and the management unit 10 ′ is communicatively connected to each of the second connectors 3141. When the processing unit 10 is installed in the processing device, that is, the processing unit 10 is connected through the first connecting piece 15 and the second connecting piece 3141, the processing unit 10 and the management unit 10' The connection is made by the connection of the first connecting piece 15 and the second connecting piece 3141. The management unit 10' manages the processing unit 10 installed in the processing device. When the processing unit 10 is hot-plugged, the initial module 41 performs initial processing according to the processing unit 10 updated by the hot-plugging.

Wherein, the initial module 41 connects the newly added processing unit 10 and the management unit 10 ′, so that the management unit 10 ′ manages the processing unit 10. The management unit 10 ′ manages the processing unit 10 through the management module 42. When the new processing unit 10 is installed in the processing device, the first connecting member 15 of the processing unit 10 and the second connecting member 3141 of the mounting portion 33 are connected to form a data path and supply Can access. The processing unit 10 obtains energy and data so that the new processing unit 10 enters a working state. The processing unit 10 is connected to the processing unit 10 as the management unit 10' through the second connecting member 3141. The management unit 10 ′ detects that the new processing unit 10 is installed, and the management unit 10 ′ manages the data processing of the processing unit 10. The management unit 10 ′ assigns the task to the processing unit 10 for processing by the processing unit 10.

11A to 11C show the disassembly and replacement of the processing unit 10.

When the processing unit 10 is damaged, the management unit 10' detects the damage of the processing unit 10, and analyzes that the working state of the processing unit 10 is abnormal.

The management unit 10' detects whether the working state of the installed processing unit 10 is normal. When the processing unit 10 is damaged, the data transmission between the processing unit 10 and the management unit 10' is abnormal, and the management unit 10' detects that the working state of the processing unit is abnormal. When the processing unit 10 stops processing data, the processing unit 10 is in an abnormal working state. The processing unit 10 in an abnormal working state performs dismantling work.

Wherein, since each of the processing units 10 is independently set in the processing device, each of the processing units 10 is independent of each other and does not interfere with each other. When an abnormality occurs in one or some of the processing units 10, the other processing units 10 can continue to work.

In an example of the present invention, each of the processing units 10 stores data to the storage element 22 respectively. Each of the processing units 10 stores the data being processed in the storage element 22 in real time. When the processing unit 10 is damaged, data is stored in the storage element 22. The management unit 10 ′ obtains data of the damaged processing unit 10 from the storage element 22. If the processing unit 10 is performing a task before the damage, the storage element 22 stores the data of the processing unit 10 until the damage, and the data state remains in the state processed when the processing unit 10 is damaged. The management unit 10 ′ obtains data of the damaged processing unit 10 from the storage element 22. The management unit 10' detects the idle processing unit 10, and sends the data of the damaged processing unit 10 to the idle processing unit 10 for data processing.

That is, when the damaged processing unit 10 is performing the task before the damage, the processing unit 10 stores the data of the task being performed to the storage element 22 in real time until the processing unit 10 damage. The data stored in the storage element 22 is the data at the time when the task is processed and the processing unit 10 is damaged. The management unit 10 ′ detects that the processing unit 10 is damaged, and the management unit 10 ′ obtains the data of the executed task stored by the processing unit 10 from the storage element 22. The management unit 10' detects the idle processing unit 10 in the processing unit 10 in the normal working state, and obtains and sends the data of the damaged processing unit 10 from the storage element 22 to the idle processing unit 10 The processing unit 10 is processed by the processing unit 10.

The management unit 10' analyzes the remaining processing capacity of the processing unit 10 that executes the task. The management unit 10' detects that the remaining processing capacity is sufficient to handle the task of the damaged processing unit 10, and the management unit 10' sends the task of the damaged processing unit 10 to the remaining processing The processing unit 10 with sufficient capacity is provided for the processing unit 10 to process the task processed by the damaged processing unit 10.

In another embodiment of the present invention, the management unit 10' obtains the data of the damaged processing unit 10, and transfers the data of the damaged processing unit 10 to another processing unit 10, which is processed by another Unit 10 performs processing.

The management unit 10' transfers the data of the damaged processing unit 10, so that the removal of the damaged processing unit 10 does not affect the security and stability of the data.

In another example of the present invention, the data of each processing unit 10 is stored in the storage element 22. When the processing unit 10 is damaged, the management unit 10' instructs another normally working processing unit 10 Obtain the damaged data of the processing unit 10 from the storage element 22 and perform processing. Wherein, the management unit 10' instructs the idle processing unit 10 to perform data processing, and may also instruct the processing unit 10 with sufficient remaining processing capacity to perform processing.

Since the data of the damaged processing unit 10 is stored or transferred, the processing unit 10 can be directly disassembled. When the processing unit 10 is disassembled, the processing unit 10 is moved outward from the supporting channel 3100, the first connecting piece 15 is disconnected from the second connecting piece 3141, and the processing unit 10 is The connection between the auxiliary processing units 20 is broken. The energy path between the processing unit 10 and the energy supply element 21 is disconnected, and the data path between the processing unit 10 and the storage element 22 is disconnected.

Since each of the processing units 10 is independently connected to the auxiliary processing unit 20, the disassembly of the processing unit 10 does not affect the connection between the other processing units 10 and the auxiliary processing unit 20.

Therefore, disassembling the damaged processing unit 10 does not affect the data processed before the damaged processing unit 10 is damaged, nor does it affect the work of other processing units 10. In other words, the processing unit 10 can be hot-plugged.

After the damaged processing unit 10 is disassembled, the processing unit 10 can be replaced with a new one. The newly replaced processing unit 10 is installed in the empty supporting channel 3100. The first connecting member 15 and the second connecting member 3141 of the processing unit 10 are connected, and the processing unit 10 is connected with the auxiliary processing unit 20. The energy supply element 21 is connected to the first connecting member 15 and the second connecting member 3141 to provide energy for the processing unit 10. The storage element 22 is connected to the processing unit 10 through the first connecting member 15 and the second connecting member 3141 for data transmission. The new processing unit 10 enters the working state.

The first connecting member 15 of the processing unit 10 and the second connecting member 3141 of the mounting portion 33 are connected to form a data path. The processing unit 10 is connected to the processing unit 10 as the management unit 10' through the second connecting member 3141. The management unit 10 ′ detects that the new processing unit 10 is installed, and the management unit 10 ′ manages the data processing of the processing unit 10. The management unit 10 ′ assigns the task to the processing unit 10 for the processing unit 10 to perform processing.

Each of the sub-processing units 14 of the processing unit 10 is independently connected to the first connecting member 15, and the sub-processing units 14 are respectively realized by the first connecting member 15 and the second connecting member 3141 Connected. Each of the sub-processing units 14 of the processing unit 10 is connected to the auxiliary processing unit 20 through the connection of the first connection member 15 and the second connection 313 respectively. The energy supply element 21 is connected to each of the sub-processing units 14 through the connection of the first connector 15 and the second connection 313 to form an energy channel. The energy supply element 21 supplies energy for each of the sub-processing units 14 respectively. The storage element 22 respectively forms a data path between each of the sub-processing units 14 through the connection of the first connection member 15 and the second connection 313. The storage element 22 performs data transmission with each of the sub-processing units 14 respectively.

It is worth mentioning that the sub-processing units 14 are independently connected to the first connecting member 15 through the communication unit 16 respectively.

The sub-processing unit 14 of the processing unit 10 forms a data path with the other processing units 10 and the sub-processing units 14 through the connection of the first connector 15 and the second connection 313, respectively , So that the sub-processing units 14 between different processing units 10 can perform data transmission.

The sub-processing units 14 of the same processing unit 10 are communicatively connected to each other. In other words, data transmission can be performed between the sub-processing units 14 of the same processing unit 10.

According to another aspect of the present invention, the present invention further provides a management method, which includes the following steps:

S1: Select a processing unit 10 as the management unit 10';

S2: Detect the state of the processing unit 10;

S3: Assign the task.

12A to 12B show the disassembly and replacement of the sub-processing unit 14 of the processing unit 10.

When a part of the sub-processing unit 14 of the processing unit 10 fails, the sub-processing unit 14 and when the sub-processing unit 14 of the processing unit 10 is faulty or damaged, the processing unit is hot-plugged. Unit 10, the sub-processing unit 14 is replaced.

In an embodiment of the present invention, each of the sub-processing units 14 stores data in the storage element 22 respectively. Each of the sub-processing units 14 stores the data being processed in the storage element 22 in real time. When the sub-processing unit 14 is damaged, data is stored in the storage element 22. The management unit 10 ′ obtains the damaged data of the sub-processing unit 14 from the storage element 22. If the sub-processing unit 14 is performing a task before the damage, the storage element 22 stores the data of the sub-processing unit 14 until the damage, and the data state remains in the state processed when the sub-processing unit 14 is damaged. The management unit 10 ′ obtains the damaged data of the sub-processing unit 14 from the storage element 22. The management unit 10' detects the idle sub-processing unit 14, and sends the data of the damaged sub-processing unit 14 to the idle sub-processing unit 14 for data processing.

Wherein, to disassemble the damaged sub-processing unit 14, the processing unit 10 needs to be disassembled first. The processing unit 10 needs to be moved out of the supporting channel 3100 to expose the damaged sub-processing unit 14. The data of the processing unit 10 is stored in the storage element 22 and redistributed by the management unit 10'.

When the damaged sub-processing unit 14 is performing the task before it is damaged, the sub-processing unit 14 stores the data of the task being performed in the storage element 22 in real time until the sub-processing unit 14 is damaged . The data stored in the storage element 22 is the data at the time when the task is processed and the sub-processing unit 14 is damaged. The management unit 10 ′ detects that the sub-processing unit 14 is damaged, and the management unit 10 ′ obtains the data of the executed task stored by the sub-processing unit 14 from the storage element 22. The management unit 10' detects the idle processing unit 10 in the processing unit 10 in the normal working state, and obtains the data of the damaged sub-processing unit 14 from the storage element 22 and sends it to the idle The processing unit 10 is processed by the processing unit 10.

In another embodiment of the present invention, the management unit 10' detects the idle sub-processing unit 14 among the other processing units 10 in a normal working state, and the idle sub-processing unit 14 continues processing .

The management unit 10' analyzes the remaining processing capacity of the sub-processing unit 14 that executes the task. The management unit 10' detects that the remaining processing capacity is sufficient to handle the task of the damaged sub-processing unit 14, and the management unit 10' sends the task of the damaged sub-processing unit 14 to the The sub-processing unit 14 with sufficient remaining processing capacity is used for the sub-processing unit 14 to process the task processed by the damaged sub-processing unit 14.

In another example of the present invention, the management unit 10' obtains the data of the damaged sub-processing unit 14, and transfers the damaged data of the sub-processing unit 14 to another processing unit 10, and the other The processing unit 10 performs processing.

The management unit 10' transfers the data of the damaged sub-processing unit 14 so that the removal of the damaged sub-processing unit 14 does not affect the security and stability of the data.

In another example of the present invention, the data of each sub-processing unit 14 is stored in the storage element 22. When the sub-processing unit 14 is damaged, the management unit 10' instructs another normally working The processing unit 10 obtains the damaged data of the sub-processing unit 14 from the storage element 22 and performs processing. Wherein, the management unit 10' instructs the idle processing unit 10 to perform data processing, and may also instruct the processing unit 10 with sufficient remaining processing capacity to perform processing.

Since the damaged data of the sub-processing unit 14 is stored or transferred, the sub-processing unit 14 can be directly disassembled. When disassembling the sub-processing unit 14, the processing unit 10 is first moved outward from the supporting channel 3100, the first connecting member 15 and the second connecting member 3141 are disconnected, and the processing unit 10 and The connection between the auxiliary processing units 20 is broken. The energy path between the processing unit 10 and the energy supply element 21 is disconnected, and the data path between the processing unit 10 and the storage element 22 is disconnected. Then the sub-processing unit 14 is removed from the processing unit 10, and the connection between the sub-processing unit 14 and the processing unit 10 is disconnected.

Since each of the processing units 10 and each of the auxiliary processing units 20 are respectively and independently connected, and each of the sub-processing units 14 are respectively connected to the auxiliary processing unit 20, the disassembly of the sub-processing units 14 does not affect Other connections between the sub-processing unit 14 and the auxiliary processing unit 20.

Therefore, disassembly of the damaged sub-processing unit 14 does not affect the data processed before the damaged sub-processing unit 14 is damaged, nor does it affect the work of other processing units 10. In other words, the sub-processing unit 14 can be hot-plugged.

The sub-processing unit 14 and the other sub-processing units 14 of the same processing unit 10 are separately connected to the first connecting member 15, so the disassembly of the sub-processing unit 14 does not affect other sub-processing units of the same processing unit 10. The sub-processing unit 14 is connected to the first connecting member 15.

After the damaged sub-processing unit 14 is disassembled, the sub-processing unit 14 can be replaced with a new one. The newly replaced sub-processing unit 14 is installed in the processing unit 10, and the processing unit 10 is continuously installed to the supporting channel 3100, and the processing unit 10 can continue to work. The first connecting member 15 and the second connecting member 3141 of the processing unit 10 are connected, and the processing unit 10 is connected with the auxiliary processing unit 20. The energy supply element 21 is connected to the first connecting member 15 and the second connecting member 3141 to provide energy for the processing unit 10. The storage element 22 is connected to the processing unit 10 through the first connecting member 15 and the second connecting member 3141 for data transmission. The processing unit 10 enters the working state.

Wherein, the replaced sub-processing unit 14 is connected to the auxiliary processing unit 20 through the first connecting member 15 and the second connecting member 3141. The replaced sub-processing unit 14 is connected to the energy supply element 21 through the connection of the first connector 15 and the second connector 3141 to obtain energy. The replaced sub-processing unit 14 is connected to the storage element 21 through the first connecting piece 15 and the second connecting piece 3141.

The sub-processing unit 14 communicates with the second connecting member 3141 of the mounting portion 33 through the first connecting member 15 to form a data path. The sub-processing unit 14 is connected to the processing unit 10 serving as the management unit 10' through the second connecting member 3141. The management unit 10' detects that the new sub-processing unit 14 is installed, and the management unit 10' manages the data processing of the sub-processing unit 14. The management unit 10 ′ assigns the task to the sub-processing unit 14 for processing by the sub-processing unit 14.

The processing unit 10 in a normal working state needs to be replaced. The processing unit 10 sends the data of the task being executed to the management unit 10', and the processing unit 10 can be replaced. When the processing unit 10 is disassembled, the first connector 15 and the second connector 3141 are disconnected, the connection between the processing unit 10 and the auxiliary processing unit 20 is disconnected, and the processing Unit 10 stops working. Since the data of the processing unit 10 is transferred before the processing unit 10 is disassembled, the disassembly of the processing unit 10 does not affect the security and stability of the data.

In another embodiment of the present invention, the processing unit 10 in a normal working state stores data to the storage element 22, and when the processing unit 10 is detached, the management unit 10' removes data from the storage element 22. 22 Acquire the data of the disassembled processing unit 10, and transfer the data to another processing unit 10 that is working normally.

In another embodiment of the present invention, the processing unit 10 in a normal working state stores data in the storage element 22, and when the processing unit 10 is disassembled, the management unit 10' indicates another normal working The processing unit 10 obtains the data of the disassembled processing unit 10 from the storage element 212 and performs processing. Wherein, the management unit 10' instructs the idle processing unit 10 to perform data processing, and may also instruct the processing unit 10 with sufficient remaining processing capacity to perform processing.

Similarly, the sub-processing unit 14 can also be replaced by hot plugging. The replacement of the sub-processing unit 14 does not affect the normal operation of the other processing units 10.

The processing device further includes a task management module 40 which is communicatively connected to each of the processing units 10 to manage the processing of the tasks by each of the processing units 10.

It is worth mentioning that each of the processing units 10 can be used as the management unit 10 ′ to manage other processing units 10.

As shown in FIG. 13, in another modified implementation of the above preferred embodiment of the present invention, the processing unit 10 is implemented as at least one initial processing unit 101 and at least one expansion processing unit 102. The processing unit 10 includes at least one initial processing unit 101 and at least one expansion processing unit 102. The initial processing unit 101 is fixedly mounted on the mounting portion 33 of the housing 30, the auxiliary processing unit 20 is fixedly mounted on the inner side of the housing 30, and the initial processing unit 101 and the auxiliary The processing units 20 are connected to each other, and the auxiliary processing unit 20 provides processing assistance for the initial processing unit 101.

Wherein, the energy supply element 21 is energetically connected to the initial processing unit 101 to provide energy for the initial processing unit 101. The storage element 22 is communicatively connected to the initial processing unit 101 to perform data transmission with the initial processing unit 101.

The supporting channel 3100 is formed in the mounting portion 33 for installing the expansion processing unit 102, the expansion processing unit 102 is installed in the supporting channel 3100, and the expansion processing unit 102 and the auxiliary processing unit 20 are connected The auxiliary processing unit 20 provides processing assistance for the extended processing unit 102.

Wherein, the initial processing unit 101 is installed in the housing 30 in the initial state of the processing device, and is fixedly connected to the auxiliary processing unit 20. When the initial processing unit 101 passes the auxiliary processing The unit 20 obtains energy, and the initial processing unit 101 can enter the working state in the initial state of the processing device.

The initial processing unit 101 serves as a management unit 10' to manage data processing. The initial processing unit 101 detects whether the expansion processing unit 102 is installed in the processing device. The initial processing unit 101 detects whether there is a task to be processed.

The processing device expands the processing capability of the processing device by installing the expansion processing unit 102. The expansion processing unit 102 is installed on the supporting channel 3100, the first connecting piece 15 of the expanding processing unit 102 and the second connecting piece 3141 on the inner wall 3111 around the supporting channel 3100 connection. Wherein, the second connecting member 3141 is connected to the auxiliary processing unit 20. The auxiliary processing unit 20 provides assistance to the expansion processing unit 102 through the second connecting member 3141.

The initial processing unit 101 and the extended processing unit 102 are respectively and independently connected to the auxiliary processing unit 20, and the installation and disassembly of the extended processing unit 102 does not affect the work of the initial processing unit 102.

The expansion processing unit 102 is installed in the supporting channel 3100, the first connecting member 15 and the second connecting member 3141 are connected, and a connection is formed between the expansion processing unit 102 and the auxiliary processing unit 20 The energy supply element 21 provides energy to the expansion processing unit 102 through the connection of the first connecting member 15 and the second connecting member 3141. The storage element 22 performs data transmission with the expansion processing unit 102 through the connection of the first connector 15 and the second connector 3141.

The expansion processing unit 102 is installed to the support channel 3100, and the heat dissipation channel 3120 is formed between the expansion processing unit 102 and the inner wall 3111. The heat dissipation channel 3120 communicates with the auxiliary space 3400 where the auxiliary processing unit 20 is located. The heat dissipation element 24 faces the heat dissipation channel 3120 to provide assistance for heat dissipation.

The initial processing unit 101 serves as the management unit 10 ′, and assigns the task to the extended processing unit 102 for processing by the extended processing unit 102. It is worth mentioning that the management unit 10' switches between the initial processing unit 101 and the expansion processing unit 102. The extension processing unit 102 serves as the management unit 10', and assigns the task to the initial processing unit 101 and other extension processing units 102 for processing.

The sub-processing unit 14 may be implemented as a chip. There are many types of chips, and different types of chips are suitable for processing different types of data. When the management unit 10' detects the type of data to be processed by the task, the management unit 10' has the data type and replaces the chip of the sub-processing unit 14 of the processing unit 10 by hot swapping to improve the corresponding type The chip processes the data.

When the processing unit 10 is processing at least one task, the management unit 10' analyzes that the processing unit 10 is in a normal working state. When the processing unit 10 does not process the task, the management unit 10' analyzes that the processing unit 10 is in an idle working state. When the connection between the management unit 10' and the processing unit 10 is not smooth or disconnected, the management unit 10' cannot normally detect the state of the processing unit 10, and the management unit 10' analyzes the processing The unit 10 is in an abnormal working state. The management unit 10' maintains a normal working state. When the management unit 10' fails, the management module 42 replaces the other processing unit 10 as the management unit 10'.

The processing device processes at least one content library, and the content library is used to generate at least one content. The management unit 10' distributes the content library to each of the processing units 10, and the processing unit 10 processes the content library. It is worth mentioning that the management unit 10' distributes the same content Libraries are allocated to different processing units 10 so that different processing units 10 generate the same content, and the management unit 10 ′ allocates different content libraries to different processing units 10. Different processing units 10 process different contents. The management unit 10' allocates multiple content libraries to each processing unit 10, so that different processing units 10 produce the same content and different content.

As shown in FIG. 14, at least one client 50 sends a content request to the processing device. The processing device receives the content request. The management unit 10' receives the content request, and analyzes the content requested by the content request. The management unit 10' generates the task according to the content requested by the content request. The management unit 10 ′ selects the idle processing unit 10 and assigns the task to the selected processing unit 10. It is worth mentioning that the processing unit 10 is equipped with the content library that generates the content requested by the content request. The management unit 10' selects the idle processing unit 10 among the processing units 10 capable of generating the content to process the task. When the task of the content request of the client 50 is allocated to the processing unit 10 by the management unit 10', the processing unit 10 is connected to the client 50. When the processing unit 10 processes the task and generates the content, the processing unit 10 sends the content to the client 50.

The processing unit 10 processes the content library and generates the content. The processing unit 10 further processes the content into a set of content units, the processing unit 10 performs stream processing on the content units, processes the content unit streams into at least one content stream, and the processing unit 10 processes The content is streamed to the client 50, and the client 50 plays the content stream to form the content.

The processing unit 10 processes the content into the content unit, and transmits it in the form of the content stream, reduces the amount of content transmission data per unit time and the data received by the client 10, and guarantees the processing unit The data transmission speed between 10 and the client 50 and the receiving speed of the client 10 enable the client 50 to keep the content playing, reducing or eliminating content delay.

It is worth mentioning that the processing unit 10 processes the content according to the environment of the client 10. The processing unit 10 selects the specifications and transmission speed of the content unit according to the transmission environment and the playback environment. The processing unit 10 generates the content unit and transmits the content unit according to the environment, so that the transmission and playback of the content unit adapt to environmental changes, thereby controlling content delay.

The processing unit 10 streams the content to the client 50, and the user obtains the content through the client 50. Among them, the user can interact with the content. At least one operation generated by the user during the interaction with the content is sent by the client 50 to the processing unit 10. The processing unit 10 processes the content library to generate the content requested by the operation.

After the processing unit 10 and the client 50 are connected to each other, the processing of the content by the client 50 is carried out by the processing unit 10 until there is a connection between the client 50 and the processing unit 10 Disconnect.

When multiple clients 50 request the content, the management unit 10' receives the content request sent by each client 50, and allocates the processing unit 10 to each client 50, so that all The processing unit 10 and the client 50 are connected to each other, and the processing unit 10 processes the content request of the client 50.

When the management unit 10' allocates the content library to the processing unit 10, the processing unit 10 processes the content library. The processing unit 10 includes at least one sub-processing unit 14, and the sub-processing unit processes data of the content library. The processing unit 10 includes at least two sub-processing units 14, one of the sub-processing units 14 is implemented as a communication unit 14 ′ for communicating with the other processing units 10 and the sub-processing units 14. The communication unit 14 ′ provides communication between the sub-processing unit 14 and the sub-processing units 14 of the other processing units 10.

In another embodiment of the present invention, the management unit 10 ′ allocates the content library to each of the sub-processing units 14 of each of the processing units 10. Each of the sub-processing units 14 processes the content library. When the client 50 requests the content, the content request is issued. The management unit 10' generates the task. The management unit 10' allocates the task to the idle sub-processing unit 14, so that the sub-processing unit 14 is connected to the client 50, and the sub-processing unit 14 serves as the client 50 provides the content.

According to another aspect of the present invention, the present invention further provides a processing method, which includes the following steps:

S1: Select a processing unit 10 as the management unit 10';

S2: Produce the task according to the content request sent by the client 50;

S3: Allocate the task to the processing unit 10;

S3: Process the content library and produce the content;

S4: Process the content into a set of content units;

S5: Streaming the content unit.

Those skilled in the art should understand that the above description and the embodiments of the present invention shown in the accompanying drawings are only examples and do not limit the present invention. The purpose of the present invention has been completely and effectively achieved. The functions and structural principles of the present invention have been shown and explained in the embodiments. Without departing from the principles, the embodiments of the present invention may have any deformation or modification.

Claims

A processing device, characterized in that it comprises:

At least one processing unit;

An auxiliary processing unit; and

A housing, wherein the processing unit is installed inside the housing, and the auxiliary processing unit is installed inside the housing, wherein the processing unit and the auxiliary processing unit are connected to enter a working state .
The processing device according to claim 1, wherein the processing unit includes a base and a mounting side wall, the mounting side wall is fixed to the base, and the mounting side wall is formed by extending vertically from one end of the base.
3. The processing device according to claim 2, wherein the processing unit comprises at least one sub-processing unit, and the sub-processing unit is detachably mounted on the base.
3. The processing device according to claim 3, wherein the processing unit comprises at least one first connecting member, and the first connecting member is arranged on a side of the base opposite to the mounting side wall, and the sub The processing unit is connected to the first connector.
4. The processing device according to claim 4, wherein the processing unit comprises a holding member, and the holding member is installed on the outer side of the installation side wall.
The processing device according to claim 5, wherein the housing includes a housing base and a cover, and the cover covers the housing base, wherein the housing base includes a front wall, and the front The wall is provided with one or more installation openings, the periphery of the installation opening extends to the inner side of the housing to form an inner wall, and the inner wall surrounds to form a supporting channel.
The processing device according to claim 6, wherein the processing element is installed in the supporting channel.
7. The processing device according to claim 7, wherein the housing base includes at least one connecting body formed between two side walls of the housing base, the processing unit and the auxiliary processing unit Are respectively installed on both sides of the connecting body, wherein the connecting body is provided with at least one second connecting piece, and the second connecting piece faces the supporting channel.
8. The processing device according to claim 8, wherein the auxiliary processing unit is connected to each of the second connecting members, and the processing unit and the auxiliary processing unit pass through the first connecting member and the second connecting member The processing unit enters the working state.
The processing device according to claim 9, wherein the housing includes a mounting portion and an auxiliary portion, the mounting portion and the auxiliary portion are respectively formed on both sides of the connecting body, wherein the processing unit is Installed on the installation part, the auxiliary part has an auxiliary space, and the auxiliary processing unit is installed in the auxiliary space.
The processing device according to claim 10, wherein the auxiliary processing unit comprises at least one energy supply element, the energy supply element is energably connected to the second connector, and the processing unit is installed in the Supporting the channel, the processing unit obtains energy from the energy supply element through the connection of the first connection member and the second connection.
11. The processing device according to claim 11, wherein the auxiliary processing unit includes at least one storage element, the storage element is connected to the second connecting member, the processing unit is installed in the supporting channel, and the processing The unit performs data transmission with the storage element through the connection of the first connector and the second connection, wherein the processing unit stores data in the storage element.
The processing device according to claim 12, wherein the auxiliary processing unit comprises at least one network control element, the network control element is connected to the second connecting member, the processing unit is installed in the supporting channel, and The network control element provides a communication network for the processing unit through the connection of the first connector and the second connection.
11. The processing device according to claim 11, wherein the processing unit is installed in the support channel, a heat dissipation channel is formed between the base and the inner wall, and the heat dissipation channel is in communication with the auxiliary space.
The processing device according to claim 14, wherein the auxiliary processing unit comprises at least one heat dissipation element, the heat dissipation element is installed in the auxiliary space, and the communication between the auxiliary space and the heat dissipation channel is the processing The unit provides heat dissipation.
The processing device according to claim 9, further equipped with a processing system, said processing system being communicatively connected to said processing device for content processing, wherein said processing system comprises:

An initial module, the initial module is communicatively connected to the second connecting member to detect whether the processing unit is installed and disassembled, wherein the initial module selects a processing unit from the processing unit as a Management unit; and

A management module, the management module is communicatively connected to the initial module to obtain the management unit, and the management unit manages the other processing units through the management module.
The processing device according to claim 16, wherein the initial module detects the performance of the processing unit in a working state and generates a management value, and the initial module selects the processing unit as the management value according to the management value. Unit, wherein the performance of the management unit is adapted to the management value.
The processing device according to claim 10, further comprising at least one management unit installed in the auxiliary part, and the management unit is communicatively connected to the auxiliary processing unit so that the auxiliary processing unit assists The management unit performs processing, and the management unit is communicatively connected to the second connector, and is detachably connected to the processing unit through the second connector.
The processing device according to any one of claims 17 or 18, wherein the management unit monitors whether the working status of each processing unit is normal, and when the processing unit is processing at least one task, the processing unit is in normal work State, when the processing unit stops processing data, the processing unit is in an abnormal working state, and when the processing unit does not process data, the processing unit is in an idle working state.
The processing device according to claim 19, wherein the processing unit stores data in the storage element in real time, and when the management unit detects that the processing unit is in an abnormal working state, the management unit receives data from the storage The component acquires the data of the processing unit and assigns the data to another processing unit.
The processing device according to claim 19, wherein the management unit acquires data of the processing unit in an abnormal working state, and transfers the data to another processing unit in a normal working state for processing.
The processing device according to claim 19, wherein the management unit analyzes a remaining processing capacity of the processing unit in a normal working state, and the management unit assigns the task to the sufficient remaining processing capacity. Processing unit.
The processing device according to claim 19, wherein the management unit assigns the task to the idle processing unit.
The processing device according to claim 19, wherein the management unit receives at least one content request sent by at least one client, wherein the content request requests at least one content, and the management unit generates the content request as a task The management unit assigns the task to the processing unit, the processing unit is connected to the client, and the processing unit processes the task to produce the content requested by the client.
23. The processing device according to claim 23, wherein the processing unit processes the content into a set of content units, and the processing unit transmits the content units to the client in the form of a content stream, and the client plays The content stream forms the content.
The processing unit according to claim 1, wherein the processing unit includes at least one sub-processing unit connected to the auxiliary processing unit to enter a working state, wherein the sub-processing unit serves as a management sub-unit The unit manages the other processing units and the sub-processing units.
The processing unit according to claim 1, wherein the processing unit includes at least two sub-processing units connected to the auxiliary processing unit to enter a working state, and one of the sub-processing units serves as a management sub-unit The unit manages the other processing units and the sub-processing units, and the other sub-processing unit performs data processing.
A processing method, characterized in that it comprises the following steps:

(A) Select a processing unit as a management unit;

(B) Assign the task to the processing unit;

(C) Generate at least one content;
The method according to claim 28, wherein between said step (A) and said step (B) further comprises the following steps:

At least one content request sent by at least one client is generated at least one task.
The method according to claim 28, further comprising the following steps:

Processing the content into a set of content units;

Stream the content unit to the client.
A processing device, characterized in that it comprises:

At least one processing unit;

An auxiliary processing unit; and

A housing, wherein the processing unit and the auxiliary processing unit are respectively mounted to the inner cavity of the housing, and the processing unit is detachably connected to the auxiliary processing unit.
The processing device according to claim 31, wherein the processing unit comprises:

A base

A mounting side wall, the mounting side wall extending vertically from one end of the base;

A holding piece, the holding piece is installed on the outside of the installation side wall;

At least one sub-processing unit, the sub-processing unit being detachably mounted on the base; and

At least one first connecting member, the first connecting member extending outwardly from the side wall of the base, wherein the sub-processing unit is connected to the first connecting member.
The processing device according to claim 31, wherein the housing includes a housing base, and the processing unit and the auxiliary processing unit are respectively mounted on the housing base, wherein the housing base includes a front The front wall is provided with at least one installation opening, the periphery of the installation opening extends toward the inner side of the housing to form an inner wall, the inner wall surrounds and forms a support channel, and the processing unit is detachably installed in The support channel.
The processing device according to claim 33, wherein the housing base includes at least one connecting body, both ends of the connecting body extend to two side walls of the housing base, and both sides of the connecting body face respectively The front wall of the housing base and the rear wall of the housing base form a mounting portion from the front wall to the connecting body, and the processing unit is detachably mounted on the mounting portion, An auxiliary part is formed from the rear wall to the connecting body, and the auxiliary processing unit is installed on the auxiliary part.
The processing device according to claim 34, wherein the connecting body is provided with one or more second connecting members, and one side of each second connecting member faces each of the supporting channels.
The processing device according to claim 35, wherein the processing unit is installed in the supporting channel through the installation opening, and the first connecting member and the second connecting member are detachably connected.
The processing device according to claim 36, wherein the auxiliary processing unit is connected to the second connecting member, and the processing unit is connected to the auxiliary processing unit through the connection of the first connecting member and the second connecting member. Unit connection.
The processing device according to claim 36, wherein a heat dissipation channel is formed between the base and the inner wall of the processing unit.
The processing device according to claim 38, wherein the auxiliary processing unit further comprises at least one heat dissipation element, and the heat dissipation element is disposed in an auxiliary space on the other side of the connecting body with respect to the processing unit, wherein The auxiliary space communicates with the heat dissipation channel.
The processing device according to claim 44, wherein the housing further comprises a cover body covering the housing base, wherein the cover body has two cover body side walls, each of the cover body side The wall and each side wall of the housing base are respectively provided with at least one vent.
The processing device according to claim 48, wherein the installation side wall of the processing unit is provided with at least one through hole, and the through hole communicates with the heat dissipation channel.
The processing device according to claim 42, wherein the processing unit comprises a plurality of the sub-processing units, each of the sub-processing units is detachably mounted on the base, and each of the sub-processing units is independent Ground is connected to the first connecting piece, and each of the sub-processing units is connected to the auxiliary processing unit through the second connecting piece.
The processing device according to claim 31, wherein the auxiliary processing unit comprises:

At least one energy supply element, the energy supply element is arranged on the auxiliary part, and each of the second connecting members is respectively connected to the energy supply element;

At least one storage element, the storage element is disposed on the auxiliary part, and each of the second connecting members is respectively connected to the storage element; and

At least one network control element, the network control element is arranged in the auxiliary part, and each of the second connectors is respectively connected to the network control element element.
A processing device, characterized in that it comprises:

At least one processing unit;

An auxiliary processing unit; and

A housing, wherein the housing includes a connecting body, and the processing unit and the auxiliary processing unit are respectively installed on both sides of the connecting body and connected to each other through the connecting body.
The processing device according to claim 44, wherein the processing unit comprises:

A base

A mounting side wall, the mounting side wall extending vertically from one end of the base;

A holding piece, the holding piece is installed on the outside of the installation side wall;

At least one sub-processing unit, the sub-processing unit being detachably mounted on the base; and

At least one first connecting member, the first connecting member extending outwardly from the side wall of the base, wherein the sub-processing unit is connected to the first connecting member.
The housing according to claim 45, wherein the housing comprises a housing base, both ends of the connecting body extend to the two side walls of the housing base, and the two sides of the connecting body respectively face the The front wall of the housing base and the rear wall of the housing base, wherein a mounting portion is formed from the front wall to the connecting body, and the processing unit is detachably mounted on the mounting portion, An auxiliary part is formed from the rear wall to the connecting body, and the auxiliary processing unit is installed on the auxiliary part.
The processing device according to claim 46, wherein the connecting body is provided with one or more second connecting members, and one side of each second connecting member faces each of the supporting channels.
The processing device according to claim 47, wherein the housing base includes a front wall, the front wall is provided with one or more installation openings, and the periphery of the installation opening extends toward the inner side of the housing to form a The inner wall surrounds the inner wall to form a supporting channel, and each of the second connecting members faces each of the supporting channels.
The processing device according to claim 48, wherein the processing unit is installed in the support channel through the installation opening, and the first connecting member and the second connecting member are detachably connected.
The processing device according to claim 49, wherein the auxiliary processing unit is connected to the second connecting member, and the processing unit is connected to the auxiliary processing unit through the connection of the first connecting member and the second connecting member. Unit connection.
The processing device according to claim 49, wherein a heat dissipation channel is formed between the base and the inner wall of the processing unit.
The processing device according to claim 51, wherein the auxiliary processing unit further comprises at least one heat dissipation element, and the heat dissipation element is disposed in an auxiliary space on the other side of the connecting body with respect to the processing unit, wherein The auxiliary space communicates with the heat dissipation channel.
The processing device according to claim 46, wherein the housing further comprises a cover body covering the housing base, wherein the cover body has two cover body side walls, each of the cover body sides The wall and each side wall of the housing base are respectively provided with at least one vent.
The processing device according to claim 51, wherein the installation side wall of the processing unit is provided with at least one through hole, and the through hole communicates with the heat dissipation channel.
The processing device according to claim 45, wherein the processing unit includes a plurality of the sub-processing units, each of the sub-processing units is detachably mounted on the base, wherein each of the sub-processing units is independent Ground is connected to the first connecting piece, and each of the sub-processing units is connected to the auxiliary processing unit through the second connecting piece.
The processing device according to claim 44, wherein the auxiliary processing unit comprises:

At least one energy supply element, the energy supply element is arranged on the auxiliary part, and each of the second connecting members is respectively connected to the energy supply element;

At least one storage element, the storage element is disposed on the auxiliary part, and each of the second connecting members is respectively connected to the storage element; and

At least one network control element, the network control element is arranged in the auxiliary part, and each of the second connectors is respectively connected to the network control element element.
A processing device, characterized in that it comprises:

At least one processing unit;

An auxiliary processing unit; and

A housing, wherein a front wall of the housing is provided with one or more installation openings, and each of the installation openings is distributed in an array on the front wall, wherein the installation openings are separated from the periphery of the installation openings An inner wall extends to the inside of the housing, and each of the inner walls surrounds to form a support channel. The processing unit is detachably mounted on the support channel, and the auxiliary processing unit is mounted on the housing opposite to On the other side of the front wall.
The processing device according to claim 57, wherein the processing unit comprises:

A base

A mounting side wall, the mounting side wall extending vertically from one end of the base;

A holding piece, the holding piece is installed on the outside of the installation side wall;

At least one sub-processing unit, the sub-processing unit being detachably mounted on the base; and

At least one first connecting member, the first connecting member extending outwardly from the side wall of the base, wherein the sub-processing unit is connected to the first connecting member.
The housing according to claim 58, wherein the housing includes a housing base and a cover, the processing unit and the auxiliary processing unit are respectively mounted on the housing base, and the cover covers The housing base.
The processing device according to claim 59, wherein the housing base includes at least one connecting body, both ends of the connecting body extend to the two side walls of the housing base, and the two sides of the connecting body respectively face The front wall of the housing base and the rear wall of the housing base form a mounting portion from the front wall to the connecting body, and the processing unit is detachably mounted on the mounting portion, An auxiliary part is formed from the rear wall to the connecting body, and the auxiliary processing unit is installed on the auxiliary part.
The processing device according to claim 60, wherein the connecting body is provided with one or more second connecting members, each of the second connecting members is distributed in an array on the connecting body, wherein each of the second connecting members One side faces each of the supporting channels respectively.
The processing device according to claim 61, wherein the processing unit is installed in the supporting channel through the installation opening, the processing unit is installed in the installation part in an array, wherein the first connecting member and The second connecting member is detachably connected.
The processing device according to claim 62, wherein the auxiliary processing unit is connected to the second connecting member, and the processing unit is connected to the auxiliary processing unit through the connection of the first connecting member and the second connecting member. Unit connection.
The processing device according to claim 62, wherein a heat dissipation channel is formed between the base and the inner wall of the processing unit.
The processing device according to claim 64, wherein the auxiliary processing unit further comprises at least one heat dissipation element, and the heat dissipation element is disposed in an auxiliary space on the other side of the connecting body with respect to the processing unit, wherein The auxiliary space communicates with the heat dissipation channel.
The processing device according to claim 59, wherein the cover body has two cover body side walls, and each of the cover body side walls and each of the side walls of the housing base is respectively provided with at least one vent .
The processing device according to claim 64, wherein the installation side wall of the processing unit is provided with at least one through hole, and the through hole communicates with the heat dissipation channel.
The processing device according to claim 58, wherein the processing unit includes a plurality of the sub-processing units, each of the sub-processing units is detachably mounted on the base, wherein each of the sub-processing units is independent Ground is connected to the first connecting piece, and each of the sub-processing units is connected to the auxiliary processing unit through the second connecting piece.
The processing device according to claim 57, wherein the auxiliary processing unit comprises:

At least one energy supply element, the energy supply element is arranged on the auxiliary part, and each of the second connecting members is respectively connected to the energy supply element;

At least one storage element, the storage element is disposed on the auxiliary part, and each of the second connecting members is respectively connected to the storage element; and

At least one network control element, the network control element is arranged in the auxiliary part, and each of the second connectors is respectively connected to the network control element element.