CN116321971A

CN116321971A - Server host with heat dissipation function

Info

Publication number: CN116321971A
Application number: CN202310292179.1A
Authority: CN
Inventors: 徐堃
Original assignee: Hangzhou Jinyuan Information Technology Co ltd
Current assignee: Inner Mongolia Zhongke Chaocai Technology Co ltd
Priority date: 2023-03-23
Filing date: 2023-03-23
Publication date: 2023-06-23
Anticipated expiration: 2043-03-23
Also published as: CN116321971B

Abstract

The invention provides a server host with a heat dissipation function, which relates to the field of servers and comprises the following components: the main body frame is provided with a plurality of interlayer mounting rails at equal intervals from top to bottom on the left side and the right side of the inside of the main body frame; a server body is arranged in the interlayer mounting rail; the front sides of the tops of the interlayer mounting rails positioned on the right side are all provided with an electric connection driving piece in a sliding insertion manner; the embedded baffle is arranged on the left side of the power-on driving piece, the corresponding group of radiating fans can be electrified to work only when the server body is installed in the interlayer, and the corresponding group of radiating fans can be powered off to wait when the server body is not installed in the interlayer, so that the radiating fans are uniformly managed, and the situation that the radiating fans idle is avoided, and the problem that the fan structure without the server interlayer can synchronously run with other fan structures, so that the idle running of the fan is caused and the power resource is wasted is solved.

Description

Server host with heat dissipation function

Technical Field

The invention relates to the technical field of servers, in particular to a server host with a heat dissipation function.

Background

The operation of the website needs to endlessly enable the server host to operate, so that people can log in the website at any time to browse the webpage, but the uninterrupted operation of the server host can continuously raise the temperature, and the heat dissipation of the server is particularly important.

When the existing server host with the heat dissipation function is used, the main heat dissipation mode is that the fan structure on the server rack and the fan structure inside the server are used, the fan structure on the server rack is usually multiple, and a plurality of fan structures can be connected to the same power supply line for convenience in management, but servers are not necessarily placed in a partition layer on the server rack, and the situation of empty exists, but because the fan structure is powered by one main electric line, the fan structure without the server partition layer can run synchronously with other fan structures, so that the fan idles without causing power resource waste.

Disclosure of Invention

In view of this, the present invention provides a server host with a heat dissipation function, so as to solve the problem that servers are not necessarily placed in a partition layer on a server rack, and there is a space in the partition layer, but because the fan structure is powered by a main electric wire, the fan structure without the partition layer of the server is still synchronous with other fan structures, resulting in idle running of the fan and wasting electric power resources.

The invention provides a server host with a heat dissipation function, which specifically comprises the following steps: the main body frame is provided with a plurality of interlayer mounting rails at equal intervals from top to bottom on the left side and the right side of the inside of the main body frame; a server body is arranged in the interlayer mounting rail; a power switch is arranged at the bottom of the rear side of the main body frame; the bottom of the power switch is connected with a connecting wire; and the tail end of the electric wire is provided with an electric plug.

Further, the front sides of the tops of the interlayer mounting rails positioned on the right side are all provided with an electric connection driving piece in a sliding insertion manner; the front side of the bottom end of the power-on driving piece is of an inclined structure; the left side of the power-on driving piece is provided with an embedded baffle; the embedded baffle is of a rectangular structure; one end of a restoring spring C is embedded and installed at the bottom of the embedded baffle; the other end of the restoring spring C is embedded and arranged at the top of the right interlayer mounting rail; and a rack B is arranged on the right side of the power-on driving piece.

Further, a plurality of heat dissipation structure mounting pieces are arranged on the right side of the main body frame at equal intervals from top to bottom; a plurality of radiating fan bodies are arranged in the radiating structure mounting piece at equal intervals from front to back; the rear side of the main body frame is provided with a conductive main line.

Further, the bottom end of the conductive main line is connected with a power switch; the top of the heat dissipation structure mounting piece is provided with a conductive auxiliary wire; the tail end of the conductive auxiliary line is connected with the conductive main line; the head end of the conductive auxiliary line is provided with a power-on sheet A; the electrifying sheet A is made of copper material capable of being electrified.

Further, a movable line which can be broken is arranged on the front side of the heat dissipation structure mounting piece; the tail end of the movable wire is provided with a power-on sheet B; the electrifying sheet B is made of copper material capable of being electrified; the front end of the heat dissipation structure mounting piece is also provided with a junction box; and the junction box is connected with the head end of the conductive auxiliary line.

Further, the bottom of each junction box is connected with three conductive wires; the tail end of each conductive wire is connected with a radiating fan body; an insulating protection cylinder is arranged on the front side of the top of the heat radiation structure mounting piece; the insulating protection cylinder is of a cylindrical structure.

Further, the electrifying sheet A and the electrifying sheet B are both positioned in the insulating protection cylinder; an embedding plate is arranged on the circumferential outer wall of the insulating protection cylinder; the embedded plate is of a rectangular structure; a connecting ring is further arranged in the insulating protection cylinder; the connecting ring is of a circular ring structure; the connecting ring is connected with the breakable movable wire.

Further, a driven stress piece is arranged at the top of the connecting ring; the top of the driven stress piece is of an inclined structure; one end of the restoring spring A is embedded and mounted at the rear side of the driven stress piece; the other end of the restoring spring A is embedded and arranged on the front side of the embedded plate; the right end of the front side of the main body frame is provided with a sliding groove.

Further, a sliding block is arranged in the sliding groove in a sliding manner; the sliding block is of a rectangular structure; one end of the restoring spring B is embedded and installed at the bottom of the sliding block; the other end of the restoring spring B is embedded and arranged at the bottom of the chute; a connecting rod is arranged on the right side of the sliding block; the connecting rod is of a cylindrical structure; the right end of the connecting rod is provided with an active trigger piece.

Further, the bottom end of the active trigger piece is of an inclined structure; the bottom inclined surface of the driving trigger piece is contacted with the top inclined surface of the driven stressed piece; a rack A is arranged on the left side of the sliding block; a transmission gear is arranged on the right side of the inside of the main body frame; the transmission gear is meshed and connected with the rack A and the rack B at the same time.

Advantageous effects

1. According to the invention, the server body is manually placed into the interlayer mounting rail, the server body pushes the inclined plane of the power receiving driving piece in the mounting process, the power receiving driving piece is driven by the influence of the pushing of the inclined plane to drive the rack B to move upwards, the rack B drives the rack B and the sliding block to move downwards along the sliding groove under the action of the transmission gear, the sliding block drives the driving trigger piece to press the inclined plane of the driven stress piece under the action of the connecting rod, the driven stress piece is stressed to drive the connecting ring, the movable line and the electrified sheet B to move backwards along the insulating protection cylinder, the electrified sheet A is contacted with the electrified sheet B, and the movable line and the conductive auxiliary line are electrified by the coordination of the electrified sheet A and the electrified sheet B, so that the heat dissipation fan body is conveniently and indirectly supplied with power.

2. According to the invention, the power connection plug and the socket on the power connection line are connected by manpower, the power switch is started after the power connection, so that current is led into the conductive auxiliary line through the conductive main line, and then the current is led into the conductive line through the conductive auxiliary line by utilizing the junction box, so that the conductive line provides power for the plurality of radiating fans, the radiating fans operate and are matched with the fan structure in the server body to radiate heat of the server body, and the server body has good heat radiation performance through the common operation of the two radiating structures.

3. According to the invention, whether the server body is installed in the interlayer installation rail and whether the radiating fan body runs or not are correlated, so that each layer of radiating fan body cannot idle, and one power supply source of a plurality of radiating fan bodies is adopted, so that the invention has the advantages of conveniently stopping the corresponding radiating fan bodies according to the installation condition of the server body, saving power and being convenient to manage.

Drawings

In order to more clearly illustrate the technical solution of the embodiments of the present invention, the drawings of the embodiments will be briefly described below.

The drawings described below are only for illustration of some embodiments of the invention and are not intended to limit the invention.

In the drawings:

fig. 1 is a schematic overall structure of an embodiment of the present invention.

Fig. 2 is a schematic diagram of the front view of fig. 1 in accordance with an embodiment of the present invention.

Fig. 3 is a schematic diagram of the bottom structure of fig. 1 in accordance with an embodiment of the invention.

Fig. 4 is a rear side structural schematic of fig. 1 of an embodiment of the present invention.

Fig. 5 is a schematic diagram of a server extraction state structure according to an embodiment of the present invention.

FIG. 6 is a schematic view of a heat dissipating structure mount and a spacer mounting rail according to an embodiment of the present invention.

Fig. 7 is another view structural schematic diagram of fig. 6 according to an embodiment of the present invention.

Fig. 8 is a schematic diagram of a semi-cut structure of an insulation shield cartridge according to an embodiment of the present invention.

FIG. 9 is a schematic view of a semi-cut structure of a barrier mounting rail according to an embodiment of the invention.

FIG. 10 is a schematic diagram of a slider and powered driver according to an embodiment of the present invention.

List of reference numerals

1. A main body frame; 101. a heat-dissipating structure mounting member; 102. a heat dissipation fan body; 103. a conductive main line; 104. a conductive sub-line; 105. energizing sheet A; 106. the movable wire can be broken; 107. a power-on sheet B; 108. a junction box; 109. a conductive wire; 1010. an insulating protective cylinder; 1011. an embedding plate; 1012. a connecting ring; 1013. a driven force receiving member; 1014. a restoring spring A; 1015. a chute; 1016. a slide block; 1017. a restoring spring B; 1018. a connecting rod; 1019. an active trigger; 1020. a rack A; 1021. a transmission gear; 2. a spacer mounting rail; 201. the electric driving piece is connected; 202. embedding a baffle; 203. a return spring C; 204. a rack B; 3. a server body; 4. a power switch; 5. and (5) connecting wires.

Detailed Description

In order to make the objects, aspects and advantages of the technical solution of the present invention more clear, the technical solution of the embodiment of the present invention will be clearly and completely described below with reference to the accompanying drawings of the specific embodiment of the present invention.

Examples: please refer to fig. 1 to 10:

the invention provides a server host with heat dissipation function, comprising: the main body frame 1, a plurality of interlayer mounting rails 2 are arranged on the left side and the right side of the inside of the main body frame 1 at equal intervals from top to bottom; a server body 3 is arranged in the interlayer mounting rail 2; the bottom of the rear side of the main body frame 1 is provided with a power switch 4; the bottom of the power switch 4 is connected with a grounding wire 5; the tail end of the electric wire 5 is provided with an electric plug; the front sides of the tops of the right interlayer mounting rails 2 are respectively provided with an electric connection driving piece 201 in a sliding insertion manner; the front side of the bottom end of the power-on driving piece 201 is of an inclined structure; the left side of the power receiving driving piece 201 is provided with an embedded baffle 202; the embedded baffle 202 is of a rectangular structure; one end of the restoring spring C203 is embedded and installed at the bottom of the embedded baffle 202; the other end of the restoring spring C203 is embedded and arranged at the top of the right interlayer mounting rail 2; a rack B204 is arranged on the right side of the power-on driving piece 201;

the power switch 4 is provided to facilitate turning on or off of the total drive power supply; the arrangement of the grounding wire 5 is used for facilitating the connection of the server host with external power socket equipment; the interlayer mounting rail 2 is provided to facilitate the mounting of the heat dissipation fan 102;

in another embodiment: the inclined surface of the power-on driving piece 201 can be provided with a protection pad, the paint surface of the shell of the server body 3 can be prevented from being scratched by the inclined surface of the power-on driving piece 201 through the arrangement of the protection pad, and the safety and the attractiveness of the server body 3 are ensured;

in another embodiment: the inside bottom of interlayer installation rail 2 can set up the commentaries on classics roller, can reduce the frictional force of server body 3 when installing in to interlayer installation rail 2 through the setting of changeing the roller, makes the inside of installing interlayer installation rail 2 that server body 3 can be more smooth and easy, can effectively reduce the artifical used power when server body 3 installs, reduces artifical physical demands.

Wherein, the right side of the main body frame 1 is provided with a plurality of heat dissipation structure mounting pieces 101 at equal intervals from top to bottom; a plurality of heat dissipation fan bodies 102 are arranged in the heat dissipation structure mounting piece 101 at equal intervals from front to back; the rear side of the main body frame 1 is provided with a conductive main line 103; the bottom end of the conductive main line 103 is connected with the power switch 4; the top of the heat dissipation structure mounting piece 101 is provided with a conductive auxiliary line 104; the tail end of the conductive auxiliary line 104 is connected with the conductive main line 103; the head end of the conductive auxiliary line 104 is provided with a power-on sheet A105; the electrifying sheet A105 is made of copper material capable of being electrified; the front side of the heat radiation structure mounting piece 101 is provided with a breakable movable wire 106; the tail end of the movable line 106 is provided with an electrifying sheet B107; the electrifying sheet B107 is made of copper material capable of being electrified; the front end of the heat radiation structure mounting piece 101 is also provided with a junction box 108;

the power switch 4 is started after the power connection is performed by manually connecting the power connection plug and the socket on the power connection wire 5, so that current is led into the conductive auxiliary wire 104 through the conductive main wire 103, and then the current is led into the conductive wire 109 through the conductive auxiliary wire 104 by utilizing the junction box 108, so that the conductive wire 109 provides power for the plurality of radiating fans 102, the radiating fans 102 operate, and the radiating fans are matched with the fan structure in the server body 3 to radiate heat to the server body 3.

Wherein, one end of the restoring spring A1014 is embedded and installed at the rear side of the driven force receiver 1013; the other end of the restoring spring a1014 is fitted to the front side of the installation plate 1011; a sliding groove 1015 is formed in the right end of the front side of the main body frame 1; a slide 1016 is slidably mounted within the chute 1015; the slider 1016 is rectangular in structure; one end of the restoring spring B1017 is embedded and installed at the bottom of the sliding block 1016; the other end of the restoring spring B1017 is embedded and arranged at the bottom of the sliding groove 1015; the right side of the slider 1016 is provided with a connecting rod 1018; the connecting rod 1018 is of cylindrical configuration; the right end of the connecting rod 1018 is provided with an active trigger 1019; the bottom end of the active trigger piece 1019 is of an inclined structure; the bottom slope of the driving trigger 1019 contacts the top slope of the driven force member 1013; a rack A1020 is arranged on the left side of the slide block 1016; a transmission gear 1021 is arranged on the right side of the inside of the main body frame 1; the transmission gear 1021 is simultaneously connected with the rack A1020 and the rack B204 in a meshed manner;

by manually placing the server body 3 into the interlayer mounting rail 2, in the mounting process, the server body 3 pushes the inclined plane of the power-on driving piece 201, so that the power-on driving piece 201 is pushed by the inclined plane to drive the rack B204 to move upwards, the rack B204 drives the rack B204 and the sliding block 1016 to move downwards along the sliding groove 1015 under the action of the transmission gear 1021, the sliding block 1016 drives the driving trigger piece 1019 to press the inclined plane of the driven force-bearing piece 1013 under the action of the connecting rod 1018, the driven force-bearing piece 1013 is stressed to drive the connecting ring 1012, the breakable movable wire 106 and the electrifying piece B107 to move backwards along the insulation protection cylinder 1010, the conduction auxiliary wire 104 and the breakable movable wire 106 are conveniently electrified, and the necessary step of placing the server body 3 into the interlayer mounting rail 2 is taken as the triggering action of electrifying work, so that a corresponding group of radiating fans 102 are conveniently electrified;

in another embodiment: the surface of the sliding block 1016 in contact with the sliding groove 1015 can be provided with a ball, so that the sliding block 1016 can move along the sliding groove 1015 more smoothly, the abrasion consumption of the sliding block 1016 and the sliding groove 1015 is reduced, and the service lives of the sliding block 1016 and the sliding groove 1015 are prolonged.

Wherein the junction box 108 is connected with the head end of the conductive auxiliary line 104; the bottom of each junction box 108 is connected with three conductive wires 109; the tail end of each conductive wire 109 is connected with one heat dissipation fan 102; the top front side of the heat radiation structure mounting member 101 is provided with an insulation protection cartridge 1010; the insulating protective cylinder 1010 has a cylindrical structure; energizing tab a105 and energizing tab B107 are both located inside insulating shield canister 1010; a mounting plate 1011 is provided on the circumferential outer wall of the insulation shield 1010; the embedded plate 1011 has a rectangular structure; a connecting ring 1012 is also arranged inside the insulating protective barrel 1010; the connecting ring 1012 has a circular ring structure; the connection ring 1012 is connected with the breakable movable wire 106; the top of the connection ring 1012 is provided with a driven force bearing member 1013; the top of the driven force receiver 1013 is of an inclined structure;

when the electrifying sheet A105 contacts with the electrifying sheet B107, the electrifying sheet A105 is matched with the electrifying sheet B107 to electrify the movable line 106 and the conductive auxiliary line 104, so that current can enter the radiating fan 102 through the junction box 108 and the conductive line 109, and the radiating fan 102 is indirectly supplied with power, so that the radiating fan 102 is convenient to operate, when the server host is used, only when the server body 3 is installed in the interlayer, the corresponding group of radiating fans 102 can be electrified to work, when the server body 3 is not installed in the interlayer, the corresponding group of radiating fans 102 can be powered off to wait, the radiating fan 102 corresponding to the interlayer of the non-installed server body 3 and the radiating fan 102 corresponding to the interlayer of the installed server are not simultaneously operated, and the radiating fan 102 is wasted in idle running without wasting electric power resources.

Specific use and action of the embodiment: when in use, firstly, the server body 3 is manually placed into the interlayer mounting rail 2, during the mounting process, the server body 3 pushes the inclined plane of the electric connection driving piece 201, so that the electric connection driving piece 201 is pushed by the inclined plane to drive the rack B204 to move upwards, the rack B204 drives the rack B204 and the sliding block 1016 to move downwards along the sliding groove 1015 under the action of the transmission gear 1021, the sliding block 1016 drives the driving triggering piece 1019 to press the inclined plane of the driven stress piece 1013 under the action of the connecting rod 1018, the driven stress piece 1013 is stressed to drive the connecting ring 1012, the movable wire 106 and the electrifying piece B107 to move backwards along the insulation protection cylinder 1010, thereby facilitating electrifying the conductive auxiliary wire 104 and the movable wire 106, thereby the step of placing the server body 3 into the interlayer mounting rail 2 is used as the triggering action of electrifying work, facilitating electrifying a corresponding group of heat dissipation fan 102, when the electrifying sheet A105 contacts with the electrifying sheet B107, the electrifying sheet A105 is matched with the electrifying sheet B107 to electrify the movable line 106 and the conductive auxiliary line 104, so that current can enter the radiating fan 102 through the junction box 108 and the conductive line 109, the radiating fan 102 is indirectly supplied with power, the radiating fan 102 is convenient to operate, when the server host is used, only when the server body 3 is installed in the interlayer, the corresponding group of radiating fan 102 can be electrified to work, when the server body 3 is not installed in the interlayer, the corresponding group of radiating fan 102 can be powered off to wait, the radiating fan 102 corresponding to the interlayer of the non-installed server body 3 and the radiating fan 102 corresponding to the interlayer of the installed server are not simultaneously operated, the radiating fan 102 wastes idle running and wastes power resources, after the electrifying preparation work is completed, the power switch 4 is started after the power connection is performed by manually connecting the power connection plug and the socket on the power connection wire 5, so that current is led into the conductive auxiliary wire 104 through the conductive main wire 103, and then the current is led into the conductive wire 109 through the conductive auxiliary wire 104 by utilizing the junction box 108, so that the conductive wire 109 provides power for the plurality of radiating fans 102, the radiating fans 102 operate, and the radiating fans are matched with the fan structure in the server body 3 to radiate heat to the server body 3.

Claims

1. A server host with heat dissipation function, comprising: the device comprises a main body frame (1), wherein a plurality of interlayer mounting rails (2) are arranged on the left side and the right side of the inside of the main body frame (1) at equal intervals from top to bottom; a server body (3) is arranged in the interlayer mounting rail (2); a power switch (4) is arranged at the bottom of the rear side of the main body frame (1); the bottom of the power switch (4) is connected with a connecting wire (5); the tail end of the electric wire (5) is provided with an electric plug; the front sides of the tops of the interlayer mounting rails (2) on the right side are all provided with an electric connection driving piece (201) in a sliding insertion manner; the front side of the bottom end of the power-on driving piece (201) is of an inclined structure; an embedded baffle plate (202) is arranged on the left side of the power-on driving piece (201); the embedded baffle plate (202) is of a rectangular structure; one end of a restoring spring C (203) is embedded and installed at the bottom of the embedded baffle plate (202); the other end of the restoring spring C (203) is embedded and arranged at the top of the right interlayer mounting rail (2); the right side of the power-on driving piece (201) is provided with a rack B (204).

2. The server host with heat dissipation function as recited in claim 1, wherein: a plurality of heat dissipation structure mounting pieces (101) are arranged on the right side of the main body frame (1) from top to bottom at equal intervals; a plurality of radiating fan bodies (102) are arranged in the radiating structure mounting piece (101) at equal intervals from front to back; the rear side of the main body rack (1) is provided with a conductive main line (103); the bottom end of the conductive main line (103) is connected with the power switch (4).

3. The server host with heat dissipation function as set forth in claim 2, wherein: a conductive auxiliary line (104) is arranged at the top of the heat dissipation structure mounting piece (101); the tail end of the conductive auxiliary line (104) is connected with the conductive main line (103); the head end of the conductive auxiliary line (104) is provided with a power-on sheet A (105); the electric sheet A (105) is made of copper material capable of being electrified.

4. A server host with heat dissipation as recited in claim 3, wherein: a movable line (106) is arranged on the front side of the heat radiation structure mounting piece (101); the tail end of the movable line (106) is provided with a power-on sheet B (107); the electrifying sheet B (107) is made of copper material capable of being electrified; the front end of the heat dissipation structure mounting piece (101) is also provided with a junction box (108).

5. The server host with heat dissipation function as recited in claim 4, wherein: the junction box (108) is connected with the head end of the conductive auxiliary line (104); the bottom of each junction box (108) is connected with three conductive wires (109); the tail end of each conductive wire (109) is connected with one heat dissipation fan body (102).

6. The server host with heat dissipation function as recited in claim 5, wherein: an insulating protection cylinder (1010) is arranged on the front side of the top of the heat radiation structure mounting piece (101); the insulating protection cylinder (1010) is of a cylindrical structure; the energizing sheet A (105) and the energizing sheet B (107) are both positioned in the insulating protective cylinder (1010); an embedding plate (1011) is arranged on the circumferential outer wall of the insulation protection cylinder (1010); the embedded plate (1011) is of a rectangular structure.

7. The server host with heat dissipation function as recited in claim 6, wherein: a connecting ring (1012) is further arranged inside the insulating protection barrel (1010); the connecting ring (1012) is of a circular ring structure; the connecting ring (1012) is connected with the movable wire (106); the top of the connecting ring (1012) is provided with a driven stress piece (1013); the top of the driven stress piece (1013) is of an inclined structure.

8. The server host with heat dissipation function as recited in claim 7, wherein: one end of a restoring spring A (1014) is embedded and installed at the rear side of the driven stress piece (1013); the other end of the restoring spring A (1014) is embedded and installed on the front side of the embedded plate (1011); a sliding groove (1015) is formed in the right end of the front side of the main body frame (1).

9. The server host with heat dissipation function as recited in claim 8, wherein: a sliding block (1016) is arranged in the sliding groove (1015) in a sliding manner; the slider (1016) is of rectangular structure; one end of a restoring spring B (1017) is embedded and installed at the bottom of the sliding block (1016); the other end of the restoring spring B (1017) is embedded and arranged at the bottom of the sliding groove (1015); a connecting rod (1018) is arranged on the right side of the sliding block (1016); the connecting rod (1018) is of cylindrical configuration.

10. The server host with heat dissipation function as recited in claim 9, wherein: the right end of the connecting rod (1018) is provided with an active trigger piece (1019); the bottom end of the active trigger piece (1019) is of an inclined structure; the bottom inclined surface of the driving trigger piece (1019) is contacted with the top inclined surface of the driven stressed piece (1013); a rack A (1020) is arranged on the left side of the sliding block (1016); a transmission gear (1021) is arranged on the right side of the inside of the main body frame (1); the transmission gear (1021) is simultaneously connected with the rack A (1020) and the rack B (204) in a meshed manner.