CN211906148U - Processing apparatus - Google Patents

Abstract

The utility model provides a processing apparatus, it includes an at least processing unit, an auxiliary processing unit and a casing, wherein a antetheca of casing is set up one or more installation opening, each installation opening distributes in array in the antetheca, wherein, respectively certainly installation opening's periphery to the inboard of casing extends and forms an inner wall, each the inner wall encircles and forms a support passageway, processing unit by detachably install in support passageway, auxiliary processing unit install in the casing for the opposite side of antetheca.

Description

Processing apparatus

Technical Field

The utility model relates to a data processing equipment field especially relates to a processing apparatus.

Background

A server is a device that provides computing services, and is capable of handling large amounts of data.

When a server fails, data processing is interrupted, thereby affecting processing progress and processing results. The server undertakes processing work and is a central processing unit and a mainboard chip set, and once components in the central processing unit and the mainboard chip set are damaged, the server breaks down and cannot be used.

The development of the internet brings about the explosive growth of data, and the efficient processing of data in the big data era is particularly important. And for huge data volume, the data depends on the processing capacity of the processing server, particularly the chip of the server. The chip is the core of the server for processing data, and the operation of the server is guaranteed, namely the safe and normal operation of the chip is guaranteed. The chip processes the data according to the instruction, and when the chip breaks down, the server cannot normally operate, the computing power is lost, and the data cannot be effectively processed. In the internet era, any time delay can cause data to lose timeliness, even if it is only a brief, transient failure.

In order for data to be processed timely and efficiently, the processing power of the server needs to be better exploded. The throughput of server is provided by the chip, and in case the chip trouble, the time of changing or maintaining the chip must be consumed, and hardly obtains effective control, waits for the chip to be changed and finishes, carries out data processing again, must lead to the fact the interrupt of data processing, and the processing of earlier stage probably can be lacked just for a short time so, also can cause data to lose validity. Therefore, the consequences of continuing data processing after the same server waits for the original server to be repaired due to failure are unpredictable, and loss is likely to occur. Data migration from a failed original server to a new server with processing capability may also cause interruption of data processing, leading to unpredictable consequences.

In addition, stopping the operation of the server to replace the chip also causes huge cost loss. The whole server is disassembled to replace the chip, which not only causes the middle section of data processing, but also causes cost consumption due to the time for disassembling, replacing and installing.

When the client processes the content output, the client occupies the hardware performance and software environment of the client, so that the efficiency of the content output is limited by the conditions of the client. When the client itself is insufficient to handle the content output, delay of the content output and content loss are easily generated. In the field of games, when playing network games, a game client needs to be downloaded and installed first, which causes the performance of devices such as mobile phones and computers to be partially occupied by the game client, thereby affecting the processing efficiency of the devices and easily causing the problem of content delay.

There is therefore a need for a technique to address the above problems.

SUMMERY OF THE UTILITY MODEL

An advantage of the present invention is to provide a processing apparatus, wherein the processing unit of the processing apparatus is detachably installed in the processing apparatus, and the processing units are independent from each other.

Another advantage of the present invention is to provide a processing apparatus, wherein the processing unit of the processing apparatus is mounted and dismounted by hot plugging.

Another advantage of the present invention is to provide a processing apparatus, wherein the processing unit of the processing apparatus is mounted and dismounted by hot plugging.

Another advantage of the present invention is to provide a processing apparatus, wherein the processing units of the processing apparatus are independent of each other and do not interfere with each other.

Another advantage of the present invention is to provide a processing apparatus, wherein the processing apparatus provides an auxiliary processing unit to the processing unit provides processing assistance.

Another advantage of the present invention is to provide a processing apparatus, wherein the processing unit and the auxiliary processing unit of the processing apparatus are mounted in a housing to form the processing apparatus.

Another advantage of the present invention is to provide a processing apparatus, wherein the processing unit of the processing apparatus is independently connected to the auxiliary processing unit, and the auxiliary processing unit is respectively for each the processing unit provides processing assistance.

Another advantage of the present invention is to provide a processing apparatus, wherein the processing units of the processing apparatus work independently of each other and also work in cooperation.

Another advantage of the present invention is to provide a processing apparatus, wherein the housing of the processing apparatus has an independent support channel for installation of the processing unit.

Another advantage of the present invention is to provide a processing apparatus, the processing apparatus the processing unit includes at least a first connecting piece, the casing includes at least a second connecting piece, the first connecting piece set up in support the passageway, the processing unit install to support the passageway, the first connecting piece with the second connecting piece is connected.

Another advantage of the present invention is to provide a processing apparatus, the processing apparatus includes at least one sub-processing unit, the sub-processing unit detachably mounted in the processing unit, the sub-processing unit realizes hot plugging.

Another advantage of the present invention is to provide a processing apparatus, wherein the processing apparatus is disassembled and assembled by hot plugging to the processing unit, so that the processing apparatus maintains an operating state.

Another advantage of the present invention is to provide a processing apparatus, wherein the processing apparatus is disassembled and assembled by hot plugging to the sub-processing units, so that the processing apparatus is maintained in an operating state by the sub-processing units.

Another advantage of the present invention is to provide a processing apparatus, the processing apparatus is realized by hot plugging the processing unit with the sub-processing unit and the disassembling and assembling, the cost is reduced, and the time is saved.

The other advantages and features of the invention will be fully apparent from the following detailed description and realized by means of the instruments and combinations particularly pointed out in the appended claims.

According to an aspect of the present invention, the present invention provides a processing apparatus, including:

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 mounting openings, each of the mounting openings is distributed on the front wall in an array, wherein an inner wall extends from a periphery of the mounting opening to an inner side of the housing to form a support channel, each of the inner walls surrounds the support channel, the processing unit is detachably mounted in the support channel, and the auxiliary processing unit is mounted on the other side of the housing opposite to the front wall.

According to an embodiment of the present invention, the processing unit includes:

a base;

a mounting sidewall formed extending vertically from one end of the base;

the holding piece is arranged on the outer side of the mounting side wall;

at least one sub-processing unit detachably mounted to the base; and

at least one first connecting piece, the first connecting piece outwards extends from the lateral wall of base and forms, wherein sub-processing unit connects in first connecting piece.

According to an embodiment of the present invention, the housing includes a housing base and a cover, the processing unit and the auxiliary processing unit are respectively installed in the housing base, and the cover covers the housing base.

According to the utility model discloses an embodiment, the casing base includes at least one connection main part, the both ends of connection main part extend to the both sides wall of casing base, the both sides of connection main part are respectively towards the casing base the antetheca with the back wall of casing base, certainly the antetheca extremely the connection main part forms an installation department, processing unit by detachably install in the installation department, certainly the back wall extremely the connection main part forms an auxiliary part, auxiliary processing unit is installed in auxiliary part.

According to an embodiment of the present invention, the connection body is provided with one or more second connection members, each of the second connection members is distributed in the connection body in an array, wherein each of one sides of the second connection members faces each of the support passages, respectively.

According to an embodiment of the present invention, the processing unit is installed in the support passage 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 are detachably connected.

According to the utility model discloses an embodiment, supplementary processing unit connect in the second connecting piece, processing unit passes through first connecting piece with the connection of second connecting piece with supplementary processing unit connects.

According to an embodiment of the present invention, the base of the processing unit and the inner wall form a heat dissipation channel therebetween.

According to an embodiment of the present invention, the auxiliary processing unit further includes at least one heat dissipation element, the heat dissipation element is disposed in an auxiliary space of the connecting body opposite to the other side of the processing unit, wherein the auxiliary space communicates with the heat dissipation channel.

According to the utility model discloses an embodiment, the lid has two lid lateral walls, each the lid lateral wall with each of the lateral wall of casing base is set up at least a vent respectively correspondingly.

According to the utility model discloses an embodiment, processing unit the installation lateral wall is provided with an at least through-hole, the through-hole with heat dissipation channel intercommunication.

According to the utility model discloses an embodiment, the processing unit includes a plurality of the sub-processing unit, each the sub-processing unit respectively by detachably install in the base, wherein each the sub-processing unit respectively independently connect in first connecting piece, each the sub-processing unit passes through respectively the second connecting piece with the auxiliary processing unit is connected.

According to the utility model discloses an embodiment, supplementary processing unit includes:

at least one energy supply element, the energy supply element is arranged on the auxiliary part, and each second connecting piece is respectively connected with the energy supply element;

at least one storage element, the storage element is set up in the said auxiliary portion, every said second link is connected to the said storage element separately; and

at least one network control element, the network control element is set in the auxiliary part, and each second connecting piece is connected to the network control element.

These and other objects, features and advantages of the present invention will become more fully apparent from the following detailed description, the accompanying drawings and the appended claims.

Drawings

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

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

Fig. 3 is a schematic view of the treatment device according to the above preferred embodiment of the present invention.

Fig. 4 is a schematic view of the treatment device according to a variant of the above-described preferred embodiment of the invention.

Fig. 5 is a rear view of the treating apparatus according to the above preferred embodiment of the present invention.

Fig. 6 is a schematic view of the treatment device according to the above preferred embodiment of the present invention.

Fig. 7 is another variant of the treatment device according to the above preferred embodiment of the invention.

Fig. 8 is a schematic view of the treatment device according to the above preferred embodiment of the present invention.

Detailed Description

The following description is presented to disclose the invention so as to enable any person skilled in the art to practice the invention. The preferred embodiments in the following description are given by way of example only, and other obvious variations will occur to those skilled in the art. The basic principles of the invention, as defined in the following description, may be applied to other embodiments, variations, modifications, equivalents and other technical solutions without departing from the spirit and scope of the invention.

It will be understood by those skilled in the art that in the present disclosure, the terms "longitudinal," "lateral," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in a generic and descriptive sense only and not for purposes of limitation, as the terms are used in the description to indicate that the referenced device or element must have the specified orientation, be constructed and operated in the specified orientation, and not for the purpose of limitation.

It is understood that the terms "a" and "an" should be interpreted as meaning that a number of one element or element is one in one embodiment, while a number of other elements is one in another embodiment, and the terms "a" and "an" should not be interpreted as limiting the number.

The utility model provides a processing device. In a preferred embodiment of the present invention, as shown in fig. 1A to 6, the processing device includes at least two processing units 10, at least one auxiliary processing unit 20, and a housing 30. The process unit 10 and the auxiliary process unit 20 are respectively mounted to the housing 30. Wherein the housing 30 encloses the processing unit 10 and the auxiliary processing unit 30. Wherein 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 32, the cover 32 is detachably mounted on the housing base 31, and an inner cavity of the housing 30 is formed between the cover 32 and the housing base 31. The process unit 10 and the auxiliary process unit 20 are mounted to the housing base 31 and are accommodated in the inner cavity of the housing 30.

The housing base 31 includes a front wall 311, a rear wall 312, and two side walls 313, wherein the front wall 311, the side walls 313, the rear wall 312, and the other side wall 313 surround the side walls forming the housing base 31. The process unit 10 is pushed into the housing 30 from the front wall 311 side to be mounted on the housing 30. The front wall 311 is provided with at least one mounting opening 310, and a support channel 3100 is formed by extending from the mounting opening 310 to the inside of the housing 30, respectively, and the support channel 3100 is used for mounting the processing unit 10.

In one example of the present invention, the front wall 311 is provided with a plurality of mounting openings 310. The mounting openings 310 are spaced apart to allow the process units 10 to pass through, respectively, to be mounted in the support channel 3100. Each support channel 3100 is independent of the other. Preferably, each support channel 3100 is provided for mounting one of said treatment units 10.

An inner wall 3111 extends from the periphery of each of the mounting openings 31 to the inside of the housing 30. Wherein the inner wall 3111 surrounds the support channel 3100. When the processing unit 10 is mounted to the support channel 3100, the processing unit 30 is surrounded by the inner wall 3111. The process unit 10 is supported by the bottom of the inner wall 3111 such that the process unit 10 is stably mounted to the support channel 3100.

Referring to fig. 2, the processing unit 10 includes a base 11 and a mounting sidewall 12, and the mounting sidewall 12 is fixed to the base 11 and is perpendicular to the base 11. The mounting sidewall 12 is formed to extend perpendicularly from one end of the base 11. Wherein the inner side of the mounting sidewall 12 faces the base 11 side. The processing unit 10 further comprises a grip 13, the grip 13 being fixed to the outer side of the mounting sidewall 12. The holding part 13 is used for holding. Preferably, the grip 13 is embodied as a handle.

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

The processing unit 10 further comprises one or more sub-processing units 14, the sub-processing units 14 being mounted to the base 11. The sub-processing unit 14 is used for processing data. The sub-processing units 14 are detachably mounted to the base 11, respectively.

The processing unit 10 further comprises at least one first connecting member 15, wherein the first connecting member 15 is arranged on the side surface of the base 11. The first connecting member 15 is formed to extend outward from a sidewall of the base 11. Wherein the first connecting member 15 and the mounting sidewall 12 are divided to be located at both sides of the base 11. When the process unit 10 is mounted to the housing 30, the first connector 15 connects the process 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 are not affected by 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, the communication unit 16 is connected to the sub-processing unit 14, the communication unit 16 is connected to the first connecting member 15, and the communication unit 16 provides communication with the sub-processing unit 14 for the sub-processing unit 14. The sub-processing unit 14 is connected to the first connection 15 via the communication unit 16.

The processing unit 10 is mounted into the support channel 3100 through the mounting opening 310. The size of the mounting opening 310 is adapted to the size of the mounting sidewall 12 of the processing unit 10, the mounting sidewall 12 is located at one end of the base 11, the height of the mounting sidewall 12 is higher than the height of the base 11, when the processing unit 10 passes through the mounting opening 310 and is mounted into the supporting channel 3100, the base 11 moves into the supporting channel 3100, and the mounting sidewall 311 closes the mounting opening 310. The base 11 occupies a portion of the support channel 3100, with the remaining support channels 3100 forming a heat dissipation channel 3120. That is, when the processing unit 10 is mounted to the support channel 3100, the heat dissipation channel 3120 is formed between the base 11 and the inner wall 3111.

Wherein the handling unit 10 is pushed into the support channel 3100 by gripping the grip 13.

With continued reference to fig. 3, the housing 30 further includes at least one connecting body 314, the connecting body 314 is disposed on the housing base 31, and the processing unit 10 and the auxiliary processing unit 20 are respectively mounted on two sides of the connecting body 314. The distance between the connecting body 314 and the front wall 311 is adapted for the mounting 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 sidewalls 313.

The inner wall 3111 forming the support channel 3100 extends from the front wall 311 toward the connecting body 314. One end of the support channel 3100 is formed at the mounting opening 310, and the other end of the support channel 3100 extends to one side of the connecting body 314. When the process unit 10 is mounted to the support channel 3100, the mounting sidewall 311 of one end of the process unit 10 fits into the mounting opening 310 and the other end of the process unit 10 fits into the connecting 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 supporting channel 3100. Wherein the first connector 15 of the processing unit 10 is disposed at the other side of the base 11 with respect to the mounting sidewall 12. When the processing unit 10 is mounted on the support channel 3100, the first connector 15 and the second connector 3141 are connected. Preferably, the first connector 15 and the second connector 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 at both sides of the connecting body 314. Wherein the processing unit 10 is mounted to the mounting portion 33, the auxiliary processing unit 20 is mounted to the auxiliary portion 34, and the auxiliary processing unit 20 is connected to the processing unit 10 to assist the processing unit 10 in processing.

The mounting portion 33 is formed to extend from the front wall 311 of the housing 30 to the connecting body 314 side. The front wall 311 is provided with a plurality of mounting openings 310 with a certain interval between the mounting openings 310. Preferably, the mounting openings 310 are arranged in an array at the front wall 311. The inner wall 3111 extends from each of the mounting openings 310 toward the inside of the housing 30. Each of the inner walls 3111 surrounds each of the support channels 3100. The support channels 3100 are distributed in an array on the mounting portion 33 of the housing 30. When the process units 10 are respectively mounted to the support passages 3100 through the mounting openings 310, the inner walls 3111 surround the process units 10, the process units 10 are respectively spaced apart by the inner walls 3111, and the process units 10 are respectively mounted to the mounting portions 33 in an array.

That is, the supporting passages 3100 formed by the inner walls 3111 are distributed in an array in the housing 30, so that the processing units 10 mounted to the supporting passages 3100, respectively, are distributed in an array.

The housing 30 has an auxiliary space 3400, the auxiliary space 3400 being formed inside the auxiliary portion 34 of the housing 30, the auxiliary space 3400 being in communication with the support passage 3100. When the processing unit 10 is mounted to the support passage 3100, the heat dissipation passage 3120 formed between the base 11 and the inner wall 3111 communicates with the auxiliary space 3400.

When the process unit 10 is mounted to the support channel 3100, the process unit 10 is mounted to the mounting portion 33 of the connecting body 314 side, and the first connector 15 of the process unit 10 is connected to the second connector 3141 of the connecting body 314. Each of the second coupling members 3141 is independently coupled to the auxiliary processing unit 20. Each of the process units 10 is independently connected to the auxiliary process unit 20 by the connection of the first and second connection members 15 and 3141, respectively.

The auxiliary treatment unit 20 is mounted to the inner cavity of the housing 30, and the auxiliary treatment unit 20 provides treatment assistance to the treatment unit 10. The auxiliary processing unit 20 is installed in the auxiliary space 3400 at one side of the connecting body 314. The auxiliary processing unit 20 is coupled to each of the second coupling members 3141 of the coupling body 314, and the auxiliary processing unit 20 is coupled to the processing unit 10 mounted to the mounting portion 33 through the coupling body 314. The processing unit 10 and the auxiliary processing unit 20 are respectively disposed at two 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 connection member 3141.

The auxiliary processing unit 20 comprises at least one energy supply element 21, wherein the energy supply element 21 is energizably connectable to the processing unit 10 for supplying energy to the processing unit 10. Wherein the energizing element 21 is connected to each of the second connecting members 3141. The auxiliary processing unit 20 comprises at least one memory element 22, the memory element 22 being communicatively connected to the processing unit 10 for storing data of the processing unit 10.

The storage device 22 may be implemented as one or a combination of a hard disk, an optical drive, a memory, etc.

Wherein, the energizing element 21 can be energizably connected to the second connection 3141, and the energizing element 21 provides energy through the second connection 3141. When the first connector 15 and the second connector 3141 of the processing unit 30 are connected, the first connector 15 is connected with the energizing element 21 through the second connector 3141, and the energy provided by the energizing element 21 enters the first connector 15 through the second connector 3141.

The memory element 22 is communicatively coupled to the second coupling 3141, and when the processing unit 10 is mounted on the support channel 3100, the first coupling 15 and the second coupling 3141 communicate for data transfer. The processing unit 10 is communicated with the storage element 22 through the communication of the first connecting piece 15 and the second connecting piece 3141, the processing unit 10 and the storage element 22 are mutually communicated and connected for data transmission, the processing unit 10 stores data into the storage element 22, and the processing unit 10 acquires data from the storage element 22.

That is, 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 connectors 3141 of the supporting channels 3100 are connected to each other, and when the second connectors 3141 are connected to the first connectors 15 of the process units 10, the process units 10 are connected to each other, and data is transmitted between the process units 10.

That is, after each of the processing units 10 is mounted to the support channel 3100, the processing units 10 may perform data transmission with each other.

Each of the second coupling members 3141 is independently coupled to the auxiliary treating unit 20, respectively, so that each of the treating units 10 mounted from the supporting channel 3100 is independently coupled to the auxiliary treating unit 20, respectively.

Each of the second coupling members 3141 is independently connected to the energizing member 21, so that the energizing member 21 energizes the processing unit 10 through each of the second coupling members 3141. Each of the second connection members 3141 is independently connected to the memory element 22, so that each of the memory elements 22 is connected to the processing unit 10 through each of the second connection members 3141, thereby forming a data path.

Each of the processing units 10 is independently connected to the memory element 22 through the connection of each of the first connectors 15 and each of the second connectors 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 coupled to each of the second connectors 3141, and when the second connectors 3141 are coupled to the first connectors 15 of the processing units 10, the network control element 23 is communicatively coupled to the processing units 10. The network control elements 23 are communicatively connected to each of the processing units 10 mounted to the support channel 3100, respectively. When the network control element 23 is enabled, the network control element 23 provides a network for each of the processing units 10, such that each of the processing units 10 is located in a communication network. The processing units 10 communicate with each other. Each of the processing units 10 communicates with other devices outside the processing apparatus via 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 a communication network, and data transmission is performed between the processing units 10 and the storage element 22. A data path is formed.

Wherein the communication unit 16 of the processing unit 10 is connected to the network control element 23 via the connection of the first connector 15 and the second connector 3141. The communication unit 16 acquires a communication network from the network control element 23. The sub-processing unit 14 communicates with the other sub-processing units 14 and the sub-processing units 14 of the other processing units 10 via the communication unit 16. Wherein, when each of the processing units 10 is mounted to the support channel 3100, each of the first connectors 15 communicates with each other.

When the processing unit 10 is mounted on the supporting channel 3100, the first connecting member 15 is connected to the second connecting member 3141, and the first connecting members 15 and the second connecting members 3141 of the other processing units 10 connect the processing unit 10 to the other processing units 10 for communication and data transmission. Each of the processing units 10 is connected to another processing unit 10 through the connecting body 314, and performs communication and data transmission.

The auxiliary processing unit 20 further includes at least one heat dissipating element 24, the heat dissipating element 24 being mounted to the auxiliary portion 34, the heat dissipating element 24 providing heat dissipation to the processing unit 10. The heat radiating member 24 is installed at the rear wall 312 of the housing base 31, one side of the heat radiating member 24 faces the auxiliary space 3400, one side of the heat radiating member 24 faces the outside of the housing 30, and the heat radiating member 24 communicates the auxiliary space 3400 and the outside of the housing 30. Air circulates between the auxiliary space 3400 and the outside space of the case 30 through the heat radiating member 24.

It is worth mentioning that the height of the connecting body 314 is lower than that of the side wall 313 of the housing base 32 so that the heat dissipation passage 3120 communicates with the auxiliary space 3400, and the air at the heat dissipation passage 3120 communicates with the space outside the housing 30 through the auxiliary space 3400 and the heat dissipation member 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 sidewall 12 communicates the heat dissipation channel 3120 with the air outside the mounting sidewall 12, and the air at the heat dissipation channel 3120 circulates to the outside through the through hole 120 when being heated, so as to dissipate heat. The heat dissipation member 24 assists the air to flow outwardly from the heat dissipation channel 3120 through the through-hole 120. The air at the heat dissipation passage 3120 enters the auxiliary space 3400 and is discharged to the outside of the case 30 through the heat dissipation element 24. The heat dissipation element 24 provides a heat dissipation aid 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 spaces are communicated with each other to allow air to circulate, thereby facilitating heat dissipation. The processing unit 10 is mounted to the processing device, occupying part of the space of the support channel 3100, forming the heat dissipation channel 3120 between the processing unit 10 and the inner wall 3111 of the support channel 3100. A certain space is provided between one end of the connecting body 314 and the cover 32. One end of the heat dissipation passage 3120 communicates with the through hole 120 of the mounting sidewall 12 of the processing unit 10, and the heat dissipation passage 3120 communicates with the outside through the through hole 120. The other end of the heat dissipation passage 3120 communicates with the auxiliary space 3400 through a space between the connecting body 314 and the cover 32. Heat generated when the processing unit 10 operates flows outward from the heat dissipation passage 3120, and the heat at the heat dissipation passage 3120 may be discharged to the outside through the through hole 120, and may also flow into the auxiliary space 3400 through the space between the connecting body 314 and the cover 32 and be discharged out of the case 30 through the heat dissipation member 24.

The cover 32 includes a cover main body 321 and two cover sidewalls 322, and each of the cover sidewalls 322 extends perpendicularly from two ends of the cover main body 321. Wherein the cover sidewall 322 is sized to fit the sidewall 313 of the housing base 31. The front wall 311, the two side walls 312 and the rear wall 313 surround an opening forming the housing base 31. The cover main body 321 is adapted to cover the opening of the housing base 31.

Wherein, the cover sidewall 322 is provided with at least one ventilation opening, the sidewall 313 of the housing base 31 is provided with at least one ventilation opening, when the cover 32 is installed on the housing base 31, the cover sidewall 322 is communicated with the ventilation opening of the sidewall 313 and is communicated with the heat dissipation channel 3120 for heat dissipation. The heat in the inner cavity of the housing 30 can also be exhausted to the housing 30 through the ventilation openings of the cover sidewall 322 and the sidewall 313 of the housing base 31.

That is, the cover side wall 322 and the side wall 313 are respectively provided with the ventilation openings 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 coupled to the housing 30, and the processing device operates when at least one processing unit 10 is mounted to the housing 30 and communicates with the auxiliary processing unit 20.

It is worth mentioning that the housing 30 further comprises one or more interfaces 35, the interfaces 35 are disposed on the outer side of the housing 30, and the processing device is connected with other devices through the interfaces 35. The interface 35 is implemented as one or a combination of USB interface, DisplayPort (display interface), VGA (Video Graphics Array) interface, network management interface, serial port, and the like. The type and number of the interfaces 35 are not limited.

As shown in fig. 4, the auxiliary portion 34 is provided with at least one management unit 10 ', the management unit 10' is connected to each of the second connection members 3141, the management unit 10 'and the auxiliary processing unit 20 are connected to each other, and the auxiliary processing unit 20 provides processing assistance to the management unit 10'. That is, the processing apparatus includes the management unit 10 ', and when the processing unit 10 is installed in the processing apparatus, the management unit 10' is connected to the processing unit 10 to manage the processing unit 10.

Wherein, the energy supply element 21 can be connected to the management unit 10 'in an energy supply manner to supply energy to the management unit 10'. The memory element 22 is communicatively connected to the management unit 10 'for data transfer 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 to the mounting portion 33, and the management unit 10' is communicatively connected to each of the second coupling members 3141. When the process unit 10 is mounted to the processing apparatus, i.e. the process unit 10 is connected by the first connector 15 and the second connector 3141, the process unit 10 and the management unit 10' are connected by the connection of the first connector 15 and the second connector 3141. The management unit 10' manages the processing unit 10 mounted to the processing apparatus.

In a variant embodiment of the invention, as shown in fig. 7, the front wall 312 of the housing 20 is provided with a plurality of mounting openings 310 distributed in an array. The rear wall 312 of the housing 30 of the processing device may also be provided with an array of the mounting openings 310. With respect to the treatment device disclosed in the above preferred embodiment, the front and rear sides of the treatment device disclosed in this modified embodiment may be provided with the mounting openings 310, and the mounting openings may extend inward to form the inner wall 3111 surrounding the support channel 3100. The process units 10 are mounted to the support channel 3100 from the mounting openings 310 at the front and rear sides, respectively.

Both sides of the connecting body 314 face the processing units 10 at the front and rear sides, respectively. The auxiliary processing unit 20 is disposed at one side of the connection 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 a side of the connecting body 314 to an upper portion of the rear wall 312, and the auxiliary portion 34 is formed from a side of the connecting body 314 to a lower portion of the rear wall 312. The process unit 10 and the auxiliary process unit 20 are mounted to the mounting portion 33 and the auxiliary portion 34, respectively.

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

The mounting portion 33 is formed between the front wall 311 and one side of the connecting body 314, the front wall 311 is provided with the mounting openings 310 distributed in an array, the mounting openings 310 extend inwards to form the supporting channels 3100, and the inner wall 3111 surrounds the supporting channels 3100 distributed in an array. The processing unit 10 is mounted to the support 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 dissipating heat. Referring to fig. 7, the upper portion of the front wall 311 and the connecting body 314 form a completely communicated heat dissipation space therebetween, and the upper portion of the front wall 311 is provided with at least one ventilation opening, and the ventilation opening is communicated with the heat dissipation space to dissipate heat. The mounting portion 33 is formed between the lower portion of the front wall 311 and the connecting body 314, and the heat dissipation passage 3120 of the mounting portion 33 communicates with the heat dissipation space. The heat dissipation passage 3120 of the other side of the connecting body 314 communicates with the heat dissipation space through a space between the connecting body 314 and the cover 32. That is, the heat dissipation passages 3120 at both sides of the connecting body 314 communicate with the heat dissipation space to dissipate heat.

The mounting portion 33 may be formed between the connecting body 314 and the front wall 311 to mount the processing unit 10, and the heat dissipation space may be formed to communicate with the heat dissipation passage 3120 to dissipate heat. The auxiliary portion 34 may be formed between the connecting body 314 and the rear wall 312 to mount the auxiliary processing unit 20, and the auxiliary portion 34 and the mounting portion 33 may be formed to mount the auxiliary processing unit 20 and the processing unit 10, respectively. The processing units 10 may be mounted on the same side of the connecting body 314 or may be mounted on the same side of the connecting body 314.

It will be understood by those skilled in the art that the embodiments of the present invention as described above and shown in the drawings are given by way of example only and are not limiting of the present invention. The objects of the present invention have been fully and effectively accomplished. The functional and structural principles of the present invention have been shown and described in the embodiments without departing from the principles, embodiments of the present invention may have any deformation or modification.

Claims (13)

1. A processing apparatus, comprising:

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 mounting openings, each of the mounting openings is distributed on the front wall in an array, wherein an inner wall extends from a periphery of the mounting opening to an inner side of the housing to form a support channel, each of the inner walls surrounds the support channel, the processing unit is detachably mounted in the support channel, and the auxiliary processing unit is mounted on the other side of the housing opposite to the front wall.

2. The processing device of claim 1, wherein the processing unit comprises:

a base;

a mounting sidewall formed extending vertically from one end of the base;

the holding piece is arranged on the outer side of the mounting side wall;

at least one sub-processing unit detachably mounted to the base; and

at least one first connecting piece, the first connecting piece outwards extends from the lateral wall of base and forms, wherein sub-processing unit connects in first connecting piece.

3. The processing apparatus according to claim 2, wherein the casing includes a casing base to which the processing unit and the auxiliary processing unit are mounted, and a cover which covers the casing base.

4. The processing apparatus as claimed in claim 3, wherein the housing base includes at least one connecting body, both ends of the connecting body extend to both side walls of the housing base, both sides of the connecting body face the front wall of the housing base and the rear wall of the housing base, respectively, an installation portion is formed from the front wall to the connecting body, the processing unit is detachably installed to the installation portion, an auxiliary portion is formed from the rear wall to the connecting body, and the auxiliary processing unit is installed to the auxiliary portion.

5. The processing apparatus according to claim 4, wherein the connecting body is provided with one or more second connectors, each of the second connectors being distributed over the connecting body in an array, wherein one side of each of the second connectors faces each of the support passages, respectively.

6. The treatment device of claim 5, wherein the treatment units are mounted to the support channel through the mounting openings, the treatment units being mounted in an array to the mounting portion, wherein the first and second connectors are detachably connected.

7. A treatment device as claimed in claim 6, wherein the auxiliary treatment unit is connected to the second connection, the treatment unit being connected to the auxiliary treatment unit by the connection of the first and second connections.

8. The processing device of claim 6, wherein a heat sink channel is formed between the base and the inner wall of the processing unit.

9. The processing apparatus as set forth in claim 8, wherein the auxiliary processing unit further comprises at least one heat dissipating member disposed in an auxiliary space on the other side of the main connection body with respect to the processing unit, wherein the auxiliary space communicates with the heat dissipating passage.

10. The processing apparatus as claimed in claim 3, wherein the cover has two cover sidewalls, and each of the cover sidewalls and each of the sidewalls of the housing base are respectively provided with at least one ventilation opening.

11. The processing apparatus as claimed in claim 8, wherein the mounting sidewall of the processing unit is provided with at least one through hole communicating with the heat dissipation channel.

12. The processing device as claimed in claim 2, wherein the processing unit comprises a plurality of the sub-processing units, each of the sub-processing units being detachably mounted to the base, wherein each of the sub-processing units is independently connected to the first connecting member, the housing comprises a housing base, the housing base comprises at least one connecting body, the connecting body is provided with one or more second connecting members, and each of the sub-processing units is connected to the auxiliary processing unit through the second connecting member.

13. The processing apparatus according to claim 5, wherein the auxiliary processing unit comprises:

at least one energy supply element, the energy supply element is arranged on the auxiliary part, and each second connecting piece is respectively connected with the energy supply element;

at least one storage element, the storage element is set up in the said auxiliary portion, every said second link is connected to the said storage element separately; and

at least one network control element, the network control element is set in the auxiliary part, and each second connecting piece is connected to the network control element.

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