CN110955301B - Server cabinet and server installation structure thereof - Google Patents

Abstract

The invention discloses a server mounting structure which comprises a cross beam arranged between longitudinal beams on two sides of the front end of a cabinet body and between longitudinal beams on two sides of the rear end of the cabinet body, X-axis sliding rods which are transversely movably connected to the cross beams on the front end and the rear end and are simultaneously distributed on two transverse sides of the cross beam, a driving mechanism arranged on the cross beam and used for driving the X-axis sliding rods to move, a Y-axis sliding block arranged on the X-axis sliding rods and capable of moving along the length direction of the X-axis sliding rods, a Z-axis sliding block vertically movably arranged on the surface of the Y-axis sliding block, and a mounting plate arranged on the Z-axis sliding block and used for supporting and clamping a server case from two sides. The server mounting structure disclosed by the invention can simplify the mounting form of the server in the cabinet, is convenient for the dismounting operation of the server in the cabinet, improves the dismounting operation efficiency of operators and reduces the labor intensity. The invention also discloses a server cabinet, which has the beneficial effects as described above.

Description

Server cabinet and server installation structure thereof

Technical Field

The invention relates to the technical field of servers, in particular to a server installation structure. The invention also relates to a server cabinet.

Background

With the development of the electronic technology in China, more and more electronic devices have been widely used.

Servers are important components in electronic devices, and are devices that provide computing services. Since the server needs to respond to and process the service request, the server generally has the capability of assuming and securing the service. The server is divided into a file server, a database server, an application server, a WEB server and the like according to different service types provided by the server. The main components of the server include a processor, a hard disk, a memory, a system bus, etc., and are similar to a general-purpose computer architecture, but the server is required to have high processing capability, stability, reliability, security, expandability, manageability, etc., because it needs to provide highly reliable services.

In the big data era, a large number of IT devices are centrally located in a data center. These data centers include various types of servers, storage, switches, and a large number of cabinets and other infrastructure. Each type of IT equipment is composed of various hardware boards, such as a computing module, a memory module, a chassis, a fan module, and the like. Hardware equipment is required to be installed and maintained, in order to improve maintenance efficiency and improve the service efficiency of the equipment, the fixing, installing and maintaining modes of various modules in the equipment are required to be continuously optimized, and high-efficiency installation and maintenance are achieved under the condition that the cost is not increased.

At present, forty left and right servers can be placed to the rack of ordinary specification, and every server all need pass through fasteners such as fixing bolt and fix in the rack, just so lead to the structure between a plurality of servers very inseparable, just very inconvenient when installing the server or need to dismantle the server, operation such as maintenance, operating space is narrower not only, the staff is difficult to the application of force, and in the dismouting in-process, need twist in proper order a plurality of bolts, staff's intensity of labour is great, and dismouting operating efficiency is low.

Therefore, how to simplify the installation form of the server in the cabinet, facilitate the dismounting operation of the server in the cabinet, improve the dismounting operation efficiency of the operator, and reduce the labor intensity is a technical problem faced by the technical personnel in the field.

Disclosure of Invention

The invention aims to provide a server mounting structure which can simplify the mounting form of a server in a cabinet, facilitate the dismounting operation of the server in the cabinet, improve the dismounting operation efficiency of operators and reduce the labor intensity. Another object of the present invention is to provide a server rack.

In order to solve the technical problems, the invention provides a server mounting structure which comprises a cross beam arranged between longitudinal beams on two sides of the front end and between longitudinal beams on two sides of the rear end of a cabinet body, an X-axis sliding rod which is connected to the cross beams on the front end and the rear end in a transversely movable manner and is distributed on two transverse sides of the cross beam, a driving mechanism which is arranged on the cross beam and is used for driving the X-axis sliding rod to move, a Y-axis sliding block which is arranged on the X-axis sliding rod and can move along the length direction of the X-axis sliding rod, a Z-axis sliding block which is arranged on the surface of the Y-axis sliding block in a vertically movable manner, and a mounting plate which is arranged on the Z-axis sliding block and is used for supporting and clamping a server case from two sides.

Preferably, the mounting plate is specifically an L-shaped plate, and a horizontal side of the mounting plate is used for supporting the bottom of the server chassis, and a vertical side of the mounting plate is used for abutting against a side wall of the server chassis.

Preferably, a plurality of balls for reducing friction between the balls and the bottom surface of the server case are embedded on the surface of the horizontal side of the mounting plate, and an elastic pad for increasing pressing force on the side wall of the server case is tightly attached to the vertical side of the mounting plate.

Preferably, the inner side surface of the Y-axis sliding block is an inclined surface, and a wedge-shaped groove is formed in the inclined surface; the bottom surface of the Z-axis sliding block is an inclined surface and is slidably arranged in the wedge-shaped groove, so that the Y-axis sliding block can be obliquely lifted along the inclined surface when moving along the transverse direction.

Preferably, a spring is connected to a groove wall of the wedge-shaped groove, and a tail end of the spring is connected to a side wall of the Z-axis sliding block so as to be driven to slide in the wedge-shaped groove by the aid of elastic force.

Preferably, the Y-axis sliding block further comprises transverse limiting rods which are transversely and simultaneously arranged on the front end faces of the Y-axis sliding blocks at two sides, transverse limiting sliding grooves with preset lengths are formed in the two sides of the surface of each transverse limiting rod along the length direction of the transverse limiting rod, and T-shaped rods used for sliding in the transverse limiting sliding grooves are vertically arranged on the front end faces of the Y-axis sliding blocks so as to limit the maximum transverse displacement of the Y-axis sliding blocks.

Preferably, a push-pull handle is arranged in the middle of the surface of the transverse limiting rod and used for being grasped by a human hand to drive the Y-axis sliding blocks to move along the length direction of the X-axis sliding rod.

Preferably, the inner side surface of the cross beam is provided with transverse slide rails along the length direction thereof, and two ends of each X-axis slide rod are slidably arranged in the transverse slide rails respectively; the driving mechanism comprises a rotating shaft, a gear, a first rack and a second rack, wherein the rotating shaft is rotatably connected between the cross beams at the front end and the rear end, the gear is sleeved on the rotating shaft, one end of the first rack is connected with one side wall of the X-axis sliding rod, the other end of the first rack is in meshing transmission with the top of the gear, and one end of the second rack is connected with the other side wall of the X-axis sliding rod, and the other end of the second rack is in meshing transmission with the bottom of the gear.

Preferably, a plurality of clamping grooves are formed in the end face of the outer end of the cross beam in the circumferential direction of the rotating shaft, a rotating disc for a human hand to rotate is further arranged on the end face of the outer end of the cross beam, and the tail end of the rotating shaft is connected to the inner surface of the rotating disc; the surface of the rotary table is detachably inserted with a locking bolt penetrating through the rotary table, and the tail end of the locking bolt extends into the corresponding clamping groove.

The invention further provides a server cabinet, which comprises a cabinet body and a server mounting structure arranged in the cabinet body, wherein the server mounting structure is specifically any one of the server mounting structures.

The invention provides a server installation structure which mainly comprises a cross beam, an X-axis sliding rod, a driving mechanism, a Y-axis sliding block, a Z-axis sliding block and an installation plate. The transverse beams are arranged between the longitudinal beams on the two sides of the front end of the cabinet body, and are also arranged between the longitudinal beams on the two sides of the rear end of the cabinet body, and the transverse beams and the longitudinal beams are generally horizontally arranged and mainly used as installation basic mechanisms of other parts and servers. The two ends of the X-axis sliding rod are respectively connected to the cross beams at the front end and the rear end, and can transversely move on the cross beams along the length direction of the cross beams, and two X-axis sliding rods are generally arranged on the cross beams at the same time and are respectively located at the two transverse sides of the cross beams. The driving mechanism is arranged on the cross beam and is mainly used for driving the X-axis sliding rod to transversely reciprocate on the cross beam. The Y-axis slide block is arranged on the X-axis slide rod and can move along the length direction of the X-axis slide rod. The Z-axis slide block is disposed on the surface of the Y-axis slide block and is movable in the vertical direction on the surface thereof. The mounting plate is arranged on the Z-axis sliding block and is mainly used for supporting the server case and clamping the server case. Therefore, the mounting plate can perform spatial three-dimensional motion in the cabinet through the compound motion of the X-axis sliding rod, the Y-axis sliding block and the Z-axis sliding block on the cross beam, so that the mounting plate can clamp or loosen the side wall of the server case by adjusting the transverse sliding position of the X-axis sliding rod when the server is dismounted; meanwhile, the longitudinal sliding position of the Y-axis sliding block on the X-axis sliding rod can be adjusted, so that the mounting plate drives the server case to be pushed into or pulled out of the cabinet; still can be through adjusting the vertical sliding position of Z axle sliding block on Y axle sliding block for the mounting panel drives server machine case and carries out elevating movement, thereby adjusts the height of server machine case, makes things convenient for the staff to get and puts. In conclusion, the server installation structure provided by the invention can simplify the installation form of the server in the cabinet, is convenient for the dismounting operation of the server in the cabinet, improves the dismounting operation efficiency of operators and reduces the labor intensity.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the provided drawings without creative efforts.

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

Fig. 2 is a cross-sectional half view of fig. 1.

Fig. 3 is a longitudinal half-sectional view of fig. 2.

Fig. 4 is an enlarged schematic view of a specific structure of the circle a shown in fig. 2.

Fig. 5 is a schematic structural diagram of a server installation structure in a server cabinet according to an embodiment of the present invention.

Wherein, in fig. 1-5:

a server chassis-a;

the cabinet comprises a cabinet body-1, longitudinal beams-2, cross beams-3, an X-axis sliding rod-4, a driving mechanism-5, a Y-axis sliding block-6, a Z-axis sliding block-7, a mounting plate-8, balls-9, elastic pads-10, springs-11, transverse limiting rods-12, transverse limiting sliding grooves-13, T-shaped rods-14, push-pull handles-15 and T-shaped sliding blocks-16;

the device comprises a transverse sliding rail-301, a rotating shaft-501, a gear-502, a first rack-503, a second rack-504, a rotating disc-505 and a locking bolt-506.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1 to 3, fig. 1 is a schematic overall structure diagram of an embodiment of the present invention, fig. 2 is a cross-sectional half view of fig. 1, and fig. 3 is a cross-sectional half view of fig. 2.

In a specific embodiment provided by the invention, the server installation structure mainly comprises a beam 3, an X-axis sliding rod 4, a driving mechanism 5, a Y-axis sliding block 6, a Z-axis sliding block 7 and an installation plate 8.

The cross beam 3 is arranged between the longitudinal beams 2 on the two sides of the front end of the cabinet body 1, and is also arranged between the longitudinal beams 2 on the two sides of the rear end of the cabinet body 1, and the two are generally horizontally arranged and have consistent height positions and are mainly used as installation bases of other parts and servers. Meanwhile, the server mounting structures are generally simultaneously provided with a plurality of servers in the vertical direction in the server cabinet, and each server mounting structure can simultaneously mount a plurality of servers, so that each cross beam 3 can be uniformly arranged on the cabinet body 1 according to the mounting height of the server, and can be detachably connected with the longitudinal beam 2 through a fastener.

The two ends of the X-axis sliding rod 4 are respectively connected to the cross beams 3 at the front and rear ends, and can move transversely on the cross beams 3 along the length direction thereof, and two X-axis sliding rods are generally arranged on the cross beams 3 at the same time and are respectively located at the two transverse sides of the cross beams 3. The driving mechanism 5 is arranged on the cross beam 3 and is mainly used for driving the X-axis sliding rods 4 at two sides to transversely reciprocate on the cross beam 3, generally, the driving mechanism 5 drives the two X-axis sliding rods 4 synchronously and reversely, that is, the two X-axis sliding rods 4 can move oppositely or back to back on the cross beams 3 at two ends.

The Y-axis slide block 6 is provided on the X-axis slide lever 4 and is movable in the longitudinal direction thereof. The Z-axis slider 7 is provided on the surface of the Y-axis slider 6 and is movable in the vertical direction on the surface thereof. The mounting plate 8 is arranged on the Z-axis sliding block 7 and is mainly used for supporting the server case a and clamping the server case a.

Thus, the mounting plate 8 can perform spatial three-dimensional motion in the cabinet through the compound motion of the X-axis sliding rod 4, the Y-axis sliding block 6 and the Z-axis sliding block 7 on the cross beam 3, so that the mounting plate 8 can clamp or loosen the side wall of the server case a by adjusting the transverse sliding position of the X-axis sliding rod 4 when the server is dismounted; meanwhile, the longitudinal sliding position of the Y-axis sliding block 6 on the X-axis sliding rod 4 can be adjusted, so that the mounting plate 8 drives the server case a to be pushed into or pulled out of the cabinet; still can be through adjusting the vertical sliding position of Z axle sliding block 7 on Y axle sliding block 6 for mounting panel 8 drives server machine case a and carries out elevating movement, thereby adjusts server machine case a's height, makes things convenient for the staff to get and puts.

In conclusion, the server installation structure provided by the embodiment can simplify the installation form of the server in the cabinet, is convenient for the dismounting operation of the server in the cabinet, improves the dismounting operation efficiency of operators, and reduces the labor intensity.

In a preferred embodiment with respect to the mounting plate 8, the mounting plate 8 may be embodied as an L-shaped plate, i.e. having two mutually perpendicular sides, which for the sake of convenience may be referred to as horizontal and vertical sides, respectively. The horizontal side of the mounting plate 8 is mainly used for supporting the bottom of the server case a, and the vertical side of the mounting plate 8 is mainly used for abutting against the side wall of the server case a. Because X axle slide bar 4 is located the horizontal left and right sides position of crossbeam 3 respectively, consequently the mounting panel 8 also distributes in the horizontal left and right sides position of crossbeam 3 to the mounting panel 8 of both sides can just be just to arranging, so, the horizontal side of both sides mounting panel 8 can be used for bearing the bottom left and right sides of server machine case an respectively, and the vertical side of both sides mounting panel 8 can inwards press from both sides tight server machine case a's lateral wall simultaneously, thereby improve the installation stability of server machine case a in server mounting structure.

Further, this embodiment has set up a plurality of ball 9 on the surface of the horizontal side of mounting panel 8 to each ball 9 can roll on the surface of horizontal side, so set up, when the staff lays server machine case a on mounting panel 8, can reduce frictional force and wearing and tearing through the rolling friction of each ball 9 and server machine case a bottom surface. Meanwhile, the elastic pad 10 is closely arranged on the vertical side edge of the mounting plate 8 in the embodiment. Specifically, the elastic pad 10 may be a rubber pad, a sponge pad, or the like, and may be adhered to the surface of the vertical side by an adhesive. So set up, the elastic deformation of accessible cushion 10 improves the effect that compresses tightly of both sides mounting panel 8 to server machine case a lateral wall.

In order to facilitate the vertical movement of the mounting plate 8, in this embodiment, the inner side surface of the Y-axis sliding block 6 is specifically an inclined surface, and a wedge-shaped groove is formed on the inclined surface. Meanwhile, the bottom surface of the Z-axis slide block 7 is also an inclined surface and slides in cooperation with the wedge groove on the inner side surface of the Y-axis slide block 6. So set up, the cross sectional shape of Y axle sliding block 6 will be right triangle-shaped to the inclined plane of the Y axle sliding block 6 of both sides all inwards, and Z axle sliding block 7 passes through Y axle sliding block 6 to the butt on its inclined plane in the lateral shifting process, passes through inclined plane component force with lateral motion and turns into vertical motion, also is accompanied with the motion along the inclined plane simultaneously certainly. Therefore, when the Y-axis slider 6 moves in the transverse direction, the Z-axis slider 7 will perform the tilt up-and-down movement along the inclined surface of the Y-axis slider 6, and further drive the mounting plate 8 to perform the synchronous tilt up-and-down movement. Generally, the included angle of the inclined plane of the Y-axis sliding block 6 can be 15-45 °.

Further, in this embodiment, the springs 11 are provided on the groove walls of the wedge-shaped groove of the Y-axis slide block 6, and the ends of the springs 11 are connected to the side walls of the Z-axis slide block 7, so that when the Z-axis slide block 7 performs a tilting up-down motion in the wedge-shaped groove, the springs 11 are compressed or extended, and the springs 11 accumulate elastic force, so that when the Z-axis slide block 7 starts to perform a reverse motion, the Z-axis slide block 7 can be driven to move in an auxiliary manner, and when the server is installed, the pressing force of the installation plate 8 against the side walls of the server casing a can be increased by abutting against the Z-axis slide block 7.

Of course, the Z-axis slider 7 may perform vertical lifting movement on the surface of the Y-axis slider 6.

For stably realizing the slip of Y axle sliding block 6 on X axle slide bar 4, make things convenient for the staff to impel the server or pull out the rack, add horizontal gag lever post 12 and push-and-pull handle 15 in this embodiment. Specifically, the transverse limiting rod 12 may be disposed parallel to the cross beam 3, and the length of the transverse limiting rod 12 is equivalent to that of the cross beam 3, except that the transverse limiting rod 12 is disposed on the front end surfaces of the Y-axis sliding blocks 6 on the two sides in a manner of being transversely attached to each other. Meanwhile, the horizontal limiting sliding grooves 13 are formed in the horizontal two side positions of the surface of the horizontal limiting rod 12, and the horizontal limiting sliding grooves 13 extend for a preset length along the length direction of the horizontal limiting rod 12. Correspondingly, T-shaped rods 14 are vertically arranged on the front end surfaces of the Y-axis sliding blocks 6 on the two sides, the T-shaped rods 14 can be in a structure such as an i-shaped nail, the rod parts of the T-shaped rods are embedded into the transverse limiting sliding grooves 13, and the head parts of the T-shaped rods extend out of the transverse limiting sliding grooves 13 and can transversely slide in the transverse limiting sliding grooves 13. Since the T-bar 14 is connected to the Y-axis sliding block 6, when the T-bar 14 slides in the transverse limiting sliding slot 13, the Y-axis sliding block 6 is driven to synchronously slide transversely. And because horizontal spacing spout 13 has and predetermines length, consequently can restrict the biggest lateral displacement of Y axle sliding block 6, prevent that the interval of the Y axle sliding block 6 of both sides is too big or undersize, and then prevent that the horizontal curb plate of both sides mounting panel 8 from breaking away from the bottom of server machine case a, prevent to hold up server machine case a too high simultaneously and lead to the unstability.

As mentioned above, the push-pull handle 15 can be generally disposed at the middle position of the surface of the horizontal limiting rod 12 (without interfering with the horizontal limiting chutes 13 on both sides), so that the user can grip the push-pull handle 15 by hand and apply force, thereby facilitating the user to grip the push-pull handle 15 and apply force in the longitudinal direction. Meanwhile, because the T-shaped rods 14 are embedded in the transverse limiting sliding grooves 13, when a worker pushes or pulls the push-pull handles 15 inwards or outwards along the longitudinal direction, the worker can push or pull the Y-axis sliding blocks 6 on the two sides to longitudinally slide on the X-axis sliding rods 4 through the abutting acting force of the transverse limiting rods on the T-shaped rods 14 on the two sides, and then push or pull the server into or out of the cabinet. Here, the Y-axis slide block 6 and the X-axis slide rod 4 are preferably connected to each other by a T-shaped slider 16 for relative sliding.

As for the relative sliding between the X-axis sliding rod 4 and the cross beam 3, in this embodiment, the inner surfaces of the cross beams 3 at the front and rear ends are provided with the transverse sliding rails 301 along the length direction thereof, and the two ends of the X-axis sliding rod 4 can be respectively arranged in the transverse sliding rails 301 at the two ends. Meanwhile, in order to facilitate the worker to control the clamping and loosening and the height adjustment of the mounting plate 8 on the server case a when the server is dismounted, in the embodiment, the driving mechanism 5 is used for driving the transverse movement of the X-axis sliding rod 4 on the cross beam 3 to realize the simultaneous operation.

As shown in fig. 4, fig. 4 is an enlarged schematic view of a specific structure of the circle a shown in fig. 2.

Specifically, the driving mechanism 5 mainly includes a rotating shaft 501, a gear 502, a first rack 503 and a second rack 504.

The rotating shaft 501 is longitudinally connected between the front end beam 3 and the rear end beam 3, and is generally located at the transverse center of the two end beams 3, and the two ends of the rotating shaft 501 are rotatably connected with the beams 3, so that the rotating shaft can rotate. The gear 502 is sleeved on the rotating shaft 501 and rotates synchronously with the rotating shaft 501. One end of the first rack 503 is connected to the side wall of one of the X-axis sliding rods 4, and the other end thereof is in meshing transmission with the top teeth of the gear 502, and correspondingly, one end of the second rack 504 is connected to the side wall of the other X-axis sliding rod 4, and the other end thereof is in meshing transmission with the bottom teeth of the gear 502. With such arrangement, the gear 502 is driven to rotate by the rotation of the rotating shaft 501, and then the first rack 503 and the second rack 504 are driven to move oppositely or move back to back by the meshing transmission between the gear 502 and the first rack 503 and the second rack 504, so as to drive the X-axis sliding rods 4 on the two sides to move oppositely or move back to back.

The gear 502 can be disposed at the middle position of the rotating shaft 501, and the first rack 503 and the second rack 504 also respectively push the middle position of the side walls of the X-axis sliding rod 4 at the two sides. Meanwhile, a plurality of groups of transmission mechanisms consisting of the gear 502, the first rack 503 and the second rack 504 can be arranged along the longitudinal direction, and can be uniformly distributed in the length direction of the rotating shaft 501.

Further, considering that the server has a certain weight and when it is placed on the mounting plate 8, the Y-axis slide block 6 and the Z-axis slide bar are pushed in reverse by gravity to move in the lateral direction, for this, the turntable 505 and the locking bolt 506 are added to the cross beam 3.

Specifically, the turntable 505 is rotatably disposed on an outer end surface of the beam 3, and an end of the rotating shaft 501 penetrates through the beam 3 and is connected to an inner surface of the turntable 505, so that a worker can drive the rotating shaft 501 to rotate by rotating the turntable 505. Meanwhile, the locking bolt 506 is inserted into the edge position of the surface of the rotating disc 505 and penetrates through the rotating disc 505 to form an eccentric arrangement with the rotating shaft 501. Correspondingly, in the area corresponding to the turntable 505 on the end face of the outer end of the cross beam 3, a plurality of clamping grooves are formed around the circumference of the rotating shaft 501, the clamping grooves are mainly used for being matched with the locking bolts 506, and the locking bolts 506 have enough length and can extend into the clamping grooves to be clamped with the clamping grooves after penetrating through the turntable 505. With the arrangement, after the locking bolt 506 is inserted into the card slot, a locking effect is formed on the rotating disc 505, and at the moment, the rotating disc 505 cannot rotate, so that the rotating shaft 501 is locked, and therefore reverse rotation caused by the weight of the server can be avoided. Certainly, when the worker needs to disassemble and assemble the server, the worker only needs to take down the locking bolt 506 from the turntable 505 first, unlock the turntable 505 and then screw the turntable 505, so that the height adjustment and clamping loosening of the mounting plate 8 on the server case a can be achieved smoothly.

Fig. 5 is a schematic structural diagram of a server installation structure in a server cabinet according to an embodiment of the present invention, as shown in fig. 5.

This embodiment still provides a server rack, mainly includes cabinet 1 and the server mounting structure of setting in cabinet 1, and wherein, this server mounting structure's main content is the same with above-mentioned relevant content, and it is no longer repeated here.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (7)

1. A server mounting structure is characterized by comprising a cross beam (3) arranged between longitudinal beams (2) on two sides of the front end of a cabinet body (1) and between longitudinal beams (2) on two sides of the rear end, an X-axis sliding rod (4) which is connected to the cross beam (3) on the front end and the rear end in a transversely movable manner and is simultaneously distributed on two transverse sides of the cross beam, a driving mechanism (5) which is arranged on the cross beam (3) and is used for driving the X-axis sliding rod (4) to move, a Y-axis sliding block (6) which is arranged on the X-axis sliding rod (4) and can move along the length direction of the X-axis sliding rod, a Z-axis sliding block (7) which is arranged on the surface of the Y-axis sliding block (6) in a vertically movable manner, and a mounting plate (8) which is arranged on the Z-axis sliding block (7) and is used for supporting and clamping a server case (a) from two sides;

the transverse limiting rod (12) is transversely and simultaneously arranged on the front end faces of the Y-axis sliding blocks (6) on the two sides, transverse limiting sliding grooves (13) with preset lengths are formed in the two side positions of the surface of the transverse limiting rod (12) along the length direction of the transverse limiting sliding grooves, T-shaped rods (14) used for sliding in the transverse limiting sliding grooves (13) are vertically arranged on the front end faces of the Y-axis sliding blocks (6) so as to limit the maximum transverse displacement of the Y-axis sliding blocks (6), and the horizontal side plates of the mounting plate (8) are prevented from being separated from the bottom of the server case (a) and lifting the server case (a) too high to cause instability;

the inner side surface of the cross beam (3) is provided with transverse slide rails (301) along the length direction, and two ends of each X-axis slide rod (4) are slidably arranged in the transverse slide rails (301) respectively; the driving mechanism (5) comprises a rotating shaft (501) rotatably connected between the cross beams (3) at the front end and the rear end, a gear (502) sleeved on the rotating shaft (501), a first rack (503) with one end connected with the side wall of one X-axis sliding rod (4) and the other end in meshing transmission with the top of the gear (502), and a second rack (504) with one end connected with the side wall of the other X-axis sliding rod (4) and the other end in meshing transmission with the bottom of the gear (502);

a plurality of clamping grooves are formed in the outer end face of the cross beam (3) in the circumferential direction of the rotating shaft (501), a rotating disc (505) for a human hand to rotate is further arranged on the outer end face of the cross beam (3), and the tail end of the rotating shaft (501) is connected to the inner surface of the rotating disc (505); locking bolts (506) penetrating through the rotary disc (505) are detachably inserted into the surface of the rotary disc, and the tail ends of the locking bolts (506) extend into the corresponding clamping grooves.

2. The server mounting structure according to claim 1, wherein the mounting plate (8) is an L-shaped plate, and has horizontal sides for supporting the bottom of the server casing (a) and vertical sides for abutting against the side walls of the server casing (a).

3. The server mounting structure according to claim 2, wherein a plurality of balls (9) for reducing friction with the bottom surface of the server casing (a) are embedded on the surface of the horizontal side of the mounting plate (8), and an elastic pad (10) for increasing pressing force against the side wall of the server casing (a) is closely attached to the vertical side of the mounting plate (8).

4. The server mounting structure according to claim 1, wherein the inner side surface of the Y-axis slider (6) is an inclined surface, and a wedge-shaped groove is formed on the inclined surface; the bottom surface of the Z-axis sliding block (7) is an inclined surface and is slidably arranged in the wedge-shaped groove, so that the Y-axis sliding block (6) can be obliquely lifted along the inclined surface when moving along the transverse direction.

5. The server mounting structure according to claim 4, wherein a spring (11) is connected to a wall of the wedge-shaped groove, and a distal end of the spring (11) is connected to a side wall of the Z-axis slider (7) to assist driving the sliding in the wedge-shaped groove by an elastic force.

6. The server mounting structure according to claim 1, wherein a push-pull handle (15) for being grasped by a human hand to simultaneously drive each of the Y-axis slide blocks (6) to move in a longitudinal direction of the X-axis slide bar (4) is provided at a surface middle position of the lateral stopper bar (12).

7. A server cabinet comprising a cabinet body (1) and a server mounting structure provided in the cabinet body (1), characterized in that the server mounting structure is specifically the server mounting structure of any one of claims 1 to 6.

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