CN109555936B - Support mechanism of big data processor - Google Patents

Abstract

The invention discloses a supporting mechanism of a large data processor, which comprises four stand columns, wherein a bottom plate is fixedly connected among the four stand columns, a cavity is formed in the bottom plate, a driving mechanism is arranged in the cavity, a moving plate is horizontally arranged in the cavity and arranged above the driving mechanism, the driving mechanism is connected with the moving plate, a supporting plate is slidably connected above the bottom plate, two cylinders are symmetrically and fixedly connected to one side of the upper end of the moving plate, the driving ends of the cylinders are rotatably connected with the lower end of the supporting plate, and two connecting rods are symmetrically and fixedly connected to one end of a raw material cylinder of the supporting plate. The invention has the advantages of stable structure, simple operation, scientific and reasonable design and short production period, can more conveniently move the large-scale processor above the bottom plate for placement, can adjust the dustproof net according to the different heights of the processors, and can better prevent moisture of the processors.

Description

Support mechanism of big data processor

Technical Field

The invention relates to the technical field of supporting mechanisms of large data processors, in particular to a supporting mechanism of a large data processor.

Background

Big data, which refers to a data set that cannot be captured, managed and processed by a conventional software tool within a certain time range, is a massive, high-growth-rate and diversified information asset that needs a new processing mode to have stronger decision-making power, insight discovery power and process optimization capability.

When the large data is processed and operated, the large data can be ensured to be smoothly processed only by the operation of a large processor, and the conventional large processors are mostly directly placed on the ground, so that the elements in the processors are affected by damp and damaged after long-time use, and the operation of the processors is influenced.

To this end, we propose a support mechanism for large data processors.

Disclosure of Invention

The invention aims to solve the problem that the long-time use of the prior art, in which a large-sized processor is mostly directly placed on the ground, can cause the elements in the processor to be affected by moisture and damage and influence the operation of the processor, and provides a support mechanism of a large-sized data processor.

In order to achieve the purpose, the invention adopts the following technical scheme: a supporting mechanism of a big data processor comprises four upright posts, a bottom plate is fixedly connected among the four upright posts, a cavity is arranged in the bottom plate, a driving mechanism is arranged in the cavity, a moving plate is horizontally arranged in the cavity, the moving plate is arranged above the driving mechanism, the driving mechanism is connected with the moving plate, a supporting plate is connected above the bottom plate in a sliding manner, two cylinders are symmetrically and fixedly connected to one side of the upper end of the moving plate, the driving end of the cylinder is rotationally connected with the lower end of the supporting plate, one end of the supporting plate far away from the cylinder is symmetrically and fixedly connected with two connecting rods, each connecting rod extends into the cavity and is rotatably connected with the upper end of the moving plate, the upper ends of the four upright posts are fixedly connected with a top plate together, and a lifting mechanism is arranged in the top plate, four dustproof nets are connected between the stand columns in a sliding manner, and the dustproof nets are connected with the lifting mechanism.

In foretell floor brick handling device for interior decoration, actuating mechanism is including rotating a plurality of pivots of connection in the cavity, every equal symmetrical cover in the pivot is equipped with two gears, and the upper end of every gear all is connected with the lower extreme of movable plate, every equal symmetrical cover in the pivot has two worm wheels, and every epaxial worm wheel of commentaries on classics sets up the both sides at the gear respectively, two first motors of symmetry fixedly connected with, every on the inside wall of cavity the equal fixedly connected with worm of drive end of first motor, and every worm meshes with a plurality of worm wheels that lie in the cavity with one side respectively.

In the floor brick carrying device for interior decoration, the lifting mechanism comprises a groove arranged in a top plate, connecting grooves are arranged in four upright posts, each connecting groove is vertically and rotatably connected with a threaded rod, the upper end of each threaded rod extends into the groove, one end of each threaded rod, which is positioned in the groove, is fixedly sleeved with a first bevel gear, two second motors are symmetrically and fixedly connected to the inner bottom, a driving end of each second motor is fixedly connected with a driving rod, one end of each driving rod, far away from the second motor, is fixedly sleeved with a second bevel gear, each second bevel gear is meshed with the corresponding first bevel gear respectively, each threaded rod is in threaded connection with a sliding block, and each slider all extends to the one side that is close to the dust screen, every the slider all with the lateral wall fixed connection of dust screen.

In foretell floor brick handling device for interior decoration, two lugs of one side symmetry fixedly connected with, every of cylinder are kept away from to the movable plate equal fixedly connected with dwang on the lug, and the one end that every connecting rod is located the cavity overlaps respectively to be established on the dwang and rotate with the dwang and be connected.

In foretell floor brick handling device for interior decoration, horizontal fixed connection baffle in the cavity, two bar grooves have been seted up to the symmetry on the baffle, and every gear all passes through the bar groove and extends to the top of baffle, two mounting grooves have been seted up to the lower extreme symmetry of movable plate, every equal fixedly connected with rack on the interior roof of mounting groove, and the upper end that just is located a plurality of gears of cavity with one side all is located same mounting groove and meshes with the rack.

In the floor tile carrying device for indoor decoration, the cavity is vertically and fixedly connected with the stabilizing plate, and the stabilizing plate is sleeved on the two worms and is rotationally connected with the two worms.

In the floor brick carrying device for interior decoration, the upper end of the bottom plate is symmetrically provided with two sliding grooves, and the two cylinders and the connecting rod are both positioned in the sliding grooves and are in sliding connection with the sliding grooves.

In the floor brick carrying device for interior decoration, the lower end of each upright post is fixedly connected with a support leg, one side of each upright post, which is close to the bottom plate, is fixedly connected with a support block, and each support block is attached to the bottom wall of the bottom plate.

In the floor tile carrying device for interior decoration, two fixing blocks are symmetrically and fixedly connected in each groove, and the two fixing blocks are respectively sleeved on the driving rod and are rotatably connected with the driving rod.

Compared with the prior art, this floor brick handling device for interior decoration of air chamber's advantage lies in:

1. according to the invention, the air cylinder is arranged to drive the support plate to rotate on the movable plate through the connecting rod, so that one end of the support plate is attached to the ground, and an included angle is formed between the support plate and the ground, and thus a large processor can be conveniently pushed onto the support plate to be placed.

2. The worm is driven to rotate by the first motor, the worm drives the gear on the rotating shaft to rotate through the worm gear, the gear drives the moving plate to pull the supporting plate to move out of the upper portion of the bottom plate through the rack at the lower end of the moving plate, and the processor can be conveniently moved to the upper portion of the bottom plate.

3. The second bevel gear on the second motor drive driving rod is arranged to rotate, and the second bevel gear drives the threaded rod to rotate through the first bevel gear, so that the threaded rod pulls the dust screen through the sliding block to adjust according to different heights of the processor.

In conclusion, the invention has the advantages of stable structure, simple operation, scientific and reasonable design and short production period, can more conveniently move the large-scale processor above the bottom plate for placing, can adjust the dustproof net according to the different heights of the processors, and can better prevent moisture of the processors.

Drawings

FIG. 1 is a schematic structural diagram of a support mechanism of a big data processor according to the present invention;

FIG. 2 is a schematic diagram of a lifting mechanism of a support mechanism of a big data processor according to the present invention;

FIG. 3 is a schematic diagram of the internal structure of a base plate of a support mechanism of a big data processor according to the present invention;

FIG. 4 is a schematic structural diagram of a driving mechanism of a support mechanism of a big data processor according to the present invention;

FIG. 5 is a schematic view of a threaded rod structure of a support mechanism of a big data processor according to the present invention;

FIG. 6 is a bottom structure diagram of a bottom plate of a supporting mechanism of a big data processor according to the present invention;

FIG. 7 is a schematic diagram of a link structure of a support mechanism of a big data processor according to the present invention;

fig. 8 is a schematic view of a gear structure of a supporting mechanism of a big data processor according to the present invention.

In the figure: the device comprises a vertical column 1, a bottom plate 2, a supporting leg 3, a dust screen 4, a top plate 5, a second motor 6, a driving rod 7, a fixed block 8, a sliding block 9, a threaded rod 10, a supporting plate 11, a moving plate 12, an air cylinder 13, a first motor 14, a stabilizing plate 15, a partition plate 16, a gear 17, a worm 18, a second bevel gear 19, a first bevel gear 20, a supporting block 21, a rotating rod 22, a connecting rod 23, a worm wheel 24 and a rotating shaft 25.

Detailed Description

The following examples are for illustrative purposes only and are not intended to limit the scope of the present invention.

Examples

Referring to fig. 1-8, a supporting mechanism of a big data processor comprises four columns 1, a bottom plate 2 is fixedly connected between the four columns 1, a cavity is arranged in the bottom plate 2, a driving mechanism is arranged in the cavity, a moving plate 12 is horizontally arranged in the cavity, the moving plate 12 is arranged above the driving mechanism, the driving mechanism is connected with the moving plate 12, a supporting plate 11 is slidably connected above the bottom plate 2 and used for supporting the processor, two cylinders 13 are symmetrically and fixedly connected to one side of the upper end of the moving plate 12, the driving end of each cylinder 13 is rotatably connected with the lower end of the supporting plate 11, two connecting rods 23 are symmetrically and fixedly connected to one end of the supporting plate 11 far away from the cylinders 13, each connecting rod 23 extends into the cavity and is rotatably connected with the upper end of the moving plate 12, a top plate 5 is fixedly connected to the upper ends of the four columns 1 together, a lifting mechanism is, and the dust screen 4 is connected with the lifting mechanism; the air cylinder 13 drives the support plate 11 to rotate on the moving plate 12 through the connecting rod 23, so that one end of the support plate 11 is attached to the ground, an included angle is formed between the support plate 11 and the ground, and the large processor can be conveniently pushed onto the support plate 11 to be placed;

the upper end of the bottom plate 2 is symmetrically provided with two sliding grooves, and the two cylinders 13 and the connecting rod 23 are both positioned in the sliding grooves and are in sliding connection with the sliding grooves, so that the moving plate 12 can be conveniently driven to pull the supporting plate 11 to move out of the upper part of the bottom plate 2, and then the processor is pushed to move onto the supporting plate 11; the lower end of each upright post 1 is fixedly connected with a support leg 3, one side of each upright post 1 close to the bottom plate 2 is fixedly connected with a support block 21, and each support block 21 is attached to the bottom wall of the bottom plate 2 and used for improving the stability of the bottom plate 2 on the upright posts 1;

the driving mechanism comprises a plurality of rotating shafts 25 which are rotatably connected in the cavity, two gears 17 are symmetrically sleeved on each rotating shaft 25, the upper end of each gear 17 is connected with the lower end of the moving plate 12, two worm wheels 24 are symmetrically sleeved on each rotating shaft 25, the worm wheels 24 on each rotating shaft 25 are respectively arranged on two sides of each gear 17, two first motors 14 are symmetrically and fixedly connected on the inner side wall of the cavity, a worm 18 is fixedly connected at the driving end of each first motor 14, each worm 18 is respectively meshed with the worm wheels 24 on the same side of the cavity, the first motors 14 adopt servo motors, and the reciprocating motion of the supporting plate 11 on the bottom plate 2 can be conveniently driven according to the requirements of people;

a stabilizing plate 15 is vertically and fixedly connected in the cavity, and the stabilizing plate 15 is sleeved on the two worms 18 and is rotationally connected with the two worms 18 to increase the stability of the stabilizing plate 15;

a partition plate 16 is horizontally and fixedly connected in the cavity, two strip-shaped grooves are symmetrically formed in the partition plate 16, each gear 17 passes through the strip-shaped groove and extends to the upper side of the partition plate 16, two mounting grooves are symmetrically formed in the lower end of the movable plate 12, a rack is fixedly connected to the inner top wall of each mounting groove, and the upper ends of the plurality of gears 17 positioned on the same side of the cavity are positioned in the same mounting groove and meshed with the racks;

the lifting mechanism comprises a groove formed in the top plate 5, connecting grooves are formed in the four stand columns 1, a threaded rod 10 is vertically and rotatably connected in each connecting groove, the upper end of each threaded rod 10 extends into the groove, a first bevel gear 20 is fixedly sleeved at one end of each threaded rod 10, which is positioned in the groove, two second motors 6 are symmetrically and fixedly connected at the inner bottom of each connecting groove, a driving rod 7 is fixedly connected at the driving end of each second motor 6, a second bevel gear 19 is fixedly sleeved at one end of each driving rod 7, which is far away from the second motor 6, each second bevel gear 19 is respectively meshed with the corresponding first bevel gear 20, a sliding block 9 is in threaded connection with each threaded rod 10, each sliding block 9 extends to one side close to the dustproof net 4, each sliding block 9 is fixedly connected with the side wall of the dustproof net 4, each second motor 6 is a bidirectional threaded rod motor, and the two-way threaded rods 10, thereby enabling the dust screen 4 to move according to the height of the processor;

two fixing blocks 8 are symmetrically and fixedly connected in each groove, and the two fixing blocks 8 are respectively sleeved on the driving rod 7 and are rotatably connected with the driving rod 7;

two convex blocks are symmetrically and fixedly connected to one side of the moving plate 12, which is far away from the cylinder 13, a rotating rod 22 is fixedly connected to each convex block, and one end of each connecting rod 23, which is located in the cavity, is respectively sleeved on the rotating rod 22 and is rotatably connected with the rotating rod 22.

The electrical components presented in the document are all electrically connected with an external master controller and 220V mains, and the master controller can be a conventional known device controlled by a computer or the like.

When the invention is used, the worm 18 on the driving end is driven by the first motor 14 to rotate on the stabilizing plate 15, so that the worm 18 drives the gear 17 sleeved on the rotating shaft 25 to rotate through the worm wheel 24, the plurality of gears 17 can drive the moving plate 12 to move through the racks in the mounting groove, so that the moving plate 12 pulls the supporting plate 11 to move, when the two cylinders 13 move to the other end of the bottom plate 2, the two cylinders 13 push the supporting plate 11 to rotate on the moving plate 12 through the connecting rod 23 until one end of the supporting plate 11 far away from the cylinders 13 is attached to the ground, so that a large-scale processor can be pushed onto the supporting plate 11, then the supporting plate 11 is pulled to be horizontal by the cylinders 13, then the first motor 14 is used for overturning, so that the worm 18 drives the gears 17 to rotate, so that the moving plate 12 pulls the supporting plate 11 to move to the upper part of the bottom, and finally, the second motor 6 drives the driving rod 7 to rotate on the fixed block 8, so that the second bevel gear 19 sleeved on the driving rod 7 drives the threaded rod 10 to rotate through the first bevel gear 20, and the sliding block 9 sleeved on the threaded rod 10 pulls the dust screen 4 to be attached to the processor.

Although the terms of the upright 1, the bottom plate 2, the legs 3, the dust screen 4, the top plate 5, the second motor 6, the driving rod 7, the fixing block 8, the slider 9, the threaded rod 10, the supporting plate 11, the moving plate 12, the cylinder 12, the first motor 14, the stabilizing plate 15, the partition plate 16, the gear 17, the worm 18, the second bevel gear 19, the first bevel gear 20, the support block 21, the rotating rod 22, the connecting rod 23, the worm wheel 24, the rotating shaft 25, etc. are used more frequently, the possibility of using other terms is not excluded. These terms are used merely to more conveniently describe and explain the nature of the present invention; they are to be construed as being without limitation to any additional limitations that may be imposed by the spirit of the present invention.

Claims (9)

1. The supporting mechanism of the big data processor comprises four upright posts (1) and is characterized in that a bottom plate (2) is fixedly connected among the four upright posts (1), a cavity is formed in the bottom plate (2), a driving mechanism is arranged in the cavity, a movable plate (12) is horizontally arranged in the cavity, the movable plate (12) is arranged above the driving mechanism, the driving mechanism is connected with the movable plate (12), a supporting plate (11) is slidably connected above the bottom plate (2), two cylinders (13) are symmetrically and fixedly connected to one side of the upper end of the movable plate (12), the driving ends of the cylinders (13) are rotatably connected with the lower end of the supporting plate (11), two connecting rods (23) are symmetrically and fixedly connected to one end, far away from the cylinders (13), of the supporting plate (11), each connecting rod (23) extends into the cavity and is rotatably connected with the upper end of the movable plate (12), four the common fixedly connected with roof (5) in upper end of stand (1), be equipped with elevating system in roof (5), four sliding connection has dust screen (4) between stand (1), and dust screen (4) are connected with elevating system.

2. The support mechanism of the big data processor according to claim 1, wherein the driving mechanism comprises a plurality of rotating shafts (25) rotatably connected in the cavity, each rotating shaft (25) is symmetrically sleeved with two gears (17), the upper end of each gear (17) is connected with the lower end of the moving plate (12), each rotating shaft (25) is symmetrically sleeved with two worm gears (24), the worm gears (24) on each rotating shaft (25) are respectively arranged on two sides of the gears (17), the inner side wall of the cavity is symmetrically and fixedly connected with two first motors (14), the driving end of each first motor (14) is fixedly connected with a worm (18), and each worm (18) is respectively meshed with the worm gears (24) on the same side of the cavity.

3. The support mechanism of a big data processor according to claim 1, wherein the lifting mechanism comprises a groove formed in the top plate (5), four of the columns (1) are respectively provided with a connecting groove, each connecting groove is vertically and rotatably connected with a threaded rod (10), the upper end of each threaded rod (10) extends into the groove, one end of each threaded rod (10) located in the groove is fixedly sleeved with a first bevel gear (20), the inner bottom of the top plate (5) is symmetrically and fixedly connected with two second motors (6), the driving end of each second motor (6) is fixedly connected with a driving rod (7), one end of each driving rod (7) far away from the second motor (6) is fixedly sleeved with a second bevel gear (19), and each second bevel gear (19) is respectively engaged with the corresponding first bevel gear (20), every equal threaded connection has slider (9) on threaded rod (10), and every slider (9) all extends to the one side that is close to dust screen (4), every slider (9) all with the lateral wall fixed connection of dust screen (4).

4. The support mechanism of a big data processor of claim 1, characterized in that, one side of the moving plate (12) far from the cylinder (13) is symmetrically and fixedly connected with two bumps, each bump is fixedly connected with a rotating rod (22), and one end of each connecting rod (23) located in the cavity is respectively sleeved on the rotating rod (22) and is rotatably connected with the rotating rod (22).

5. The supporting mechanism of a big data processor of claim 2, characterized in that, the cavity is internally and horizontally and fixedly connected with a partition plate (16), two strip-shaped grooves are symmetrically formed on the partition plate (16), each gear (17) passes through the strip-shaped groove and extends to the upper side of the partition plate (16), two mounting grooves are symmetrically formed at the lower end of the moving plate (12), each mounting groove is fixedly connected with a rack on the inner top wall, and the upper ends of the plurality of gears (17) positioned at the same side of the cavity are positioned in the same mounting groove and meshed with the rack.

6. The support mechanism of a big data processor of claim 2, characterized in that a stabilizing plate (15) is vertically and fixedly connected in the cavity, and the stabilizing plate (15) is sleeved on the two worms (18) and is rotatably connected with the two worms (18).

7. The supporting mechanism of a big data processor of claim 1, characterized in that, two sliding grooves are symmetrically opened on the upper end of the bottom plate (2), and the two cylinders (13) and the connecting rod (23) are both located on the sliding grooves and are connected with the sliding grooves in a sliding manner.

8. The support mechanism of a big data processor of claim 1, characterized in that the lower end of each upright (1) is fixedly connected with a support leg (3), one side of each upright (1) close to the bottom plate (2) is fixedly connected with a support block (21), and each support block (21) is attached to the bottom wall of the bottom plate (2).

9. The supporting mechanism of a big data processor of claim 3, characterized in that two fixing blocks (8) are symmetrically and fixedly connected in each groove, and the two fixing blocks (8) are respectively sleeved on the driving rod (7) and rotatably connected with the driving rod (7).

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