CN216078919U - Program transferring module for dynamic load balancing - Google Patents

Abstract

The utility model belongs to the technical field of program transferring module maintenance, in particular to a program transferring module with balanced dynamic load, which aims at solving the problems that the transferring module in the existing working environment is often installed in a machine body through screws, the disassembly and the assembly are inconvenient and the maintenance difficulty is increased in the working process. The utility model avoids using screws to install and transfer the module body, is convenient for installation and later-period disassembly and maintenance, and reduces the maintenance difficulty.

Description

Program transferring module for dynamic load balancing

Technical Field

The utility model relates to the technical field of program transferring module maintenance, in particular to a program transferring module with dynamic load balancing.

Background

Load balancing is built on the existing network structure, and provides a cheap and effective method for expanding the bandwidth of a server, increasing the throughput, strengthening the data processing capacity of the network and improving the flexibility and the usability of the network. It mainly accomplishes the following tasks: the problem of network congestion is solved, service is provided nearby, and geographical position independence is realized; better access quality is provided for the user; the response speed of the server is improved; the utilization efficiency of the server and other resources is improved; and single-point failure of key parts of the network is avoided. The existing load balancing system composed of a scheduling module or a scheduling node and a service node schedules dynamic load balancing, for example, application number: 201110404910 discloses a system for load balancing scheduling in a cloud computing environment, which comprises a load balancer, dynamically-scheduled virtual machine resources, and a scheduling center module, and is respectively responsible for system load scheduling, user request response, and virtual machine resource scheduling functions. The dispatching center module (the dispatching module) informs the load balancer to add and delete the dispatching object of the virtual machine based on the processing of the system monitoring information, and the system dynamically adjusts the service capacity of the load balancing system.

The transfer module is installed in the organism through the screw more among the operational environment now, and there is the dismouting inconvenient in the work, increases the maintenance degree of difficulty.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the defects that in the existing working environment, the transfer module is mostly installed in a machine body through screws, and the working is inconvenient to disassemble and assemble and the maintenance difficulty is increased, and provides a program transfer module with balanced dynamic load.

In order to achieve the purpose, the utility model adopts the following technical scheme:

the utility model provides a module is transferred to balanced procedure of dynamic load, including transferring the module body, the outside of transferring the module body sets up the organism, the organism includes drain pan and top shell, fixed mounting has the backup pad in the drain pan, the vertical slidable mounting in top of backup pad has two guide arms, the equal fixed mounting in top of two guide arms has the touch panel, the touch panel contacts with the bottom of transferring the module body mutually, the top symmetry slidable mounting of backup pad has two fixed units in side, the fixed unit in side contacts with transferring the module body, the bottom of the fixed unit in side is connected with fixed unit, fixed unit and support plate looks adaptation, the outside of guide arm is connected with wire rope, wire rope's one end links to each other with the fixed unit in side, the through-hole has been seted up in the backup pad, wire rope and through-hole swing joint.

Preferably, the side fixing unit comprises a push plate and an anti-slip pad, the anti-slip pad is connected with the inner side of the push plate, the anti-slip pad is in contact with the maneuvering module body, and the steel wire rope is connected with the inner side of the push plate.

Preferably, the side fixing unit comprises an I-shaped block, a tension spring, an insert rod, a limiting slide block, a manual rod and a pressure spring, two I-shaped grooves are symmetrically formed in the top of the supporting plate, the I-shaped block is connected with the corresponding I-shaped groove in a sliding mode, one end of the tension spring is fixedly connected with the I-shaped block, the other end of the tension spring is fixedly connected with the inner wall of each I-shaped groove, the top of the I-shaped block is connected with the bottom of the push plate, a plurality of trapezoidal grooves are uniformly formed in the inner wall of the bottom of each I-shaped groove, the bottom end of the insert rod is obliquely arranged, the insert rod is slidably mounted on the I-shaped block and penetrates through the I-shaped block to be in one-way clamping connection with the trapezoidal grooves, the bottom of the limiting slide block is connected with the top end of the insert rod, and the manual rod is connected with the outer side of the limiting slide block, spacing spout has been seted up in the outside of push pedal, spacing slider and spacing spout sliding connection, and the bottom of pressure spring links to each other with spacing slider's top, and the top of pressure spring links to each other with the top inner wall of spacing spout.

Preferably, the outer side of the guide rod is sleeved with a spring, the bottom end of the spring is connected with the top of the supporting plate, and the top end of the spring is connected with the bottom of the abutting plate.

Compared with the prior art, the utility model has the advantages that:

according to the scheme, the transferring module body is placed on the tops of the two abutting plates, the transferring module body is pressed downwards, so that the push plates can be close to the transferring module body, the transferring module body is pressed and fixed by the two push plates through the two anti-slip pads, and the transferring module body is released;

according to the scheme, under the elastic force action of the pressure spring, the inserted rod enters the corresponding trapezoidal groove, so that the stability of the I-shaped block and the push plate can be ensured, and the stability of the module body during use is further ensured;

this scheme need upwards stimulate two manual levers when maintaining to transfer module body dismantlement, and manual lever drives the inserted bar and leaves the dovetail groove that corresponds, and under the pulling force effect of tension spring, the push pedal drives the slipmat and leaves transfer module body, can dismantle the maintenance of transfer module body, convenient operation.

The utility model avoids using screws to install and transfer the module body, is convenient for installation and later-period disassembly and maintenance, and reduces the maintenance difficulty.

Drawings

Fig. 1 is a schematic structural diagram of a program scheduling module for dynamic load balancing according to the present invention;

fig. 2 is a schematic structural diagram of a part a of a dynamic load balancing program scheduling module according to the present invention;

fig. 3 is a schematic top view of the maneuvering module body, the push plate, the anti-slip pad, the limiting slide block and the manual lever according to the present invention.

In the figure: 1. transferring the module body; 2. a bottom case; 3. a top shell; 4. a support plate; 5. a through hole; 6. a guide bar; 7. a touch plate; 8. a spring; 9. pushing the plate; 10. a non-slip mat; 11. an I-shaped groove; 12. an I-shaped block; 13. a tension spring; 14. inserting a rod; 15. a trapezoidal groove; 16. a limiting slide block; 17. a manual lever; 18. a pressure spring; 19. a steel cord.

Detailed Description

The technical solutions in the embodiments will be described clearly and completely with reference to the drawings in the embodiments, and it is obvious that the described embodiments are only a part of the embodiments, but not all embodiments.

Example one

Referring to fig. 1-3, a program transferring module with balanced dynamic load comprises a transferring module body 1, a machine body is arranged on the outer side of the transferring module body 1, the machine body comprises a bottom shell 2 and a top shell 3, a supporting plate 4 is fixedly installed in the bottom shell 2, two guide rods 6 are vertically and slidably installed at the top of the supporting plate 4, a touch plate 7 is fixedly installed at the top of each guide rod 6, the touch plate 7 is in contact with the bottom of the transferring module body 1, two side fixing units are symmetrically and slidably installed at the top of the supporting plate 4, the side fixing units are in contact with the transferring module body 1, fixing units are connected to the bottoms of the side fixing units, the fixing units are matched with the supporting plate 4, a steel wire rope 19 is connected to the outer side of each guide rod 6, one end of the steel wire rope 19 is connected with the side fixing units, a through hole 5 is formed in the supporting plate 4, and the steel wire rope 19 is movably connected with the through hole 5.

In this embodiment, the side fixing unit includes push pedal 9 and slipmat 10, and slipmat 10 links to each other with the inboard of push pedal 9, and slipmat 10 contacts with transferring module body 1, and wire rope 19 links to each other with the inboard of push pedal 9, sets up wire rope 19 and is used for pulling push pedal 9, and slipmat 10 increases the frictional force of push pedal 9 and transferring module body 1.

In this embodiment, the side fixing unit includes an i-shaped block 12, a tension spring 13, an insertion rod 14, a limiting slider 16, a manual lever 17, and a pressure spring 18, two i-shaped grooves 11 are symmetrically formed in the top of the support plate 4, the i-shaped block 12 is slidably connected to the corresponding i-shaped groove 11, one end of the tension spring 13 is fixedly connected to the i-shaped block 12, the other end of the tension spring 13 is fixedly connected to the inner wall of the i-shaped groove 11, the top of the i-shaped block 12 is connected to the bottom of the push plate 9, a plurality of trapezoidal grooves 15 are uniformly formed in the inner wall of the bottom of the i-shaped groove 11, the bottom end of the insertion rod 14 is obliquely arranged, the insertion rod 14 is slidably mounted on the i-shaped block 12 and penetrates through the i-shaped block 12 to be in one-way clamped connection with the trapezoidal grooves 15, the bottom of the limiting slider 16 is connected to the top end of the insertion rod 14, the manual lever 17 is connected to the outer side of the limiting slider 16, and the insertion rod 14 is connected to the trapezoidal grooves 15, so that the stability of the push plate 9 can be ensured.

In this embodiment, the spacing spout has been seted up in the outside of push pedal 9, and limiting slide block 16 and limiting slide groove sliding connection, the bottom of pressure spring 18 links to each other with limiting slide block 16's top, and the top of pressure spring 18 links to each other with the top inner wall of spacing spout, and pressure spring 18 provides decurrent elasticity for limiting slide block 16, and then makes inserted bar 14 can get into dovetail groove 15.

In this embodiment, the outside cover of guide arm 6 is equipped with spring 8, and spring 8's bottom links to each other with the top of backup pad 4, and spring 8's top links to each other with the bottom of conflict board 7, and spring 8 provides ascending elasticity for conflict board 7.

Example two

Referring to fig. 1-3, a program transferring module with balanced dynamic load comprises a transferring module body 1, a machine body is arranged on the outer side of the transferring module body 1, the machine body comprises a bottom shell 2 and a top shell 3, a supporting plate 4 is fixedly installed in the bottom shell 2, two guide rods 6 are vertically and slidably installed at the top of the supporting plate 4, a touch plate 7 is fixedly installed at the top of each guide rod 6, the touch plate 7 is in contact with the bottom of the transferring module body 1, two side fixing units are symmetrically and slidably installed at the top of the supporting plate 4, the side fixing units are in contact with the transferring module body 1, fixing units are connected to the bottoms of the side fixing units, the fixing units are matched with the supporting plate 4, a steel wire rope 19 is connected to the outer side of each guide rod 6, one end of the steel wire rope 19 is connected with the side fixing units, a through hole 5 is formed in the supporting plate 4, and the steel wire rope 19 is movably connected with the through hole 5.

In this embodiment, the side fixing unit includes push pedal 9 and slipmat 10, and slipmat 10 links to each other with the inboard of push pedal 9, and slipmat 10 contacts with transferring module body 1, and wire rope 19 links to each other with the inboard of push pedal 9, sets up wire rope 19 and is used for pulling push pedal 9, and slipmat 10 increases the frictional force of push pedal 9 and transferring module body 1.

In this embodiment, the side fixing unit includes an i-shaped block 12, a tension spring 13, and an insertion rod 14, the top of the supporting plate 4 is symmetrically provided with two I-shaped grooves 11, the I-shaped blocks 12 are connected with the corresponding I-shaped grooves 11 in a sliding mode, one end of a tension spring 13 is connected with the I-shaped blocks 12 in a welding mode, the other end of the tension spring 13 is connected with the inner walls of the I-shaped grooves 11 in a welding mode, the top of each I-shaped block 12 is connected with the bottom of the push plate 9, the inner wall of the bottom of each I-shaped groove 11 is evenly provided with a plurality of trapezoidal grooves 15, the bottom end of the insertion rod 14 is arranged in an inclined mode, the insertion rod 14 is installed on the I-shaped blocks 12 in a sliding mode and penetrates through the I-shaped blocks 12 to be connected with the trapezoidal grooves 15 in a one-way mode, the bottom of the limiting sliding block 16 is connected with the top end of the insertion rod 14, the manual rod 17 is connected with the outer side of the limiting sliding block 16, and the insertion rod 14 is connected with the trapezoidal grooves 15 so that the stability of the push plate 9 can be guaranteed.

In this embodiment, the spacing spout has been seted up in the outside of push pedal 9, and limiting slide block 16 and limiting slide groove sliding connection, the bottom of pressure spring 18 links to each other with limiting slide block 16's top, and the top of pressure spring 18 links to each other with the top inner wall of spacing spout, and pressure spring 18 provides decurrent elasticity for limiting slide block 16, and then makes inserted bar 14 can get into dovetail groove 15.

In this embodiment, the outside cover of guide arm 6 is equipped with spring 8, and spring 8's bottom links to each other with the top of backup pad 4, and spring 8's top links to each other with the bottom of conflict board 7, and spring 8 provides ascending elasticity for conflict board 7.

In the embodiment, when the movable module is used, the movable module body 1 is placed on the top of the supporting plate 4 and is in contact with the two touch plates 7, the movable module body 1 is pressed downwards, the two touch plates 7 drive the two guide rods 6 to move downwards, the guide rods 6 drive the push plates 9 to be close to the movable module body 1 through the corresponding steel wire ropes 19 until the two push plates 9 tightly press and fix the movable module body 1 through the two anti-skid pads 10, at this time, the movable module body 1 is released, the insertion rods 14 enter the corresponding trapezoidal grooves 15 under the action of the elastic force of the pressure springs 18, the stability of the I-shaped blocks 12 and the push plates 9 can be ensured, and further the stability of the movable module body 1 during use is ensured, when the movable module body 1 needs to be disassembled and maintained, the two manual rods 17 are upwards pulled, the manual rods 17 drive the insertion rods 14 to leave the corresponding trapezoidal grooves 15, under the action of the tension springs 13, the push plates 9 drive the anti-skid pads 10 to leave the movable module body 1, simultaneously spring 8 promotes to touch panel 7 and upwards promotes transfer module body 1, can dismantle the maintenance of transfer module body 1, convenient operation, and the load balancing ware that provides in the background of the application document, the virtual machine resource that can dynamically dispatch all can adopt this mode to install.

The above descriptions are only preferred embodiments of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the scope of the present invention, and the technical solutions and the utility model concepts of the present invention are equivalent to, replaced or changed.

Claims (5)

1. A program transferring module with balanced dynamic load comprises a transferring module body (1), wherein a machine body is arranged on the outer side of the transferring module body (1) and comprises a bottom shell (2) and a top shell (3), and is characterized in that a supporting plate (4) is fixedly arranged in the bottom shell (2), two guide rods (6) are vertically and slidably arranged on the top of the supporting plate (4), touch plates (7) are fixedly arranged on the tops of the two guide rods (6), the touch plates (7) are in contact with the bottom of the transferring module body (1), two side fixing units are symmetrically and slidably arranged on the top of the supporting plate (4), the side fixing units are in contact with the transferring module body (1), the bottoms of the side fixing units are connected with fixing units, the fixing units are matched with the supporting plate (4), steel wire ropes (19) are connected on the outer sides of the guide rods (6), and one end of each steel wire (19) is connected with the side fixing unit, the supporting plate (4) is provided with a through hole (5), and the steel wire rope (19) is movably connected with the through hole (5).

2. The program maneuvering module for dynamic load balancing according to claim 1, characterized in that the side fixing unit comprises a push plate (9) and a non-slip mat (10), the non-slip mat (10) is connected to the inner side of the push plate (9), the non-slip mat (10) is in contact with the maneuvering module body (1), and the steel wire rope (19) is connected to the inner side of the push plate (9).

3. The program scheduling module for dynamic load balancing according to claim 1, wherein the side fixing unit comprises an i-shaped block (12), a tension spring (13), an insertion rod (14), a limiting slider (16), a manual rod (17) and a pressure spring (18), the top of the support plate (4) is symmetrically provided with two i-shaped grooves (11), the i-shaped block (12) is slidably connected with the corresponding i-shaped groove (11), one end of the tension spring (13) is fixedly connected with the i-shaped block (12), the other end of the tension spring (13) is fixedly connected with the inner wall of the i-shaped groove (11), the top of the i-shaped block (12) is connected with the bottom of the push plate (9), the inner wall of the bottom of the i-shaped groove (11) is uniformly provided with a plurality of trapezoidal grooves (15), the bottom end of the insertion rod (14) is obliquely arranged, the insertion rod (14) is slidably mounted on the i-shaped block (12) and penetrates through the i-shaped block (12) to be in one-way clamped connection with the trapezoidal grooves (15), the bottom of the limiting slide block (16) is connected with the top end of the inserted link (14), and the manual lever (17) is connected with the outer side of the limiting slide block (16).

4. The program transferring module for dynamic load balancing according to claim 3, wherein a limiting sliding groove is formed in the outer side of the pushing plate (9), the limiting sliding block (16) is connected with the limiting sliding groove in a sliding manner, the bottom end of the pressure spring (18) is connected with the top of the limiting sliding block (16), and the top end of the pressure spring (18) is connected with the inner wall of the top of the limiting sliding groove.

5. Procedure call module for dynamic load balancing according to claim 1, characterized in that the guide rods (6) are externally sleeved with springs (8), the bottom ends of the springs (8) are connected to the top of the support plate (4), and the top ends of the springs (8) are connected to the bottom of the contact plate (7).

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